Planet Musings

May 17, 2025

John Baez — Dead Stars Don’t Radiate

Three guys claim that any heavy chunk of matter emits Hawking radiation, even if it’s not a black hole:

• Michael F. Wondrak, Walter D. van Suijlekom and Heino Falcke, Gravitational pair production and black hole evaporation, Phys. Rev. Lett. 130 (2023), 221502.

Now they’re getting more publicity by claiming this means that the universe will fizzle out sooner than we expected. They’re claiming, for example, that a dead, cold star will emit Hawking radiation, and thus slowly lose mass and eventually disappear!

They admit that this would violate baryon conservation: after all, the protons and neutrons in the star would have to go away somehow! They admit they don’t know how this would work. They just say that the gravitational field of the star will create particle-antiparticle pairs that will slowly radiate away, forcing the dead star to lose mass somehow to conserve energy.

If experts thought this had even a chance of being true, it would be the biggest thing since sliced bread—at least in the field of quantum gravity. Everyone would be writing papers about it, because if true it would be revolutionary. It would overturn calculations by experts which say that a stationary chunk of matter doesn’t emit Hawking radiation. It would also mean that quantum field theory in curved spacetime can only be consistent if baryon number fails to be conserved! This would be utterly shocking.

But in fact, these new papers have had almost zero effect on physics. There’s a short rebuttal, here:

• Antonio Ferreiro José Navarro-Salas and Silvia Pla, Comment on “Gravitational pair production and black hole evaporation”, Phys. Rev. Lett. 133 (2024), 229001.

It explains that these guys used a crude approximation that gives wrong results even in a simpler problem. Similar points are made here:

• E. T. Akhmedov, D. V. Diakonov and C. Schubert, Complex effective actions and gravitational pair creation, Phys. Rev. D. 110, 105011.

Unfortunately, it seems the real experts on quantum field theory in curved spacetime have not come out and mentioned the correct way to think about this issue, which has been known at least since 1975. To them—or maybe I should dare to say “us”—it’s just well known that the gravitational field of a static mass does not cause the creation of particle-antiparticle pairs.

Of course, the referees should have rejected Wondrak, van Suijlekom and Falcke’s papers. But apparently none of those referees were experts on the subject at hand. So you can’t trust a paper just because it appears in a supposedly reputable physics journal. You have to actually understand the subject and assess the paper yourself, or talk to some experts you trust.

If I were a science journalist writing an article about a supposedly shocking development like this, I would email some experts and check to see if it’s for real. But plenty of science journalists don’t bother with that anymore: they just believe the press releases. So now we’re being bombarded with lazy articles like these:

• Universe will die “much sooner than expected,” new research says, CBS News, May 13, 2025.

• Sharmila Kuthunur, Scientists calculate when the universe will end—it’s sooner than expected, Space.com, 15 May 2025.

• Jamie Carter, The universe will end sooner than thought, scientists say, Forbes, 16 May 2025.

The list goes on; these are just three. There’s no way what I say can have much effect against such a flood of misinformation. As Mark Twain said, “A lie can travel around the world and back again while the truth is lacing up its boots.” Actually he probably didn’t say that—but everyone keeps saying he did, illustrating the point perfectly.

Still, there might be a few people who both care and don’t already know this stuff. Instead of trying to give a mini-course here, let me simply point to an explanation of how things really work:

• Abhay Ashtekar and Anne Magnon, Quantum fields in curved space-times, Proceedings of the Royal Society, 346 (1975), 375–394.

It’s technical, so it’s not easy reading if you haven’t studied quantum field theory and general relativity, but that’s unavoidable. It shows that in a static spacetime there is a well-defined concept of ‘vacuum’, and the vacuum is stable. Jorge Pullin pointed out the key sentence for present purposes:

Thus, if the underlying space-time admits a everywhere time-like Killing field, the vacuum state is indeed stable and phenomena such as the spontaneous creation of particles do not occur.

This condition of having an “everywhere time-like Killing field” says that a spacetime has time translation symmetry. Ashtekar and Magnon also assume that spacetime is globally hyperbolic and that the wave equation for a massive spin-zero particle has a smooth solution given smooth initial data. All this lets us define a concept of energy for solutions of this equation. It also lets us split solutions into positive-frequency solutions, which correspond to particles, and negative-frequency ones, which correspond to antiparticles. We can thus set up quantum field theory in way we’re used to on Minkowski spacetime, where there’s a well-defined vacuum which does not decay into particle-antiparticle pairs.

The Schwarzschild solution, which describes a static black hole, also has a Killing field. But this ceases to be timelike at the event horizon, so this result does not apply to that!

I could go into more detail if required, but you can find a more pedagogical treatment in this standard textbook:

• Robert Wald, Quantum Field Theory in Curved Spacetime and Black Hole Thermodynamics, University of Chicago Press, Chicago, 1994.

In particular, go to Section 4.3, which is on quantum field theory in stationary spacetimes.

I also can’t resist citing this thesis by a student of mine:

• Valeria Michelle Carrión Álvarez, Loop Quantization versus Fock Quantization of p-Form Electromagnetism on Static Spacetimes, Ph.D. thesis, U. C. Riverside, 2004.

This thesis covers the case of electromagnetism, while Ashtekar and Magnon, and also Wald, focus on a massive scalar field for simplicity.

So: it’s been rigorously shown that the gravitational field of a static object does not create particle-antiparticle pairs. This has been known for decades. Now some people have done a crude approximate calculation that seems to show otherwise. Some flaws in the approximation have been pointed out. Of course the authors of the calculation don’t believe their approximation is flawed. We could argue about that for a long time. But it’s scarcely worth thinking about, because no approximations were required to settle this issue. It was settled over 50 years ago, and the new work is not shedding new light on the issue: it’s much more hand-wavy than the old work.

by John Baez at May 17, 2025 04:00 PM

Jordan Ellenberg — This and that

The Orioles game tonight was the MLB.tv Free Game of the Day, so I watched it. The Orioles left 15 men on base — including leaving the bases loaded three times — and lost 4-3 to a terrible Nationals team when Felix Bautista forgot there was a runner on second. It was not, in fact, the free game of the day. It came at a great emotional cost.
I have been traveling a lot the last few weeks. I was wondering: if sitting in the exit row means you’re asserting your availability to help the crew in case of an emergency, why are they allowed to serve alcohol to exit row passengers?
I only just realized that “Going Down to Liverpool” (the Katrina and the Waves song made famous, or at least a little more famous, when the Bangles covered it) is a wholesome response song to the very unwholesome “Hey Joe.” “Hey Joe” is a song about a man killing his wife. “Hey Joe, where you goin’ with that gun in your hand? // I’m goin’ down to shoot my old lady.” “Going Down to Liverpool” is a song about a chill guy who’s unemployed. “I said hey, where you goin’ with that UB40 in your hand? // I’m going down to LIverpool to do nothing, all the days of my life.”
I actually have lots of interesting math to talk about but somehow have not felt lately — maybe because I’ve been traveling a lot, teetotaling in the exit row — that I had the spare minutes to write a substantial math post. But I will!

by JSE at May 17, 2025 03:06 AM

May 16, 2025

Matt von Hippel — Post on the Weak Gravity Conjecture for FirstPrinciples.org

I have another piece this week on the FirstPrinciples.org Hub. If you’d like to know who they are, I say a bit about my impressions of them in my post on the last piece I had there. They’re still finding their niche, so there may be shifts in the kind of content they cover over time, but for now they’ve given me an opportunity to cover a few topics that are off the beaten path.

This time, the piece is what we in the journalism biz call an “explainer”. Instead of interviewing people about cutting-edge science, I wrote a piece to explain an older idea. It’s an idea that’s pretty cool, in a way I think a lot of people can actually understand: a black hole puzzle that might explain why gravity is the weakest force. It’s an idea that’s had an enormous influence, both in the string theory world where it originated and on people speculating more broadly about the rules of quantum gravity. If you want to learn more, read the piece!

Since I didn’t interview anyone for this piece, I don’t have the same sort of “bonus content” I sometimes give. Instead of interviewing, I brushed up on the topic, and the best resource I found was this review article written by Dan Harlow, Ben Heidenreich, Matthew Reece, and Tom Rudelius. It gave me a much better idea of the subtleties: how many different ways there are to interpret the original conjecture, and how different attempts to build on it reflect on different facets and highlight different implications. If you are a physicist curious what the whole thing is about, I recommend reading that review: while I try to give a flavor of some of the subtleties, a piece for a broad audience can only do so much.

by 4gravitons at May 16, 2025 04:00 PM

John Baez — Meteor Burst Communications

Back before satellites, to transmit radio waves over really long distances folks bounced them off the ionosphere—a layer of charged particles in the upper atmosphere. Unfortunately this layer only reflects radio waves with frequencies up to 30 megahertz. This limits the rate at which information can be transmitted.

How to work around this?

METEOR BURST COMMUNICATIONS!

On average, 100 million meteorites weighing about a milligram hit the Earth each day. They vaporize about 120 kilometers up. Each one creates a trail of ions that lasts about a second. And you can bounce radio waves with a frequency up to 100 megahertz off this trail.

That’s not a huge improvement, and you need to transmit in bursts whenever a suitable meterorite comes your way, but the military actually looked into doing this.

The National Bureau of Standards tested a burst-mode system in 1958 that used the 50-MHz band and offered a full-duplex link at 2,400 bits per second. The system used magnetic tape loops to buffer data and transmitters at both ends of the link that operated continually to probe for a path. Whenever the receiver at one end detected a sufficiently strong probe signal from the other end, the transmitter would start sending data. The Canadians got in on the MBC action with their JANET system, which had a similar dedicated probing channel and tape buffer. In 1954 they established a full-duplex teletype link between Ottawa and Nova Scotia at 1,300 bits per second with an error rate of only 1.5%.

This is from

• Dan Maloney, Radio apocalypse: meteor burst communications, Hackaday, 2025 May 12.

and the whole article is a great read.

There’s a lot more to the story. For example, until recently people used this method in the western United States to report the snow pack from mountain tops!

The system was called SNOTEL, and you can read more about it here:

• Dan Maloney, Know snow: monitoring snowpack with the SNOTEL network, Hackaday, 2023 June 29.

Also, a lot of ham radio operators bounce signals off meteors just for fun!

• Robert Gulley, Incoming! An introduction to meteor scatter propagation, The SWLing Post, 2024 January 17.

by John Baez at May 16, 2025 09:14 AM

May 15, 2025

John Baez — Visions for the Future of Physics

On Wednesday May 14, 2025 I’ll be giving a talk at 2 pm Pacific Time, or 10 pm UK time. The talk is for physics students at the Universidade de São Paulo in Brazil, organized by Artur Renato Baptista Boyago.

Visions for the Future of Physics

Abstract. The 20th century was the century of fundamental physics. What about the 21st? Progress on fundamental physics has been slow since about 1980, but there is exciting progress in other fields, such as condensed matter. This requires an adjustment in how we think about the goal of physics.

You can see my slides here, or watch a video of the talk here:

by John Baez at May 15, 2025 03:06 PM

May 14, 2025

Terence Tao — Some variants of the periodic tiling conjecture

Rachel Greenfeld and I have just uploaded to the arXiv our paper Some variants of the periodic tiling conjecture. This paper explores variants of the periodic tiling phenomenon that, in some cases, a tile that can translationally tile a group, must also be able to translationally tile the group periodically. For instance, for a given discrete abelian group ${G}$ , consider the following question:

Question 1 (Periodic tiling question) Let ${F}$ be a finite subset of ${G}$ . If there is a solution ${1_A}$ to the tiling equation ${1_F * 1_A = 1}$ , must there exist a periodic solution ${1_{A_p}}$ to the same equation ${1_F * 1_{A_p} = 1}$ ?

We know that the answer to this question is positive for finite groups ${H}$ (trivially, since all sets are periodic in this case), one-dimensional groups ${{\bf Z} \times H}$ with ${H}$ finite, and in ${{\bf Z}^2}$ , but it can fail for ${{\bf Z}^2 \times H}$ for certain finite ${H}$ , and also for ${{\bf Z}^d}$ for sufficiently large ${d}$ ; see this previous blog post for more discussion. But now one can consider other variants of this question:

Instead of considering level one tilings ${1_F * 1_A = 1}$ , one can consider level ${k}$ tilings ${1_F * 1_A = k}$ for a given natural number ${k}$ (so that every point in ${G}$ is covered by exactly ${k}$ translates of ${F}$ ), or more generally ${1_F * 1_A = g}$ for some periodic function ${g}$ .
Instead of requiring ${1_F}$ and ${1_A}$ to be indicator functions, one can allow these functions to be integer-valued, thus we are now studying convolution equations ${f*a=g}$ where ${f, g}$ are given integer-valued functions (with ${g}$ periodic and ${f}$ finitely supported).

We are able to obtain positive answers to three such analogues of the periodic tiling conjecture for three cases of this question. The first result (which was kindly shared with us by Tim Austin), concerns the homogeneous problem ${f*a = 0}$ . Here the results are very satisfactory:

Theorem 2 (First periodic tiling result) Let ${G}$ be a discrete abelian group, and let ${f}$ be integer-valued and finitely supported. Then the following are equivalent.

(i) There exists an integer-valued solution ${a}$ to ${f*a=0}$ that is not identically zero.
(ii) There exists a periodic integer-valued solution ${a_p}$ to ${f * a_p = 0}$ that is not identically zero.
(iii) There is a vanishing Fourier coefficient ${\hat f(\xi)=0}$ for some non-trivial character ${\xi \in \hat G}$ of finite order.

By combining this result with an old result of Henry Mann about sums of roots of unity, as well as an even older decidability result of Wanda Szmielew, we obtain

Corollary 3 Any of the statements (i), (ii), (iii) is algorithmically decidable; there is an algorithm that, when given ${G}$ and ${f}$ as input, determines in finite time whether any of these assertions hold.

Now we turn to the inhomogeneous problem in ${{\bf Z}^2}$ , which is the first difficult case (periodic tiling type results are easy to establish in one dimension, and trivial in zero dimensions). Here we have two results:

Theorem 4 (Second periodic tiling result) Let ${G={\bf Z}^2}$ , let ${g}$ be periodic, and let ${f}$ be integer-valued and finitely supported. Then the following are equivalent.

(i) There exists an integer-valued solution ${a}$ to ${f*a=g}$ .
(ii) There exists a periodic integer-valued solution ${a_p}$ to ${f * a_p = g}$ .

Theorem 5 (Third periodic tiling result) Let ${G={\bf Z}^2}$ , let ${g}$ be periodic, and let ${f}$ be integer-valued and finitely supported. Then the following are equivalent.

(i) There exists an indicator function solution ${1_A}$ to ${f*1_A=g}$ .
(ii) There exists a periodic indicator function solution ${1_{A_p}}$ to ${f * 1_{A_p} = g}$ .

In particular, the previously established case of periodic tiling conjecture for level one tilings of ${{\bf Z}^2}$ , is now extended to higher level. By an old argument of Hao Wang, we now know that the statements mentioned in Theorem 5 are now also algorithmically decidable, although it remains open whether the same is the case for Theorem 4. We know from past results that Theorem 5 cannot hold in sufficiently high dimension (even in the classic case ${g=1}$ ), but it also remains open whether Theorem 4 fails in that setting.

Following past literature, we rely heavily on a structure theorem for solutions ${a}$ to tiling equations ${f*a=g}$ , which roughly speaking asserts that such solutions ${a}$ must be expressible as a finite sum of functions ${\varphi_w}$ that are one-periodic (periodic in a single direction). This already explains why tiling is easy to understand in one dimension, and why the two-dimensional case is more tractable than the case of general dimension. This structure theorem can be obtained by averaging a dilation lemma, which is a somewhat surprising symmetry of tiling equations that basically arises from finite characteristic arguments (viewing the tiling equation modulo ${p}$ for various large primes ${p}$ ).

For Theorem 2, one can take advantage of the fact that the homogeneous equation ${f*a=0}$ is preserved under finite difference operators ${\partial_h a(x) := a(x+h)-a(x)}$ : if ${a}$ solves ${f*a=0}$ , then ${\partial_h a}$ also solves the same equation ${f * \partial_h a = 0}$ . This freedom to take finite differences one to selectively eliminate certain one-periodic components ${\varphi_w}$ of a solution ${a}$ to the homogeneous equation ${f*a=0}$ until the solution is a pure one-periodic function, at which point one can appeal to an induction on dimension, to equate parts (i) and (ii) of the theorem. To link up with part (iii), we also take advantage of the existence of retraction homomorphisms from ${{\bf C}}$ to ${{\bf Q}}$ to convert a vanishing Fourier coefficient ${\hat f(\xi)= 0}$ into an integer solution to ${f*a=0}$ .

The inhomogeneous results are more difficult, and rely on arguments that are specific to two dimensions. For Theorem 4, one can also perform finite differences to analyze various components ${\varphi_w}$ of a solution ${a}$ to a tiling equation ${f*a=g}$ , but the conclusion now is that the these components are determined (modulo ${1}$ ) by polynomials of one variable. Applying a retraction homomorphism, one can make the coefficients of these polynomials rational, which makes the polynomials periodic. This turns out to reduce the original tiling equation ${f*a=g}$ to a system of essentially local combinatorial equations, which allows one to “periodize” a non-periodic solution by periodically repeating a suitable block of the (retraction homomorphism applied to the) original solution.

Theorem 5 is significantly more difficult to establish than the other two results, because of the need to maintain the solution in the form of an indicator function. There are now two separate sources of aperiodicity to grapple with. One is the fact that the polynomials involved in the components ${\varphi_w}$ may have irrational coefficients (see Theorem 1.3 of our previous paper for an explicit example of this for a level 4 tiling). The other is that in addition to the polynomials (which influence the fractional parts of the components ${\varphi_w}$ ), there is also “combinatorial” data (roughly speaking, associated to the integer parts of ${\varphi_w}$ ) which also interact with each other in a slightly non-local way. Once one can make the polynomial coefficients rational, there is enough periodicity that the periodization approach used for the second theorem can be applied to the third theorem; the main remaining challenge is to find a way to make the polynomial coefficients rational, while still maintaining the indicator function property of the solution ${a}$ .

It turns out that the restriction homomorphism approach is no longer available here (it makes the components ${\varphi_w}$ unbounded, which makes the combinatorial problem too difficult to solve). Instead, one has to first perform a second moment analysis to discern more structure about the polynomials involved. It turns out that the components ${\varphi_w}$ of an indicator function ${1_A}$ can only utilize linear polynomials (as opposed to polynomials of higher degree), and that one can partition ${{\bf Z}^2}$ into a finite number of cosets on which only three of these linear polynomials are “active” on any given coset. The irrational coefficients of these linear polynomials then have to obey some rather complicated, but (locally) finite, sentence in the theory of first-order linear inequalities over the rationals, in order to form an indicator function ${1_A}$ . One can then use the Weyl equidistribution theorem to replace these irrational coefficients with rational coefficients that obey the same constraints (although one first has to ensure that one does not accidentally fall into the boundary of the constraint set, where things are discontinuous). Then one can apply periodization to the remaining combinatorial data to conclude.

A key technical problem arises from the discontinuities of the fractional part operator ${\{x\}}$ at integers, so a certain amount of technical manipulation (in particular, passing at one point to a weak limit of the original tiling) is needed to avoid ever having to encounter this discontinuity.

by Terence Tao at May 14, 2025 07:00 PM

May 13, 2025

Terence Tao — A tool to verify estimates, II: a flexible proof assistant

In a recent post, I talked about a proof of concept tool to verify estimates automatically. Since that post, I have overhauled the tool twice: first to turn it into a rudimentary proof assistant that could also handle some propositional logic; and second into a much more flexible proof assistant (deliberately designed to mimic the Lean proof assistant in several key aspects) that is also powered by the extensive Python package sympy for symbolic algebra, following the feedback from previous commenters. This I think is now a stable framework with which one can extend the tool much further; my initial aim was just to automate (or semi-automate) the proving of asymptotic estimates involving scalar functions, but in principle one could keep adding tactics, new sympy types, and lemmas to the tool to handle a very broad range of other mathematical tasks as well.

The current version of the proof assistant can be found here. (As with my previous coding, I ended up relying heavily on large language model assistance to understand some of the finer points of Python and sympy, with the autocomplete feature of Github Copilot being particularly useful.) While the tool can support fully automated proofs, I have decided to focus more for now on semi-automated interactive proofs, where the human user supplies high-level “tactics” that the proof assistant then performs the necessary calculations for, until the proof is completed.

It’s easiest to explain how the proof assistant works with examples. Right now I have implemented the assistant to work inside the interactive mode of Python, in which one enters Python commands one at a time. (Readers from my generation may be familiar with text adventure games, which have a broadly similar interface.) I would be interested developing at some point a graphical user interface for the tool, but for prototype purposes, the Python interactive version suffices. (One can also run the proof assistant within a Python script, of course.)

After downloading the relevant files, one can launch the proof assistant inside Python by typing from main import * and then loading one of the pre-made exercises. Here is one such exercise:

>>> from main import *
>>> p = linarith_exercise()
Starting proof.  Current proof state:
x: pos_real
y: pos_real
z: pos_real
h1: x < 2*y
h2: y < 3*z + 1
|- x < 7*z + 2

This is the proof assistant’s formalization of the following problem: If $x,y,z$ are positive reals such that $x < 2y$ and $y < 3z+1$ , prove that $x < 7z+2$ .

The way the proof assistant works is that one directs the assistant to use various “tactics” to simplify the problem until it is solved. In this case, the problem can be solved by linear arithmetic, as formalized by the Linarith() tactic:

>>> p.use(Linarith())
Goal solved by linear arithmetic!
Proof complete!

If instead one wanted a bit more detail on how the linear arithmetic worked, one could have run this tactic instead with a verbose flag:

>>> p.use(Linarith(verbose=true))
Checking feasibility of the following inequalities:
1*z > 0
1*x + -7*z >= 2
1*y + -3*z < 1
1*y > 0
1*x > 0
1*x + -2*y < 0
Infeasible by summing the following:
1*z > 0 multiplied by 1/4
1*x + -7*z >= 2 multiplied by 1/4
1*y + -3*z < 1 multiplied by -1/2
1*x + -2*y < 0 multiplied by -1/4
Goal solved by linear arithmetic!
Proof complete!

Sometimes, the proof involves case splitting, and then the final proof has the structure of a tree. Here is one example, where the task is to show that the hypotheses $(x>-1) \wedge (x<1)$ and $(y>-2) \wedge (y<2)$ imply $(x+y>-3) \wedge (x+y<3)$ :

>>> from main import *
>>> p = split_exercise()
Starting proof.  Current proof state:
x: real
y: real
h1: (x > -1) & (x < 1)
h2: (y > -2) & (y < 2)
|- (x + y > -3) & (x + y < 3)
>>> p.use(SplitHyp("h1"))
Decomposing h1: (x > -1) & (x < 1) into components x > -1, x < 1.
1 goal remaining.
>>> p.use(SplitHyp("h2"))
Decomposing h2: (y > -2) & (y < 2) into components y > -2, y < 2.
1 goal remaining.
>>> p.use(SplitGoal())
Split into conjunctions: x + y > -3, x + y < 3
2 goals remaining.
>>> p.use(Linarith())
Goal solved by linear arithmetic!
1 goal remaining.
>>> p.use(Linarith())
Goal solved by linear arithmetic!
Proof complete!
>>> print(p.proof())
example (x: real) (y: real) (h1: (x > -1) & (x < 1)) (h2: (y > -2) & (y < 2)): (x + y > -3) & (x + y < 3) := by
  split_hyp h1
  split_hyp h2
  split_goal
  . linarith
  linarith

Here at the end we gave a “pseudo-Lean” description of the proof in terms of the three tactics used: a tactic cases h1 to case split on the hypothesis h1, followed by two applications of the simp_all tactic to simplify in each of the two cases.

The tool supports asymptotic estimation. I found a way to implement the order of magnitude formalism from the previous post within sympy. It turns out that sympy, in some sense, already natively implements nonstandard analysis: its symbolic variables have an is_number flag which basically corresponds to the concept of a “standard” number in nonstandard analysis. For instance, the sympy version S(3) of the number 3 has S(3).is_number == True and so is standard, whereas an integer variable n = Symbol("n", integer=true) has n.is_number == False and so is nonstandard. Within sympy, I was able to construct orders of magnitude Theta(X) of various (positive) expressions X, with the property that Theta(n)=Theta(1) if n is a standard number, and use this concept to then define asymptotic estimates such as $X \lesssim Y$ (implemented as lesssim(X,Y)). One can then apply a logarithmic form of linear arithmetic to then automatically verify some asymptotic estimates. Here is a simple example, in which one is given a positive integer $N$ and positive reals $x,y$ such that $x \leq 2N^2$ and $y < 3N$ , and the task is to conclude that $xy \lesssim N^4$ :

>>> p = loglinarith_exercise()
Starting proof.  Current proof state:
N: pos_int
x: pos_real
y: pos_real
h1: x <= 2*N**2
h2: y < 3*N
|- Theta(x)*Theta(y) <= Theta(N)**4
>>> p.use(LogLinarith(verbose=True))
Checking feasibility of the following inequalities:
Theta(N)**1 >= Theta(1)
Theta(x)**1 * Theta(N)**-2 <= Theta(1)
Theta(y)**1 * Theta(N)**-1 <= Theta(1)
Theta(x)**1 * Theta(y)**1 * Theta(N)**-4 > Theta(1)
Infeasible by multiplying the following:
Theta(N)**1 >= Theta(1) raised to power 1
Theta(x)**1 * Theta(N)**-2 <= Theta(1) raised to power -1
Theta(y)**1 * Theta(N)**-1 <= Theta(1) raised to power -1
Theta(x)**1 * Theta(y)**1 * Theta(N)**-4 > Theta(1) raised to power 1
Proof complete!

The logarithmic linear programming solver can also handle lower order terms, by a rather brute force branching method:

>>> p = loglinarith_hard_exercise()
Starting proof.  Current proof state:
N: pos_int
x: pos_real
y: pos_real
h1: x <= 2*N**2 + 1
h2: y < 3*N + 4
|- Theta(x)*Theta(y) <= Theta(N)**3
>>> p.use(LogLinarith())
Goal solved by log-linear arithmetic!
Proof complete!

I plan to start developing tools for estimating function space norms of symbolic functions, for instance creating tactics to deploy lemmas such as Holder’s inequality and the Sobolev embedding inequality. It looks like the sympy framework is flexible enough to allow for creating further object classes for these sorts of objects. (Right now, I only have one proof-of-concept lemma to illustrate the framework, the arithmetic mean-geometric mean lemma.)

I am satisfied enough with the basic framework of this proof assistant that I would be open to further suggestions or contributions of new features, for instance by introducing new data types, lemmas, and tactics, or by contributing example problems that ought to be easily solvable by such an assistant, but are currently beyond its ability, for instance due to the lack of appropriate tactics and lemmas.

by Terence Tao at May 13, 2025 06:39 AM

May 11, 2025

Tommaso Dorigo — On Progress

The human race has made huge progress in the past few thousand years, gradually improving the living condition of human beings by learning how to cure illness; improving farming; harvesting, storing, and using energy in several forms; and countless other activities.

Progress is measured over long time scales, and on metrics related to the access to innovations by all, as Ford once noted. So it is natural for us to consider ourselves lucky to have lived "in the best of times".

Why, if you were born 400 years ago, e.g., you would probably never even learn what a hot shower is! And even only 100 years ago you could have been watching powerless as your children died of diseases that today elicit little worry.

by Tommaso Dorigo at May 11, 2025 09:00 PM

Mark Goodsell — Choose France for Science

In the news this week was the joint announcement by the presidents of the European Commission and France of initiatives about welcoming top researchers from abroad, with the aim being especially to encourage researchers from the USA to cross the Atlantic. I've seen some discussion online about this among people I know and thought I'd add a few comments here, for those outside Europe thinking about making such a jump.

Firstly, what is the new initiative? Various programmes have been put in place; on the EU side it seems to be encouraging applications to Marie Curie Fellowships for postdocs and ERC grants. It looks like there is some new money, particularly for Marie Curie Fellowships for incoming researchers. Applying for these is generally good advice, as they are prestigious programs that open the way to a career; in my field a Marie Curie often leads to a permanent position, and an ERC grant is so huge that it opens doors everywhere. In France, the programme seems to be an ANR programme targeting specific strategic fields, so unlikely to be relevant for high-energy physicists (despite the fact that they invited Mark Thomson to speak at the meeting). But France can be a destination for the European programmes, and there are good reasons for choose France as a destination.

So the advice would seem to be to try out life in France with a Marie-Curie Fellowship, and then apply through the usual channels for a permanent position. This is very reasonable, because it makes little sense to move permanently before having some idea of what life and research is actually like here first. I would heartily recommend it. There are several permanent positions available every year in the CNRS at the junior level, but because of the way the CNRS hiring works -- via a central committee, that decides for positions in the whole country -- if someone leaves it is not very easy to replace them, and people job-hopping is a recurrent problem. There is also the possibility for people to enter the CNRS at a senior level, with up to one position available in theoretical physics most years.

I wrote a bit last year where I mentioned some of the great things about the CNRS but I will add a bit now. Firstly, what is it? It is a large organisation that essentially just hires permanent researchers, who work in laboratories throughout the country. Most of these laboratories are hosted by universities, such as my lab (the LPTHE) which is hosted by Sorbonne University. Most of these laboratories are mixed, meaning that they also include university staff, i.e. researchers who also teach undergraduates. University positions have a similar but parallel career to the CNRS, but since the teaching is done in French, and because the positions only open on a rather unpredictable basis, I won't talk about them today. The CNRS positions are 100% research; there is little administrative overhead, and therefore plenty of time to focus on what is important. This is the main advantage of such positions; but also the fact that the organisation of researchers is done into laboratories is a big difference to the Anglo-Saxon model. My lab is relatively small, yet contains a large number of people working in HEP, and this provides a very friendly environment with lots of interesting interactions, without being lost in a labyrinthine organisation or having key decisions taken by people working in vastly different (sub) fields.

The main criticisms I have seen bandied around on social media about the CNRS are that the pay is not competitive, and that CNRS researchers are lazy/do not work. I won't comment about pay, because it's difficult to compare. But there is plenty of oversight by the CNRS committee -- a body of our peers elected by all researchers -- which scrutinises activity, in addition to deciding on hiring and promotions. If people were really sitting on their hands then this would be spotted and nipped in the bud; but the process of doing this is not onerous or intrusive, precisely because it is done by our peers. In fact, the yearly and five-yearly reports serve a useful role in helping people to focus their activities and plan for the next one to five years. There is also evaluation of laboratories and universities (the HCERES, which will now be changed into something else) that however seems sensible: it doesn't seem to lead to the same sort of panic or perverse incentives that the (equivalent) REF seems to induce in the UK, for example.

The people I know are incredibly hard-working and productive. This is, to be fair, also a product of the fact that we have relatively few PhD students compared to other countries. This is partly by design: the philosophy is that it is unfair to train lots of students who can never get permanent positions in the field. As a result, we take good care of our students, and the students we have tend to be good; but since we have the time, we mostly do research ourselves, rather than just being managers.

So the main reason to choose France is to be allowed to do the research you want to do, without managerialisation, bureaucrats or other obstacles interfering. If that sounds appealing, then I suggest getting in touch and/or arranging to visit. A visit to the RPP or one of the national meetings would be a great way to start. The applications for Marie Curie fellowships are open now, and the CNRS competition opens in December with a deadline usually in early January.

by Mark Goodsell at May 11, 2025 05:55 PM

May 09, 2025

Matt von Hippel — There Is No Shortcut to Saying What You Mean

Blogger Andrew Oh-Willeke of Dispatches from Turtle Island pointed me to an editorial in Science about the phrase scientific consensus.

The editorial argues that by referring to conclusions like the existence of climate change or vaccine safety as “the scientific consensus”, communicators have inadvertently fanned the flames of distrust. By emphasizing agreement between scientists, the phrase “scientific consensus” leaves open the question of how that consensus was reached. More conspiracy-minded people imagine shady backroom deals and corrupt payouts, while the more realistic blame incentives and groupthink. If you disagree with “the scientific consensus”, you may thus decide the best way forward is to silence those pesky scientists.

(The link to current events is left as an exercise to the reader, to comment on elsewhere. As usual, please no explicit discussion of politics on this blog!)

Instead of “scientific consensus”, the editorial suggests another term, convergence of evidence. The idea is that by centering the evidence instead of the scientists, the phrase would make it clear that these conclusions are justified by something more than social pressures, and will remain even if the scientists promoting them are silenced.

Oh-Willeke pointed me to another blog post responding to the editorial, which has a nice discussion of how the terms were used historically, showing their popularity over time. “Convergence of evidence” was more popular in the 1950’s, with a small surge in the late 90’s and early 2000’s. “Scientific consensus” rose in the 1980’s and 90’s, lining up with a time when social scientists were skeptical about science’s objectivity and wanted to explore the social reasons why scientists come to agreement. It then fell around the year 2000, before rising again, this time used instead by professional groups of scientists to emphasize their agreement on issues like climate change.

(The blog post then goes on to try to motivate the word “consilience” instead, on the rather thin basis that “convergence of evidence” isn’t interdisciplinary enough, which seems like a pretty silly objection. “Convergence” implies coming in from multiple directions, it’s already interdisciplinary!)

I appreciate “convergence of evidence”, it seems like a useful phrase. But I think the editorial is working from the wrong perspective, in trying to argue for which terms “we should use” in the first place.

Sometimes, as a scientist or an organization or a journalist, you want to emphasize evidence. Is it “a preponderance of evidence”, most but not all? Is it “overwhelming evidence”, evidence so powerful it is unlikely to ever be defeated? Or is it a “convergence of evidence”, evidence that came in slowly from multiple paths, each independent route making a coincidence that much less likely?

But sometimes, you want to emphasize the judgement of the scientists themselves.

Sometimes when scientists agree, they’re working not from evidence but from personal experience: feelings of which kinds of research pan out and which don’t, or shared philosophies that sit deep in how they conceive their discipline. Describing physicists’ reasons for expecting supersymmetry before the LHC turned on as a convergence of evidence would be inaccurate. Describing it as having been a (not unanimous) consensus gets much closer to the truth.

Sometimes, scientists do have evidence, but as a journalist, you can’t evaluate its strength. You note some controversy, you can follow some of the arguments, but ultimately you have to be honest about how you got the information. And sometimes, that will be because it’s what most of the responsible scientists you talked to agreed on: scientific consensus.

As science communicators, we care about telling the truth (as much as we ever can, at any rate). As a result, we cannot adopt blanket rules of thumb. We cannot say, “we as a community are using this term now”. The only responsible thing we can do is to think about each individual word. We need to decide what we actually mean, to read widely and learn from experience, to find which words express our case in a way that is both convincing and accurate. There’s no shortcut to that, no formula where you just “use the right words” and everything turns out fine. You have to do the work, and hope it’s enough.

by 4gravitons at May 09, 2025 04:00 PM

May 08, 2025

Scott Aaronson Cracking the Top Fifty!

I’ve now been blogging for nearly twenty years—through five presidential administrations, my own moves from Waterloo to MIT to UT Austin, my work on algebrization and BosonSampling and BQP vs. PH and quantum money and shadow tomography, the publication of Quantum Computing Since Democritus, my courtship and marriage and the birth of my two kids, a global pandemic, the rise of super-powerful AI and the terrifying downfall of the liberal world order.

Yet all that time, through more than a thousand blog posts on quantum computing, complexity theory, philosophy, the state of the world, and everything else, I chased a form of recognition for my blogging that remained elusive.

Until now.

This week I received the following email:

I emailed regarding your blog Shtetl-Optimized Blog which was selected by FeedSpot as one of the Top 50 Quantum Computing Blogs on the web.

https://bloggers.feedspot.com/quantum_computing_blogs

We recommend adding your website link and other social media handles to get more visibility in our list, get better ranking and get discovered by brands for collaboration.

We’ve also created a badge for you to highlight this recognition. You can proudly display it on your website or share it with your followers on social media.

We’d be thankful if you can help us spread the word by briefly mentioning Top 50 Quantum Computing Blogs in any of your upcoming posts.

Please let me know if you can do the needful.

You read that correctly: Shtetl-Optimized is now officially one of the top 50 quantum computing blogs on the web. You can click the link to find the other 49.

Maybe it’s not unrelated to this new notoriety that, over the past few months, I’ve gotten a massively higher-than-usual volume of emailed solutions to the P vs. NP problem, as well as the other Clay Millennium Problems (sometimes all seven problems at once), as well as quantum gravity and life, the universe, and everything. I now get at least six or seven confident such emails per day.

While I don’t spend much time on this flood of scientific breakthroughs (how could I?), I’d like to note one detail that’s new. Many of the emails now include transcripts where ChatGPT fills in the details of the emailer’s theories for them—unironically, as though that ought to clinch the case. Who said generative AI wasn’t poised to change the world? Indeed, I’ll probably need to start relying on LLMs myself to keep up with the flood of fan mail, hate mail, crank mail, and advice-seeking mail.

Anyway, thanks for reading everyone! I look forward to another twenty years of Shtetl-Optimized, if my own health and the health of the world cooperate.

by Scott at May 08, 2025 09:26 PM

May 06, 2025

Scott Aaronson Opposing SB37

Yesterday, the Texas State Legislature heard public comments about SB37, a bill that would give a state board direct oversight over course content and faculty hiring at public universities, perhaps inspired by Trump’s national crackdown on higher education. (See here or here for coverage.) So, encouraged by a friend in the history department, I submitted the following public comment, whatever good it will do.

I’m a computer science professor at UT, although I’m writing in my personal capacity. For 20 years, on my blog and elsewhere, I’ve been outspoken in opposing woke radicalism on campus and (especially) obsessive hatred of Israel that often veers into antisemitism, even when that’s caused me to get attacked from my left. Nevertheless, I write to strongly oppose SB37 in its current form, because of my certainty that no world-class research university can survive ceding control over its curriculum and faculty hiring to the state. If this bill passes, for example, it will severely impact my ability to recruit the most talented computer scientists to UT Austin, if they have competing options that will safeguard their academic freedom as traditionally conceived. Even if our candidates are approved, the new layer of bureaucracy will make it difficult and slow for us to do anything. For those concerned about intellectual diversity in academia, a much better solution would include safeguarding tenure and other protections for faculty with heterodox views, and actually enforcing content-neutral time, place, and manner rules for protests and disruptions. UT has actually done a better job on these things than many other universities in the US, and could serve as a national model for how viewpoint diversity can work — but not under an intolerably stifling regime like the one proposed by this bill.

by Scott at May 06, 2025 06:21 PM

May 05, 2025

Peter Rohde Protected: Random junk

by Peter Rohde at May 05, 2025 10:37 PM

Jordan Ellenberg — A paleontologist, a scientist, a tree, decided, God, Superman, the leveler, the voice of Sarah Strickland’s rage, the walrus

Are the things that “I am,” according to songs in my iTunes library.

by JSE at May 05, 2025 07:45 PM

Scott Aaronson Quantum! AI! Everything but Trump!

Grant Sanderson, of 3blue1brown, has put up a phenomenal YouTube video explaining Grover’s algorithm, and dispelling the fundamental misconception about quantum computing, that QC works simply by “trying all the possibilities in parallel.” Let me not futz around: this video explains, in 36 minutes, what I’ve tried to explain over and over on this blog for 20 years … and it does it better. It’s a masterpiece. Yes, I consulted with Grant for this video (he wanted my intuitions for “why is the answer √N?”), and I even have a cameo at the end of it, but I wish I had made the video. Damn you, Grant!

The incomparably great, and absurdly prolific, blogger Zvi Mowshowitz and yours truly spend 1 hour and 40 minutes discussing AI existential risk, education, blogging, and more. I end up “interviewing” Zvi, who does the majority of the talking, which is fine by me, as he has many important things to say! (Among them: his searing critique of those K-12 educators who see it as their life’s mission to prevent kids from learning too much too fast—I’ve linked his best piece on this from the header of this blog.) Thanks so much to Rick Coyle for arranging this conversation.

Progress in quantum complexity theory! In 2000, John Watrous showed that the Group Non-Membership problem is in the complexity class QMA (Quantum Merlin-Arthur). In other words, if some element g is not contained in a given subgroup H of an exponentially large finite group G, which is specified via a black box, then there’s a short quantum proof that g∉H, with only ~log|G| qubits, which can be verified on a quantum computer in time polynomial in log|G|. This soon raised the question of whether Group Non-Membership could be used to separate QMA from QCMA by oracles, where QCMA (Quantum Classical Merlin Arthur), defined by Aharonov and Naveh in 2002, is the subclass of QMA where the proof needs to be classical, but the verification procedure can still be quantum. In other words, could Group Non-Membership be the first non-quantum example where quantum proofs actually help?

In 2006, alas, Greg Kuperberg and I showed that the answer was probably “no”: Group Non-Membership has “polynomial QCMA query complexity.” This means that there’s a QCMA protocol for the problem where Arthur makes only polylog|G| quantum queries to the group oracle—albeit, possibly an exponential in log|G| number of quantum computation steps besides that! To prove our result, Greg and I needed to make mild use of the Classification of Finite Simple Groups, one of the crowning achievements of 20th-century mathematics (its proof is about 15,000 pages long). We conjectured (but couldn’t prove) that someone else, who knew more about the Classification than we did, could show that Group Non-Membership was simply in QCMA outright.

Now, after almost 20 years, François Le Gall, Harumichi Nishimura, and Dhara Thakkar have finally proven our conjecture—showing that Group Order, and therefore also Group Non-Membership, are indeed in QCMA. They did indeed need to use the Classification, doing one thing for almost all finite groups covered by the Classification, but a different thing for groups of “Ree type” (whatever those are).

Interestingly, the Group Membership problem had also been a candidate for separating BQP/qpoly, or quantum polynomial time with polynomial-size quantum advice—my personal favorite complexity class—from BQP/poly, or the same thing with polynomial-size classical advice. And it might conceivably still be! The authors explain to me that their protocol doesn’t put Group Membership (with group G and subgroup H depending only on the input length n) into BQP/poly, the reason being that their short classical witnesses for g∉H depend on both g and H, in contrast to Watrous’s quantum witnesses which depended only on H. So there’s still plenty that’s open here! Actually, for that matter, I don’t know of good evidence that the entire Group Membership problem isn’t in BQP—i.e., that quantum computers can’t just solve the whole thing outright, with no Merlins or witnesses in sight!

Anyway, huge congratulations to Le Gall, Nishimura, and Thakkar for peeling back our ignorance of these matters a bit further! Reeeeeeeee!
Potential big progress in quantum algorithms! Vittorio Giovannetti, Seth Lloyd, and Lorenzo Maccone (GLM) have given what they present as a quantum algorithm to estimate the determinant of an n×n matrix A, exponentially faster in some contexts than we know how to do it classically.

[Update (May 5): In the comments, Alessandro Luongo shares a paper where he and Changpeng Shao describe what appears to be essentially the same algorithm back in 2020.]

The algorithm is closely related to the 2008 HHL (Harrow-Hassidim-Lloyd) quantum algorithm for solving systems of linear equations. Which means that anyone who knows the history of this class of quantum algorithms knows to ask immediately: what’s the fine print? A couple weeks ago, when I visited Harvard and MIT, I had a chance to catch up with Seth Lloyd, so I asked him, and he kindly told me. Firstly, we assume the matrix A is Hermitian and positive semidefinite. Next, we assume A is sparse, and not only that, but there’s a QRAM data structure that points to its nonzero entries, so you don’t need to do Grover search or the like to find them, and can query them in coherent superposition. Finally, we assume that all the eigenvalues of A are at least some constant λ>0. The algorithm then estimates det(A), to multiplicative error ε, in time that scales linearly with log(n), and polynomially with 1/λ and 1/ε.

Now for the challenge I leave for ambitious readers: is there a classical randomized algorithm to estimate the determinant under the same assumptions and with comparable running time? In other words, can the GLM algorithm be “Ewinized”? Seth didn’t know, and I think it’s a wonderful crisp open question! On the one hand, if Ewinization is possible, it wouldn’t be the first time that publicity on this blog had led to the brutal murder of a tantalizing quantum speedup. On the other hand … well, maybe not! I also consider it possible that the problem solved by GLM—for exponentially-large, implicitly-specified matrices A—is BQP-complete, as for example was the general problem solved by HHL. This would mean, for example, that one could embed Shor’s factoring algorithm into GLM, and that there’s no hope of dequantizing it unless P=BQP. (Even then, though, just like with the HHL algorithm, we’d still face the question of whether the GLM algorithm was “independently useful,” or whether it merely reproduced quantum speedups that were already known.)

Anyway, quantum algorithms research lives! So does dequantization research! If basic science in the US is able to continue at all—the thing I promised not to talk about in this post—we’ll have plenty to keep us busy over the next few years.

by Scott at May 05, 2025 07:29 PM

Doug Natelson — Updates, thoughts about industrial support of university research

Lots of news in the last few days regarding federal funding of university research:

NSF has now frozen all funding for new and continuing awards. This is not good; just how bad it is depends on the definition of "until further notice".
Here is an open letter from the NSF employees union to the basically-silent-so-far National Science Board, asking for the NSB to support the agency.
Here is a grass roots SaveNSF website with good information and suggestions for action - please take a look.
NSF also wants to cap indirect cost rates at 15% for higher ed institutions for new awards. This will almost certainly generate a law suit from the AAU and others.
Speaking of the AAU, last week there was a hearing in the Massachusetts district court regarding the lawsuits about the DOE setting indirect cost rates to 15% for active and new awards. There had already been a temporary restraining order in place nominally stopping the change; the hearing resulted in that order being extended "until a further order is issued resolving the request for a temporary injunction." (See here, the entry for April 29.)
In the meantime, the presidential budget request has come out, and if enacted it would be devastating to the science agencies. Proposed cuts include 55% to NSF, 40% to NIH, 33% to USGS, 25% to NOAA, etc. If these cuts went through, we are taking about more than $35B, at a rough eyeball estimate.
And here is a letter from former NSF directors and NSB chairs to the appropriators in Congress, asking them to ignore that budget request and continue to support government sponsored science and engineering research.

Unsurprisingly, during these times there is a lot of talk about the need for universities to diversify their research portfolios - that is, expanding non-federally-supported ways to continue generating new knowledge, training the next generation of the technically literate workforce, and producing IP and entrepreneurial startup companies. (Let's take it as read that it would be economically and societally desirable to continue these things, for the purposes of this post.)

Philanthropy is great, and foundations do fantastic work in supporting university research, philanthropy can't come close to making up for sharp drawdowns of federal support. The numbers just don't work. The endowment of the Moore Foundation, for example, is around $10B, implying an annual payout of $500M or so, which is great but around 1.4% of the cuts being envisioned.

Industry seems like the only non-governmental possibility that could in principle muster the resources that could make a large-scale difference. Consider the estimated profits (not revenues) of different industrial sectors. The US semiconductor market had revenues last year of around $500B with an annualized net margin of around 17%, giving $85B/yr of profit. US aerospace and defense similarly have an annual profit of around $70B. The financial/banking sector, which has historically benefitted greatly from PhD-trained quants, has an annual net income of $250B. I haven't even listed numbers for the energy and medical sectors, because those are challenging to parse (but large).

All of those industries have been helped greatly by university research, directly and indirectly. It's the source of trained people. It's the source of initial work that is too long-term for corporations to be able to support without short-time-horizon shareholders getting annoyed. It's the source of many startup companies that sometimes grow and other times get gobbled up by bigger fish.

Encouraging greater industrial sponsorship of university research is a key challenge. The value proposition must be made clear to both the companies and universities. The market is unforgiving and exerts pressure to worry about the short term not the long term. Given how Congress is functioning, it does not look like there are going to be changes to the tax code put in place that could incentivize long term investment.

Cracking this and meaningfully growing the scale of industrial support for university research could be enormously impactful. Something to ponder.

by Douglas Natelson at May 05, 2025 02:47 PM

Terence Tao — Orders of infinity

Many problems in analysis (as well as adjacent fields such as combinatorics, theoretical computer science, and PDE) are interested in the order of growth (or decay) of some quantity ${X}$ that depends on one or more asymptotic parameters (such as ${N}$ ) – for instance, whether the quantity ${X}$ grows or decays linearly, quadratically, polynomially, exponentially, etc. in ${N}$ . In the case where these quantities grow to infinity, these growth rates had once been termed “orders of infinity” – for instance, in the 1910 book of this name by Hardy – although this term has fallen out of use in recent years. (Hardy fields are still a thing, though.)

In modern analysis, asymptotic notation is the preferred device to organize orders of infinity. There are a couple of flavors of this notation, but here is one such (a blend of Hardy’s notation and Landau’s notation). Formally, we need a parameter space ${\Omega}$ equipped with a non-principal filter ${{\mathcal F}}$ that describes the subsets of parameter space that are “sufficiently large” (e.g., the cofinite (Fréchet) filter on ${{\bf N}}$ , or the cocompact filter on ${{\bf R}}$ ). We will use ${N}$ to denote elements of this filter; thus, an assertion holds for sufficiently large ${N}$ if and only if it holds for all ${N}$ in some element ${U}$ of the filter ${{\mathcal F}}$ . Given two positive quantities ${X = X(N), Y = Y(N)}$ that are defined for sufficiently large ${N \in \Omega}$ , one can then define the following notions:

(i) We write ${X = O(Y)}$ , ${X \lesssim Y}$ , or ${Y \gtrsim X}$ (and sometimes ${Y = \Omega(X)}$ ) if there exists a constant ${C>0}$ such that ${X(N) \leq CY(N)}$ for all sufficiently large ${N}$ .
(ii) We write ${X = o(Y)}$ , ${X \ll Y}$ , or ${Y \gg X}$ (and sometimes ${Y = \omega(X)}$ ) if, for every ${\varepsilon>0}$ , one has ${X(N) \leq \varepsilon Y(N)}$ for all sufficiently large ${N}$ .
(iii) We write ${X \asymp Y}$ (and sometimes ${X \sim Y}$ or ${Y = \Theta(X)}$ ) if ${X \lesssim Y \lesssim X}$ , or equivalently if there exist constants ${C, c > 0}$ such that ${c Y(N) \leq X(N) \leq C Y(N)}$ for all sufficiently large ${N}$ .

We caution that in analytic number theory and adjacent fields, the slightly different notation of Vinogradov is favored, in which ${X \ll Y}$ would denote the concept (i) instead of (ii), and ${X \sim Y}$ would denote a fourth concept ${X = (1+o(1)) Y}$ instead of (iii). However, we will use the Hardy-Landau notation exclusively in this blog post.

Anyone who works with asymptotic notation for a while will quickly recognize that it enjoys various algebraic properties akin to the familiar algebraic properties of order ${<}$ on the real line. For instance, the symbols ${\lesssim, \ll, \gg, \gtrsim}$ behave very much like ${\leq}$ , ${<}$ , ${>}$ , ${\gtrsim}$ , with properties such as the following:

If ${X \lesssim Y}$ and ${Y \lesssim Z}$ , then ${X \lesssim Z}$ .
${X \lesssim Y}$ if and only if ${XZ \lesssim YZ}$ .
If ${N}$ is restricted to a sequence, then (after passing to a subsequence if necessary), exactly one of ${X \ll Y}$ , ${X \asymp Y}$ , and ${X \gg Y}$ is true.

One also has the “tropical” property ${X+Y \asymp \max(X,Y)}$ , making asymptotic notation a kind of “tropical algebra“.

However, in contrast with other standard algebraic structures (such as ordered fields) that blend order and arithmetic operations, the precise laws of orders of infinity are usually not written down as a short list of axioms. Part of this is due to cultural differences between analysis and algebra – as discussed in this essay by Gowers, analysis is often not well suited to the axiomatic approach to mathematics that algebra benefits so much from. But another reason is due to our orthodox implementation of analysis via “epsilon-delta” type concepts, such as the notion of “sufficiently large” used above, which notoriously introduces a large number of both universal and existential quantifiers into the subject (for every epsilon, there exists a delta…) which tends to interfere with the smooth application of algebraic laws (which are optimized for the universal quantifier rather than the existential quantifier).

But there is an alternate approach to analysis, namely nonstandard analysis, which rearranges the foundations so that many of quantifiers (particularly the existential ones) are concealed from view (usually via the device of ultrafilters). This makes the subject of analysis considerably more “algebraic” in nature, as the “epsilon management” that is so prevalent in orthodox analysis is now performed much more invisibly. For instance, as we shall see, in the nonstandard framework, orders of infinity acquire the algebraic structure of a totally ordered vector space that also enjoys a completeness property reminiscent, though not identical to, the completeness of the real numbers. There is also a transfer principle that allows one to convert assertions in orthodox asymptotic notation into logically equivalent assertions about nonstandard orders of infinity, allowing one to then prove asymptotic statements in a purely algebraic fashion. There is a price to pay for this “algebrization” of analysis; the spaces one works with become quite large (in particular, they tend to be “inseparable” and not “countably generated” in any reasonable fashion), and it becomes difficult to extract explicit constants ${C}$ (or explicit decay rates) from the asymptotic notation. However, there are some cases in which the tradeoff is worthwhile. For instance, symbolic computations tend to be easier to perform in algebraic settings than in orthodox analytic settings, so formal computations of orders of infinity (such as the ones discussed in the previous blog post) could benefit from the nonstandard approach. (See also my previous posts on nonstandard analysis for more discussion about these tradeoffs.)

Let us now describe the nonstandard approach to asymptotic notation. With the above formalism, the switch from standard to nonstandard analysis is actually quite simple: one assumes that the asymptotic filter ${{\mathcal F}}$ is in fact an ultrafilter. In terms of the concept of “sufficiently large”, this means adding the following useful axiom:

Given any predicate ${P(N)}$ , exactly one of the two statements “ ${P(N)}$ holds for sufficiently large ${N}$ ” and “ ${P(N)}$ does not hold for sufficiently large ${N}$ ” is true.

This can be compared with the situation with, say, the Fréchet filter on the natural numbers ${{\bf N}}$ , in which one has to insert some qualifier such as “after passing to a subsequence if necessary” in order to make the above axiom true.

The existence of an ultrafilter requires some weak version of the axiom of choice (specifically, the ultrafilter lemma), but for this post we shall just take the existence of ultrafilters for granted.

We can now define the nonstandard orders of infinity ${{\mathcal O}}$ to be the space of all non-negative functions ${X(N)}$ defined for sufficiently large ${N \in \Omega}$ , modulo the equivalence relation ${\asymp}$ defined previously. That is to say, a nonstandard order of infinity is an equivalence class

$\displaystyle \Theta(X) := \{ Y : U \rightarrow {\bf R}^+: X \asymp Y \}$

of functions ${Y: U \rightarrow {\bf R}^+}$ defined on elements ${U}$ of the ultrafliter. For instance, if ${\Omega}$ is the natural numbers, then ${\Theta(N)}$ itself is an order of infinity, as is ${\Theta(N^2)}$ , ${\Theta(e^N)}$ , ${\Theta(1/N)}$ , ${\Theta(N \log N)}$ , and so forth. But we exclude ${0}$ ; it will be important for us that the order of infinity is strictly positive for all sufficiently large ${N}$ .

We can place various familiar algebraic operations on ${{\mathcal O}}$ :

Addition. We define ${\Theta(X)+\Theta(Y) :=\Theta(X+Y)}$ . It is easy to see that this is well-defined, by verifying that if ${X \asymp X'}$ and ${Y \asymp Y'}$ , then ${X+Y \asymp X'+Y'}$ . However, because of our positivity requirement, we do not define subtraction on ${{\mathcal O}}$ .
Multiplication and division We define ${\Theta(X) \times \Theta(Y) := \Theta(XY)}$ and ${\Theta(X)/\Theta(Y) = \Theta(X/Y)}$ ; we do not need to worry about division by zero, thanks to the positivity requirement. Again it is easy to verify this is well-defined.
Scalar exponentiation If ${\lambda}$ is a real number, we define ${\Theta(X)^\lambda := \Theta(X^\lambda)}$ . Again, this is easily checked to be well-defined.
Order We define ${\Theta(X) \leq \Theta(Y)}$ if ${X \lesssim Y}$ , and ${\Theta(X) < \Theta(Y)}$ if ${X \ll Y}$ . Again, this is easily checked to be well-defined. (And the ultrafilter axiom ensures that ${\Theta(X) \leq \Theta(Y)}$ holds iff exactly one of ${\Theta(X)=\Theta(Y)}$ and ${\Theta(X) < \Theta(Y)}$ holds.)

With these operations, combined with the ultrafilter axiom, we see that ${{\mathcal O}}$ obeys the laws of many standard algebraic structures, the proofs of which we leave as exercises for the reader:

${({\mathcal O}, \leq)}$ is a totally ordered set.
In fact, ${({\mathcal O}, \leq, \Theta(1), \times, (\cdot)^{\cdot})}$ is a totally ordered vector space, with ${\Theta(1)}$ playing the role of the zero vector, multiplication ${(\Theta(X), \Theta(Y)) \mapsto \Theta(X) \times \Theta(Y)}$ playing the role of vector addition, and scalar exponentiation ${(\lambda, \Theta(X)) \mapsto \Theta(X)^\lambda}$ playing the role of scalar multiplication. (Of course, division would then play the role of vector subtraction.) To avoid confusion, one might refer to ${{\mathcal O}}$ as a log-vector space rather than a vector space to emphasize the fact that the vector structure is coming from multiplication (and exponentiation) rather than addition (and multiplication). Ordered log-vector spaces may seem like a strange and exotic concept, but they are actually already studied implicitly in analysis, albeit under the guise of other names such as log-convexity.
${({\mathcal O}, +, \times, 1)}$ is a semiring (albeit one without an additive identity element), which is idempotent: ${\Theta(X) + \Theta(X) = \Theta(X)}$ for all ${\Theta(X) \in {\mathcal O}}$ .
More generally, addition can be described in purely order-theoretic terms: ${\Theta(X) + \Theta(Y) = \max(\Theta(X), \Theta(Y))}$ for all ${\Theta(X), \Theta(Y) \in {\mathcal O}}$ . (It would therefore be natural to call ${{\mathcal O}}$ a tropical semiring, although the precise axiomatization of this term does not appear to be fully standardized currently.)

The ordered (log-)vector space structure of ${{\mathcal O}}$ in particular opens up the ability to prove asymptotic implications by (log-)linear programming; this was implicitly used in my previous post. One can also use the language of (log-)linear algebra to describe further properties of various orders of infinity. For instance, if ${\Omega}$ is the natural numbers, we can form the subspace

$\displaystyle N^{O(1)} := \bigcup_{k \geq 0} [\Theta(N)^{-k}, \Theta(N)^k]$

of ${{\mathcal O}}$ consisting of those orders of infinity ${\Theta(X)}$ which are of polynomial type in the sense that ${N^{-C} \lesssim X \lesssim N^C}$ for some ${C>0}$ ; this is then a (log)-vector subspace of ${{\mathcal O}}$ , and has a canonical (log-)linear surjection ${\mathrm{ord}: N^{O(1)} \rightarrow {\bf R}}$ that assigns to each order of infinity ${\Theta(X)}$ of polynomial type the unique real number ${\alpha}$ such that ${X(N) = N^{\alpha+o(1)}}$ , that is to say for all ${\varepsilon>0}$ one has ${N^{\alpha-\varepsilon} \lesssim X(N) \lesssim N^{\alpha+\varepsilon}}$ for all sufficiently large ${N}$ . (The existence of such an ${\alpha}$ follows from the ultrafilter axiom and by a variant of the proof of the Bolzano–Weierstrass theorem; the uniqueness is also easy to establish.) The kernel ${N^{o(1)}}$ of this surjection is then the log-subspace of quasilogarithmic orders of infinity – ${\Theta(X)}$ for which ${N^{-\varepsilon} \lesssim X \lesssim N^\varepsilon}$ for all ${\varepsilon>0}$ .

In addition to the above algebraic properties, the nonstandard orders of infinity ${{\mathcal O}}$ also enjoy a completeness property that is reminiscent of the completeness of the real numbers. In the reals, it is true that any nested sequence ${K_1 \supset K_2 \supset \dots}$ of non-empty closed intervals has a non-empty intersection, which is a property closely tied to the more familiar definition of completeness as the assertion that Cauchy sequences are always convergent. This claim of course fails for open intervals: for instance, ${(0,1/n)}$ for ${n=1,2,\dots}$ is a nested sequence of non-empty open intervals whose intersection is empty. However, in the nonstandard orders of infinity ${{\mathcal O}}$ , we have the same property for both open and closed intervals!

Lemma 1 (Completeness for arbitrary intervals) Let ${I_1 \supset I_2 \supset \dots}$ be a nested sequence of non-empty intervals in ${{\mathcal O}}$ (which can be open, closed, or half-open). Then the intersection ${\bigcap_{n=1}^\infty I_n}$ is non-empty.

Proof: For sake of notation we shall assume the intervals are open intervals ${I_n = (\Theta(X_n), \Theta(Y_n))}$ , although much the same argument would also work for closed or half-open intervals (and then by the pigeonhole principle one can then handle nested sequences of arbitrary intervals); we leave this extension to the interested reader.

Pick an element ${\Theta(Z_n)}$ of each ${I_n}$ , then we have ${X_m \ll Z_n \ll Y_m}$ whenever ${m \leq n}$ . In particular, one can find a set ${U_n}$ in the ultrafilter such that

$\displaystyle n X_m(N) \leq Z_n(N) \leq \frac{1}{n} Y_m(N)$

whenever ${N \in U_n}$ and ${m \leq n}$ , and by taking suitable intersections that these sets are nested: ${U_1 \supset U_2 \supset \dots}$ . If we now define ${Z(N)}$ to equal ${Z_n(N)}$ for ${N \in U_n \backslash U_{n+1}}$ (and leave ${Z}$ undefined outside of ${U_1}$ ), one can check that ${X_m \ll Z \ll Y_m}$ for all ${m}$ , thus ${\Theta(Z)}$ lies in the intersection of all the ${I_n}$ , giving the claim. $\Box$

This property is closely related to the countable saturation and overspill properties in nonstandard analysis. From this property one might expect that ${{\mathcal O}}$ has better topological structure than say the reals. This is not exactly true, because unfortunately ${{\mathcal O}}$ is not metrizable (or separable, or first or second countable). It is perhaps better to view ${{\mathcal O}}$ as obeying a parallel type of completeness that is neither strictly stronger nor strictly weaker than the more familiar notion of metric completeness, but is otherwise rather analogous.

by Terence Tao at May 05, 2025 02:46 PM

May 04, 2025

Tommaso Dorigo — The Night Sky From Atacama

For the third time in 9 years I am visiting San Pedro de Atacama, a jewel in the middle of nowhere in northern Chile. The Atacama desert is a stretch of extremely dry land at high altitude, which makes it exceptionally attractive for astronomical activities. In its whereabouts, e.g., are some of the largest telescopes in the world - the Cerro Paranal Very Large Telescope (VLT), and the planned Extremely Large Telescope (ELT) now being built in Cerro Armazones. And I have news that an even larger telescope, tentatively dubbed RLT for Ridiculously Large Telescope, is being planned in the region...

by Tommaso Dorigo at May 04, 2025 02:46 PM

May 03, 2025

Peter Rohde Living with Mental Illness in Academia

An article I wrote for Voices of Academia back in 2022.

Leading by Example: Living with Mental Illness in Academia by Dr Peter Rohde

by Peter Rohde at May 03, 2025 07:14 PM

May 02, 2025

Terence Tao — A proof of concept tool to verify estimates

This post was inspired by some recent discussions with Bjoern Bringmann.

Symbolic math software packages are highly developed for many mathematical tasks in areas such as algebra, calculus, and numerical analysis. However, to my knowledge we do not have similarly sophisticated tools for verifying asymptotic estimates – inequalities that are supposed to hold for arbitrarily large parameters, with constant losses. Particularly important are functional estimates, where the parameters involve an unknown function or sequence (living in some suitable function space, such as an ${L^p}$ space); but for this discussion I will focus on the simpler situation of asymptotic estimates involving a finite number of positive real numbers, combined using arithmetic operations such as addition, multiplication, division, exponentiation, and minimum and maximum (but no subtraction). A typical inequality here might be the weak arithmetic mean-geometric mean inequality

$\displaystyle (abc)^{1/3} \lesssim a+b+c \ \ \ \ \ (1)$

where ${a,b,c}$ are arbitrary positive real numbers, and the ${\lesssim}$ here indicates that we are willing to lose an unspecified (multiplicative) constant in the estimates.

I have wished in the past (e.g., in this MathOverflow answer) for a tool that could automatically determine whether such an estimate was true or not (and provide a proof if true, or an asymptotic counterexample if false). In principle, simple inequalities of this form could be automatically resolved by brute force case splitting. For instance, with (1), one first observes that ${a+b+c}$ is comparable to ${\max(a,b,c)}$ up to constants, so it suffices to determine if

$\displaystyle (abc)^{1/3} \lesssim \max(a,b,c). \ \ \ \ \ (2)$

Next, to resolve the maximum, one can divide into three cases: ${a \gtrsim b,c}$ ; ${b \gtrsim a,c}$ ; and ${c \gtrsim a,b}$ . Suppose for instance that ${a \gtrsim b,c}$ . Then the estimate to prove simplifies to

$\displaystyle (abc)^{1/3} \lesssim a,$

and this is (after taking logarithms) a positive linear combination of the hypotheses ${a \gtrsim b}$ , ${a \gtrsim c}$ . The task of determining such a linear combination is a standard linear programming task, for which many computer software packages exist.

Any single such inequality is not too difficult to resolve by hand, but there are applications in which one needs to check a large number of such inequalities, or split into a large number of cases. I will take an example at random from an old paper of mine (adapted from the equation after (51), and ignoring some epsilon terms for simplicity): I wanted to establish the estimate

$\displaystyle \frac{\langle N_2 \rangle^{1/2}}{\langle N_1 \rangle^{1/4} L_1^{1/2} L_2^{1/2} } L_{\min}^{1/2} N^{-1} (N_1 N_2 N_3)^{1/2} \lesssim 1 \ \ \ \ \ (3)$

for any ${N_1,N_2,N_3,L_1,L_2,L_3 > 0}$ obeying the constraints

$\displaystyle N_{\max} \sim N_{\mathrm{med}} \sim N; \quad L_{\max} \sim L_{\mathrm{med}} \gtrsim N_1 N_2 N_3$

where ${N_{\max}}$ , ${N_{\mathrm{med}}}$ , and ${N_{\min}}$ are the maximum, median, and minimum of ${N_1, N_2, N_3}$ respectively, and similarly for ${L_{\max}}$ , ${L_{\mathrm{med}}}$ , and ${L_{\min}}$ , and ${\langle N \rangle := (1+N^2)^{1/2}}$ . This particular bound could be dispatched in three or four lines from some simpler inequalities; but it took some time to come up with those inequalities, and I had to do a dozen further inequalities of this type. This is a task that seems extremely ripe for automation, particularly with modern technology.

Recently, I have been doing a lot more coding (in Python, mostly) than in the past, aided by the remarkable facility of large language models to generate initial code samples for many different tasks, or to autocomplete partially written code. For the most part, I have restricted myself to fairly simple coding tasks, such as computing and then plotting some mildly complicated mathematical functions, or doing some rudimentary data analysis on some dataset. But I decided to give myself the more challenging task of coding a verifier that could handle inequalities of the above form. After about four hours of coding, with frequent assistance from an LLM, I was able to produce a proof of concept tool for this, which can be found at this Github repository. For instance, to verify (1), the relevant Python code is

    a = Variable("a")
    b = Variable("b")
    c = Variable("c")
    assumptions = Assumptions()
    assumptions.can_bound((a * b * c) ** (1 / 3), max(a, b, c))

and the (somewhat verbose) output verifying the inequality is

Checking if we can bound (((a * b) * c) ** 0.3333333333333333) by max(a, b, c) from the given axioms.
We will split into the following cases:
[[b <~ a, c <~ a], [a <~ b, c <~ b], [a <~ c, b <~ c]]
Trying case: ([b <~ a, c <~ a],)
Simplify to proving (((a ** 0.6666666666666667) * (b ** -0.3333333333333333)) * (c ** -0.3333333333333333)) >= 1.
Bound was proven true by multiplying the following hypotheses :
b <~ a raised to power 0.33333333
c <~ a raised to power 0.33333333
Trying case: ([a <~ b, c <~ b],)
Simplify to proving (((b ** 0.6666666666666667) * (a ** -0.3333333333333333)) * (c ** -0.3333333333333333)) >= 1.
Bound was proven true by multiplying the following hypotheses :
a <~ b raised to power 0.33333333
c <~ b raised to power 0.33333333
Trying case: ([a <~ c, b <~ c],)
Simplify to proving (((c ** 0.6666666666666667) * (a ** -0.3333333
333333333)) * (b ** -0.3333333333333333)) >= 1.
Bound was proven true by multiplying the following hypotheses :
a <~ c raised to power 0.33333333
b <~ c raised to power 0.33333333
Bound was proven true in all cases!

This is of course an extremely inelegant proof, but elegance is not the point here; rather, that it is automated. (See also this recent article of Heather Macbeth for how proof writing styles change in the presence of automated tools, such as formal proof assistants.)

The code is close to also being able to handle more complicated estimates such as (3); right now I have not written code to properly handle hypotheses such as ${N_{\max} \sim N_{\mathrm{med}} \sim N}$ that involve complex expressions such as ${N_{\max} = \max(N_1,N_2,N_3)}$ , as opposed to hypotheses that only involve atomic variables such as ${N_1}$ , ${N_2, N_3}$ , but I can at least handle such complex expressions in the left and right-hand sides of the estimate I am trying to verify.

In any event, the code, being a mixture of LLM-generated code and my own rudimentary Python skills, is hardly an exemplar of efficient or elegant coding, and I am sure that there are many expert programmers who could do a much better job. But I think this is proof of concept that a more sophisticated tool of this form could be quite readily created to do more advanced tasks. One such example task was the one I gave in the above MathOverflow question, namely being able to automatically verify a claim such as

$\displaystyle \sum_{d=0}^\infty \frac{2d+1}{2h^2 (1 + \frac{d(d+1)}{h^2}) (1 + \frac{d(d+1)}{h^2m^2})^2} \lesssim 1 + \log(m^2)$

for all ${h,m > 0}$ . Another task would be to automatically verify the ability to estimate some multilinear expression of various functions, in terms of norms of such functions in standard spaces such as Sobolev spaces; this is a task that is particularly prevalent in PDE and harmonic analysis (and can frankly get somewhat tedious to do by hand). As speculated in that MO post, one could eventually hope to also utilize AI to assist in the verification process, for instance by suggesting possible splittings of the various sums or integrals involved, but that would be a long-term objective.

This sort of software development would likely best be performed as a collaborative project, involving both mathematicians and expert programmers. I would be interested to receive advice on how best to proceed with such a project (for instance, would it make sense to incorporate such a tool into an existing platform such as SageMATH), and what features for a general estimate verifier would be most desirable for mathematicians. One thing on my wishlist is the ability to give a tool an expression to estimate (such as a multilinear integral of some unknown functions), as well as a fixed set of tools to bound that integral (e.g., splitting the integral into pieces, integrating by parts, using the Hölder and Sobolev inequalities, etc.), and have the computer do its best to optimize the bound it can produce with those tools (complete with some independently verifiable proof certificate for its output). One could also imagine such tools having the option to output their proof certificates in a formal proof assistant language such as Lean. But perhaps there are other useful features that readers may wish to propose.

by Terence Tao at May 02, 2025 08:33 PM

Matt von Hippel — Experiments Should Be Surprising, but Not Too Surprising

People are talking about colliders again.

This year, the European particle physics community is updating its shared plan for the future, the European Strategy for Particle Physics. A raft of proposals at the end of March stirred up a tail of public debate, focused on asking what sort of new particle collider should be built, and discussing potential reasons why.

That discussion, in turn, has got me thinking about experiments, and how they’re justified.

The purpose of experiments, and of science in general, is to learn something new. The more sure we are of something, the less reason there is to test it. Scientists don’t check whether the Sun rises every day. Like everyone else, they assume it will rise, and use that knowledge to learn other things.

You want your experiment to surprise you. But to design an experiment to surprise you, you run into a contradiction.

Suppose that every morning, you check whether the Sun rises. If it doesn’t, you will really be surprised! You’ll have made the discovery of the century! That’s a really exciting payoff, grant agencies should be lining up to pay for…

Well, is that actually likely to happen, though?

The same reasons it would be surprising if the Sun stopped rising are reasons why we shouldn’t expect the Sun to stop rising. A sunrise-checking observatory has incredibly high potential scientific reward…but an absurdly low chance of giving that reward.

Ok, so you can re-frame your experiment. You’re not hoping the Sun won’t rise, you’re observing the sunrise. You expect it to rise, almost guaranteed, so your experiment has an almost guaranteed payoff.

But what a small payoff! You saw exactly what you expected, there’s no science in that!

By either criterion, the “does the Sun rise” observatory is a stupid experiment. Real experiments operate in between the two extremes. They also mix motivations. Together, that leads to some interesting tensions.

What was the purpose of the Large Hadron Collider?

There were a few things physicists were pretty sure of, when they planned the LHC. Previous colliders had measured W bosons and Z bosons, and their properties made it clear that something was missing. If you could collide protons with enough energy, physicists were pretty sure you’d see the missing piece. Physicists had a reasonably plausible story for that missing piece, in the form of the Higgs boson. So physicists could be pretty sure they’d see something, and reasonably sure it would be the Higgs boson.

If physicists expected the Higgs boson, what was the point of the experiment?

First, physicists expected to see the Higgs boson, but they didn’t expect it to have the mass that it did. In fact, they didn’t know anything about the particle’s mass, besides that it should be low enough that the collider could produce it, and high enough that it hadn’t been detected before. The specific number? That was a surprise, and an almost-inevitable one. A rare creature, an almost-guaranteed scientific payoff.

I say almost, because there was a second point. The Higgs boson didn’t have to be there. In fact, it didn’t have to exist at all. There was a much bigger potential payoff, of noticing something very strange, something much more complicated than the straightforward theory most physicists had expected.

(Many people also argued for another almost-guaranteed payoff, and that got a lot more press. People talked about finding the origin of dark matter by discovering supersymmetric particles, which they argued was almost guaranteed due to a principle called naturalness. This is very important for understanding the history…but it’s an argument that many people feel has failed, and that isn’t showing up much anymore. So for this post, I’ll leave it to the side.)

This mix, of a guaranteed small surprise and the potential for a very large surprise, was a big part of what made the LHC make sense. The mix has changed a bit for people considering a new collider, and it’s making for a rougher conversation.

Like the LHC, most of the new collider proposals have a guaranteed payoff. The LHC could measure the mass of the Higgs, these new colliders will measure its “couplings”: how strongly it influences other particles and forces.

Unlike the LHC, though, this guarantee is not a guaranteed surprise. Before building the LHC, we did not know the mass of the Higgs, and we could not predict it. On the other hand, now we absolutely can predict the couplings of the Higgs. We have quite precise numbers, our expectation for what they should be based on a theory that so far has proven quite successful.

We aren’t certain, of course, just like physicists weren’t certain before. The Higgs boson might have many surprising properties, things that contradict our current best theory and usher in something new. These surprises could genuinely tell us something about some of the big questions, from the nature of dark matter to the universe’s balance of matter and antimatter to the stability of the laws of physics.

But of course, they also might not. We no longer have that rare creature, a guaranteed mild surprise, to hedge in case the big surprises fail. We have guaranteed observations, and experimenters will happily tell you about them…but no guaranteed surprises.

That’s a strange position to be in. And I’m not sure physicists have figured out what to do about it.

by 4gravitons at May 02, 2025 04:00 PM

May 01, 2025

Peter Rohde Z Measurement

Outcome letter_B304831656 Download

Your reporting dates and important information_B305888587 Download

by Peter Rohde at May 01, 2025 05:58 AM

April 29, 2025

John Baez — Civilizational Collapse (Part 5)

A tale of civilizational decline and rebirth

Around 250 BC Archimedes found a general algorithm for computing pi to arbitrary accuracy, and used it to prove that 223/71 < π < 22/7. This seems to be when people started using 22/7 as an approximation to pi.

By the Middle Ages, math had backslid so much in Western Europe that scholars believed pi was actually equal to 22/7.

Around 1020, a mathematician named Franco of Liège got interested in the ancient Greek problem of squaring the circle. But since he believed that pi is 22/7, he started studying the square root of 22/7.

There’s a big difference between being misinformed and being stupid. Franco was misinformed but not stupid. He went ahead to prove that the square root of 22/7 is irrational!

His proof resembles the old Greek proof that the square root of 2 is irrational. I don’t know if Franco was aware of that. I also don’t know if he noticed that if pi were 22/7, it would be possible to square the circle with straightedge and compass. I also don’t know if he wondered why pi was 22/7. He may have just taken it on authority.

But still: math was coming back.

Franco was a student of a student of the famous scholar Gerbert of Aurillac (~950–1003), who studied in the Islamic schools of Sevilla and Córdoba, and thus got some benefits of a culture whose mathematics was light years ahead of Western Europe. Gerbert wrote something interesting: he said that the benefit of mathematics lie in the “sharpening of the mind”.

I got most of this interesting tale from this book:

• Thomas Sonar, trans. Morton Patricia and Keith William Morton, 3000 Years of Analysis: Mathematics in History and Culture, Birkhäuser, 2020. Preface and table of contents free here.

It’s over 700 pages long, but it’s fun to read, and you can start anywhere! The translation is weak and occasionally funny, but tolerable. If its length is intimating, you may enjoy the detailed review here:

• Anthony Weston, 3000 years of analysis, Notices of the American Mathematical Society 70 1 (January 2023), 115–121.

by John Baez at April 29, 2025 05:23 PM

April 28, 2025

John Preskill — Quantum automata

Do you know when an engineer built the first artificial automaton—the first human-made machine that operated by itself, without external control mechanisms that altered the machine’s behavior over time as the machine undertook its mission?

The ancient Greek thinker Archytas of Tarentum reportedly created it about 2,300 years ago. Steam propelled his mechanical pigeon through the air.

For centuries, automata cropped up here and there as curiosities and entertainment. The wealthy exhibited automata to amuse and awe their peers and underlings. For instance, the French engineer Jacques de Vauconson built a mechanical duck that appeared to eat and then expel grains. The device earned the nickname the Digesting Duck…and the nickname the Defecating Duck.

Vauconson also invented a mechanical loom that helped foster the Industrial Revolution. During the 18th and 19th centuries, automata began to enable factories, which changed the face of civilization. We’ve inherited the upshots of that change. Nowadays, cars drive themselves, Roombas clean floors, and drones deliver packages.¹ Automata have graduated from toys to practical tools.²

Rather, classical automata have. What of their quantum counterparts?

Scientists have designed autonomous quantum machines, and experimentalists have begun realizing them. The roster of such machines includes autonomous quantum engines, refrigerators, and clocks. Much of this research falls under the purview of quantum thermodynamics, due to the roles played by energy in these machines’ functioning: above, I defined an automaton as a machine free of time-dependent control (exerted by a user). Equivalently, according to a thermodynamicist mentality, we can define an automaton as a machine on which no user performs any work as the machine operates. Thermodynamic work is well-ordered energy that can be harnessed directly to perform a useful task. Often, instead of receiving work, an automaton receives access to a hot environment and a cold environment. Heat flows from the hot to the cold, and the automaton transforms some of the heat into work.

Quantum automata appeal to me because quantum thermodynamics has few practical applications, as I complained in my previous blog post. Quantum thermodynamics has helped illuminate the nature of the universe, and I laud such foundational insights. Yet we can progress beyond laudation by trying to harness those insights in applications. Some quantum thermal machines—quantum batteries, engines, etc.—can outperform their classical counterparts, according to certain metrics. But controlling those machines, and keeping them cold enough that they behave quantum mechanically, costs substantial resources. The machines cost more than they’re worth. Quantum automata, requiring little control, offer hope for practicality.

To illustrate this hope, my group partnered with Simone Gasparinetti’s lab at Chalmer’s University in Sweden. The experimentalists created an autonomous quantum refrigerator from superconducting qubits. The quantum refrigerator can help reset, or “clear,” a quantum computer between calculations.

Artist’s conception of the autonomous-quantum-refrigerator chip. Credit: Chalmers University of Technology/Boid AB/NIST.

After we wrote the refrigerator paper, collaborators and I raised our heads and peered a little farther into the distance. What does building a useful autonomous quantum machine take, generally? Collaborators and I laid out guidelines in a “Key Issues Review” published in Reports in Progress on Physics last November.

We based our guidelines on DiVincenzo’s criteria for quantum computing. In 1996, David DiVincenzo published seven criteria that any platform, or setup, must meet to serve as a quantum computer. He cast five of the criteria as necessary and two criteria, related to information transmission, as optional. Similarly, our team provides ten criteria for building useful quantum automata. We regard eight of the criteria as necessary, at least typically. The final two, optional guidelines govern information transmission and machine transportation.

Time-dependent external control and autonomy

DiVincenzo illustrated his criteria with multiple possible quantum-computing platforms, such as ions. Similarly, we illustrate our criteria in two ways. First, we show how different quantum automata—engines, clocks, quantum circuits, etc.—can satisfy the criteria. Second, we illustrate how quantum automata can consist of different platforms: ultracold atoms, superconducting qubits, molecules, and so on.

Nature has suggested some of these platforms. For example, our eyes contain autonomous quantum energy transducers called photoisomers, or molecular switches. Suppose that such a molecule absorbs a photon. The molecule may use the photon’s energy to switch configuration. This switching sets off chemical and neurological reactions that result in the impression of sight. So the quantum switch transduces energy from light into mechanical, chemical, and electric energy.

Photoisomer. (Image by Todd Cahill, from *Quantum Steampunk*.)

My favorite of our criteria ranks among the necessary conditions: every useful quantum automata must produce output worth the input. How one quantifies a machine’s worth and cost depends on the machine and on the user. For example, an agent using a quantum engine may care about the engine’s efficiency, power, or efficiency at maximum power. Costs can include the energy required to cool the engine to the quantum regime, as well as the control required to initialize the engine. The agent also chooses which value they regard as an acceptable threshold for the output produced per unit input. I like this criterion because it applies a broom to dust that we quantum thermodynamicists often hide under a rug: quantum thermal machines’ costs. Let’s begin building quantum engines that perform more work than they require to operate.

One might object that scientists and engineers are already sweating over nonautonomous quantum machines. Companies, governments, and universities are pouring billions of dollars into quantum computing. Building a full-scale quantum computer by hook or by crook, regardless of classical control, is costing enough. Eliminating time-dependent control sounds even tougher. Why bother?

Fellow Quantum Frontiers blogger John Preskill pointed out one answer, when I described my new research program to him in 2022: control systems are classical—large and hot. Consider superconducting qubits—tiny quantum circuits—printed on a squarish chip about the size of your hand. A control wire terminates on each qubit. The rest of the wire runs off the edge of the chip, extending to classical hardware standing nearby. One can fit only so many wires on the chip, so one can fit only so many qubits. Also, the wires, being classical, are hotter than the qubits should be. The wires can help decohere the circuits, introducing errors into the quantum information they store. The more we can free the qubits from external control—the more autonomy we can grant them—the better.

Besides, quantum automata exemplify quantum steampunk, as my coauthor Pauli Erker observed. I kicked myself after he did, because I’d missed the connection. The irony was so thick, you could have cut it with the retractible steel knife attached to a swashbuckling villain’s robotic arm. Only two years before, I’d read The Watchmaker of Filigree Street, by Natasha Pulley. The novel features a Londoner expatriate from Meiji Japan, named Mori, who builds clockwork devices. The most endearing is a pet-like octopus, called Katsu, who scrambles around Mori’s workshop and hoards socks.

Does the world need a quantum version of Katsu? Not outside of quantum-steampunk fiction…yet. But a girl can dream. And quantum automata now have the opportunity to put quantum thermodynamics to work.

¹And deliver pizzas. While visiting the University of Pittsburgh a few years ago, I was surprised to learn that the robots scurrying down the streets were serving hungry students.

²And minions of starving young scholars.

by Nicole Yunger Halpern at April 28, 2025 12:12 AM

April 27, 2025

Scott Aaronson Fight Fiercely

Last week I visited Harvard and MIT, and as advertised in my last post, gave the Yip Lecture at Harvard on the subject “How Much Math Is Knowable?” The visit was hosted by Harvard’s wonderful Center of Mathematical Sciences and Applications (CMSA), directed by my former UT Austin colleague Dan Freed. Thanks so much to everyone at CMSA for the visit.

And good news! You can now watch my lecture on YouTube here:

I’m told it was one of my better performances. As always, I strongly recommend watching at 2x speed.

I opened the lecture by saying that, while obviously it would always be an honor to give the Yip Lecture at Harvard, it’s especially an honor right now, as the rest of American academia looks to Harvard to defend the value of our entire enterprise. I urged Harvard to “fight fiercely,” in the words of the Tom Lehrer song.

I wasn’t just fishing for applause; I meant it. It’s crucial for people to understand that, in its total war against universities, MAGA has now lost, not merely the anti-Israel leftists, but also most conservatives, classical liberals, Zionists, etc. with any intellectual scruples whatsoever. To my mind, this opens up the possibility for a broad, nonpartisan response, highlighting everything universities (yes, even Harvard ) do for our civilization that’s worth defending.

For three days in my old hometown of Cambridge, MA, I met back-to-back with friends and colleagues old and new. Almost to a person, they were terrified about whether they’ll be able to keep doing science as their funding gets decimated, but especially terrified for anyone who they cared about on visas and green cards. International scholars can now be handcuffed, deported, and even placed in indefinite confinement for pretty much any reason—including long-ago speeding tickets—or no reason at all. The resulting fear has paralyzed, in a matter of months, an American scientific juggernaut that took a century to build.

A few of my colleagues personally knew Rümeysa Öztürk, the Turkish student at Tufts who currently sits in prison for coauthoring an editorial for her student newspaper advocating the boycott of Israel. I of course disagree with what Öztürk wrote … and that is completely irrelevant to my moral demand that she go free. Even supposing the government had much more on her than this one editorial, still the proper response would seem to be a deportation notice—“either contest our evidence in court, or else get on the next flight back to Turkey”—rather than grabbing Öztürk off the street and sending her to indefinite detention in Louisiana. It’s impossible to imagine any university worth attending where the students live in constant fear of imprisonment for the civil expression of opinions.

To help calibrate where things stand right now, here’s the individual you might expect to be most on board with a crackdown on antisemitism at Harvard:

Jason Rubenstein, the executive director of Harvard Hillel, said that the school is in the midst of a long — and long-overdue — reckoning with antisemitism, and that [President] Garber has taken important steps to address the problem. Methodical federal civil rights oversight could play a constructive role in that reform, he said. “But the government’s current, fast-paced assault against Harvard – shuttering apolitical, life-saving research; targeting the university’s tax-exempt status; and threatening all student visas … is neither deliberate nor methodical, and its disregard for the necessities of negotiation and due process threatens the bulwarks of institutional independence and the rule of law that undergird our shared freedoms.”

Meanwhile, as the storm clouds over American academia continue to darken, I’ll just continue to write what I think about everything, because what else can I do?

Last night, alas, I lost yet another left-wing academic friend, the fourth or fifth I’ve lost since October 7. For while I was ready to take a ferocious public stand against the current US government, for the survival and independence of our universities, and for free speech and due process for foreign students, this friend regarded all that as insufficient. He demanded that I also clear the tentifada movement of any charge of antisemitism. For, as he patiently explained to me (while worrying that I wouldn’t grasp the point), while the protesters may have technically violated university rules, disrupted education, created a hostile environment in the sense of Title VI antidiscrimination law in ways that would be obvious were we discussing any other targeted minority, etc. etc., still, the only thing that matters morally is that the protesters represent “the powerless,” whereas Zionist Jews like me represent “the powerful.” So, I told this former friend to go fuck himself. Too harsh? Maybe if he hadn’t been Jewish himself, I could’ve forgiven him for letting the world’s oldest conspiracy theory colonize his brain.

For me, the deep significance of in-person visits, including my recent trip to Harvard, is that they reassure me of the preponderance of sanity within my little world—and thereby of my own sanity. Online, every single day I feel isolated and embattled: pressed in on one side by MAGA forces who claim to care about antisemitism, but then turn out to want the destruction of science, universities, free speech, international exchange, due process of law, and everything else that’s made the modern world less than fully horrible; and on the other side, by leftists who say they stand with me for science and academic freedom and civil rights and everything else that’s good, but then add that the struggle needs to continue until the downfall of the scheming, moneyed Zionists and the liberation of Palestine from river to sea.

When I travel to universities to give talks, though, I meet one sane, reasonable human being after another. Almost to a person, they acknowledge the reality of antisemitism, ideological monoculture, bureaucracy, spiraling costs, and many other problems at universities—and they care about universities enough to want to fix those problems, rather than gleefully nuking the universities from orbit as MAGA is doing. Mostly, though, people just want me to sign Quantum Computing Since Democritus, or tell me how much they like this blog, or ask questions about quantum algorithms or the Busy Beaver function. Which is fine too, and which you can do in the comments.

by Scott at April 27, 2025 12:52 AM

April 26, 2025

Jordan Ellenberg — St. Olaf, Carleton, UW-Madison, wholesomeness

I was in Northfield, MN last week giving the “Math Across the Cannon” lectures at St. Olaf and Carleton. (It turns out the Cannon is a river; I had imagined the two campuses each having a rusty hilltop artillery piece aimed at the other, the relic of some 19th century intra-Lutheran feud….) They both seem like fun places to go to school. CJ didn’t apply to colleges like this; on grounds of novelty he took a pretty hard line on not applying to colleges that were smaller than his high school, and his high school has 2200 kids, so that did actually rule some places out.

Anyway, visiting a college means a bunch of meetings with undergraduates to talk about their work, their interests, and their plans, and as always I was struck by what a great part of my job this is, to be around young people like this so much the time. Their values are agreeably old-fashioned: they want to work hard, they want to learn about things, they want to get a little better at stuff every year, they want to use the skills they’re building to lead a life they can be proud of. And of course it’s not just small colleges where these values are realized. I taught my FIG again this year: “Writing and Data,” where the freshmen, mostly STEM majors, practice the art of writing non-technical articles about quantitative topics. (Previously covered on the blog.) I wasn’t sure how this would go — but the students have drastically exceeded my expectations. It’s a true joy to spend those hours each week with a group of 18-year-olds who sincerely want to learn a craft, who are generous and conscientious readers and editors of each others’ work, who are not cynical in the slightest, who truly believe that there’s value in learning how to do things well. College is, in a word, wholesome. Not everybody gets to work in such a wholesome environment and I ought to take the time to appreciate it more.

by JSE at April 26, 2025 07:41 PM

April 25, 2025

Doug Natelson — NSF, quo vadis?

There is a lot going on. Today, some words about NSF.

Yesterday Sethuraman Panchanathan, the director of the National Science Foundation, resigned 16 months before the end of his six year term. The relevant Science article raises the possibility that this is because, as an executive branch appointee, he would effectively have to endorse the upcoming presidential budget request, which is rumored to be a 55% cut to the agency budget (from around $9B/yr to $4B/yr) and a 50% reduction in agency staffing. (Note: actual appropriations are set by Congress, which has ignored presidential budget requests in the past.) This comes at the end of a week when all new awards were halted at the agency while non-agency personnel conducted "a second review" of all grants, and many active grants have been terminated. Bear in mind, awards this year from NSF are already down 50% over last year, even without official budget cuts. Update: Here is Nature's reporting from earlier today.

The NSF has been absolutely critical to a long list of scientific and technological advances over the last 70 years (see here while it's still up). As mentioned previously, government support of basic research has a great return on investment for the national economy, and it's a tiny fraction of government spending. Less than three years ago, the CHIPS & Science Act was passed with supposed bipartisan support in Congress, authorizing the doubling of the NSF budget. Last summer I posted in frustration that this support seemed to be an illusion when it came to actual funding.

People can have disagreements about the "right" level of government support for science in times of fiscal challenges, but as far as I can tell, no one (including and especially Congress so far) voted for the dismantling of the NSF. If you think the present trajectory is wrong, contact your legislators and make your voices heard.

by Douglas Natelson at April 25, 2025 08:12 PM

John Preskill — Quantum Algorithms: A Call To Action

Quantum computing finds itself in a peculiar situation. On the technological side, after billions of dollars and decades of research, working quantum computers are nearing fruition. But still, the number one question asked about quantum computers is the same as it was two decades ago: What are they good for? The honest answer reveals an elephant in the room: We don’t fully know yet. For theorists like me, this is an opportunity, a call to action.

Technological momentum

Suppose we do not have quantum computers in a few decades time. What will be the reason? It’s unlikely that we’ll encounter some insurmountable engineering obstacle. The theoretical basis of quantum error-correction is solid, and several platforms are approaching or below the error-correction threshold (Harvard, Yale, Google). Experimentalists believe today’s technology can scale to 100 logical qubits and $10^6$ gates—the megaquop era. If mankind spends $100 billion over the next few decades, it’s likely we could build a quantum computer.

A more concerning reason that quantum computing might fail is that there is not enough incentive to justify such a large investment in R&D and infrastructure. Let’s make a comparison to nuclear fusion. Like quantum hardware, they have challenging science and engineering problems to solve. However, if a nuclear fusion lab were to succeed in their mission of building a nuclear fusion reactor, the application would be self-evident. This is not the case for quantum computing—it is a sledgehammer looking for nails to hit.

Nevertheless, industry investment in quantum computing is currently accelerating. To maintain the momentum, it is critical to match investment growth and hardware progress with algorithmic capabilities. The time to discover quantum algorithms is now.

Empowered theorists

Theory research is forward-looking and predictive. Theorists such as Geoffrey Hinton laid the foundations of the current AI revolution. But decades later, with an abundance of computing hardware, AI has become much more of an empirical field. I look forward to the day that quantum hardware reaches a state of abundance, but that day is not yet here.

Today, quantum computing is an area where theorists have extraordinary leverage. A few pages of mathematics by Peter Shor inspired thousands of researchers, engineers and investors to join the field. Perhaps another few pages by someone reading this blog will establish a future of world-altering impact for the industry. There are not many places where mathematics has such potential for influence. An entire community of experimentalists, engineers, and businesses are looking to the theorists for ideas.

The Challenge

Traditionally, it is thought that the ideal quantum algorithm would exhibit three features. First, it should be provably correct, giving a guarantee that executing the quantum circuit reliably will achieve the intended outcome. Second, the underlying problem should be classically hard—the output of the quantum algorithm should be computationally hard to replicate with a classical algorithm. Third, it should be useful, with the potential to solve a problem of interest in the real world. Shor’s algorithm comes close to meeting all of these criteria. However, demanding all three in an absolute fashion may be unnecessary and perhaps even counterproductive to progress.

Provable correctness is important, since today we cannot yet empirically test quantum algorithms on hardware at scale. But what degree of evidence should we require for classical hardness? Rigorous proof of classical hardness is currently unattainable without resolving major open problems like P vs NP, but there are softer forms of proof, such as reductions to well-studied classical hardness assumptions.

I argue that we should replace the ideal of provable hardness with a more pragmatic approach: The quantum algorithm should outperform the best known classical algorithm that produces the same output by a super-quadratic speedup.¹ Emphasizing provable classical hardness might inadvertently impede the discovery of new quantum algorithms, since a truly novel quantum algorithm could potentially introduce a new classical hardness assumption that differs fundamentally from established ones. The back-and-forth process of proposing and breaking new assumptions is a productive direction that helps us triangulate where quantum advantage lies.

It may also be unproductive to aim directly at solving existing real-world problems with quantum algorithms. Fundamental computational tasks with quantum advantage are special and we have very few examples, yet they necessarily provide the basis for any eventual quantum application. We should search for more of these fundamental tasks and match them to applications later.

That said, it is important to distinguish between quantum algorithms that could one day provide the basis for a practically relevant computation, and those that will not. In the real world, computations are not useful unless they are verifiable or at least repeatable. For instance, consider a quantum simulation algorithm that computes a physical observable. If two different quantum computers run the simulation and get the same answer, one can be confident that this answer is correct and that it makes a robust prediction about the world. Some problems such as factoring are naturally easy to verify classically, but we can set the bar even lower: The output of a useful quantum algorithm should at least be repeatable by another quantum computer.

There is a subtle fourth requirement of paramount importance that is often overlooked, captured by the following litmus test: If given a quantum computer tomorrow, could you implement your quantum algorithm? In order to do so, you need not only a quantum algorithm but also a distribution over its inputs on which to run it. Classical hardness must then be judged in the average case over this distribution of inputs, rather than in the worst case.

I’ll end this section with a specific caution regarding quantum algorithms whose output is the expectation value of an observable. A common reason these proposals fail to be classically hard is that the expectation value exponentially concentrates over the distribution of inputs. When this happens, a trivial classical algorithm can replicate the quantum result by simply outputting the concentrated (typical) value for every input. To avoid this, we must seek ensembles of quantum circuits whose expectation values exhibit meaningful variation and sensitivity to different inputs.

We can crystallize these priorities into the following challenge:

The Challenge
Find a quantum algorithm and a distribution over its inputs with the following features:
— (Provable correctness.) The quantum algorithm is provably correct.
— (Classical hardness.) The quantum algorithm outperforms the best known classical algorithm that performs the same task by a super-quadratic speedup, in the average-case over the distribution of inputs.
— (Potential utility.) The output is verifiable, or at least repeatable.

Examples and non-examples

Category	Classically verifiable	Quantumly repeatable	Potentially useful	Provable classical hardness	Examples
Search problem	Yes	Yes	Yes	No	Shor ‘99 Regev’s reduction: CLZ22, YZ24, Jor+24 Planted inference: Has20, SOKB24
Compute a value	No	Yes	Yes	No	Condensed matter physics? Quantum chemistry?
Proof of quantumness	Yes, with key	Yes, with respect to key	No	Yes, under crypto assumptions	BCMVV21
Sampling	No	No	No	Almost, under complexity assumptions	BJS10, AA11, Google ‘20

We can categorize quantum algorithms by the form of their output. First, there are quantum algorithms for search problems, which produce a bitstring satisfying some constraints. This could be the prime factors of a number, a planted feature in some dataset, or the solution to an optimization problem. Next, there are quantum algorithms that compute a value to some precision, for example the expectation value of some physical observable. Then there are proofs of quantumness, which involve a verifier who generates a test using some hidden key, and the key can be used to verify the output. Finally, there are quantum algorithms which sample from some distribution.

Hamiltonian simulation is perhaps the most widely heralded source of quantum utility. Physics and chemistry contain many quantities that Nature computes effortlessly, yet remain beyond the reach of even our best classical simulations. Quantum computation is capable of simulating Nature directly, giving us strong reason to believe that quantum algorithms can compute classically-hard quantities.

There are already many examples where a quantum computer could help us answer an unsolved scientific question, like determining the phase diagram of the Hubbard model or the ground energy of FeMoCo. These undoubtedly have scientific value. However, they are isolated examples, whereas we would like evidence that the pool of quantum-solvable questions is inexhaustible. Can we take inspiration from strongly correlated physics to write down a concrete ensemble of Hamiltonian simulation instances where there is a classically-hard observable? This would gather evidence for the sustained, broad utility of quantum simulation, and would also help us understand where and how quantum advantage arises.

Over in the computer science community, there has been a lot of work on oracle separations such as welded trees and forrelation, which should give us confidence in the abilities of quantum computers. Can we instantiate these oracles in a way that pragmatically remains classically hard? This is necessary in order to pass our earlier litmus test of being ready to run the quantum algorithm tomorrow.

In addition to Hamiltonian simulation, there are several other broad classes of quantum algorithms, including quantum algorithms for linear systems of equations and differential equations, variational quantum algorithms for machine learning, and quantum algorithms for optimization. These frameworks sometimes come with proofs of BQP-completeness.

The issue with these broad frameworks is that they often do not specify a distribution over inputs. Can we find novel ensembles of inputs to these frameworks which exhibit super-quadratic speedups? BQP-completeness shows that one has translated the notion of quantum computation into a different language, which allows one to embed an existing quantum algorithm such as Shor’s algorithm into your framework. But in order to discover a new quantum algorithm, you must find an ensemble of BQP computations which does not arise from Shor’s algorithm.

Table I claims that sampling tasks alone are not useful since they are not even quantumly repeatable. One may wonder if sampling tasks could be useful in some way. After all, classical Monte Carlo sampling algorithms are widely used in practice. However, applications of sampling typically use samples to extract meaningful information or specific features of the underlying distribution. For example, Monte Carlo sampling can be used to evaluate integrals in Bayesian inference and statistical physics. In contrast, samples obtained from random quantum circuits lack any discernible features. If a collection of quantum algorithms generated samples containing meaningful signals from which one could extract classically hard-to-compute values, those algorithms would effectively transition into the compute a value category.

Table I also claims that proofs of quantumness are not useful. This is not completely true—one potential application is generating certifiable randomness. However, such applications are generally cryptographic rather than computational in nature. Specifically, proofs of quantumness cannot help us solve problems or answer questions whose solutions we do not already know.

Finally, there are several exciting directions proposing applications of quantum technologies in sensing and metrology, communication, learning with quantum memory, and streaming. These are very interesting, and I hope that mankind’s second century of quantum mechanics brings forth all flavors of capabilities. However, the technological momentum is mostly focused on building quantum computers for the purpose of computational advantage, and so this is where breakthroughs will have the greatest immediate impact.

Don’t be too afraid

At the annual QIP conference, only a handful of papers out of hundreds each year attempt to advance new quantum algorithms. Given the stakes, why is this number so low? One common explanation is that quantum algorithm research is simply too difficult. Nevertheless, we have seen substantial progress in quantum algorithms in recent years. After an underwhelming lack of end-to-end proposals with the potential for utility between the years 2000 and 2020, Table I exhibits several breakthroughs from the past 5 years.

In between blind optimism and resigned pessimism, embracing a mission-driven mindset can propel our field forward. We should allow ourselves to adopt a more exploratory, scrappier approach: We can hunt for quantum advantages in yet-unstudied problems or subtle signals in the third decimal place. The bar for meaningful progress is lower than it might seem, and even incremental advances are valuable. Don’t be too afraid!

Quadratic speedups are widespread but will not form the basis of practical quantum advantage due to the overheads associated with quantum error-correction. ︎

by robbieking1000 at April 25, 2025 07:15 PM

Terence Tao — Stonean spaces, projective objects, the Riesz representation theorem, and (possibly) condensed mathematics

A basic type of problem that occurs throughout mathematics is the lifting problem: given some space ${X}$ that “sits above” some other “base” space ${Y}$ due to a projection map ${\pi: X \rightarrow Y}$ , and some map ${f: A \rightarrow Y}$ from a third space ${A}$ into the base space ${Y}$ , find a “lift” ${\tilde f}$ of ${f}$ to ${X}$ , that is to say a map ${\tilde f: A \rightarrow X}$ such that ${\pi \circ \tilde f = f}$ . In many applications we would like to have ${\tilde f}$ preserve many of the properties of ${f}$ (e.g., continuity, differentiability, linearity, etc.).

Of course, if the projection map ${\pi: X \rightarrow Y}$ is not surjective, one would not expect the lifting problem to be solvable in general, as the map ${f}$ to be lifted could simply take values outside of the range of ${\pi}$ . So it is natural to impose the requirement that ${\pi}$ be surjective, giving the following commutative diagram to complete:

If no further requirements are placed on the lift ${\tilde f}$ , then the axiom of choice is precisely the assertion that the lifting problem is always solvable (once we require ${\pi}$ to be surjective). Indeed, the axiom of choice lets us select a preimage ${\phi(y) \in \pi^{-1}(\{y\})}$ in the fiber of each point ${y \in Y}$ , and one can lift any ${f: A \rightarrow Y}$ by setting ${\tilde f := \phi \circ f}$ . Conversely, to build a choice function for a surjective map ${\pi: X \rightarrow Y}$ , it suffices to lift the identity map ${\mathrm{id}_Y:Y \rightarrow Y}$ to ${X}$ .

Of course, the maps provided by the axiom of choice are famously pathological, being almost certain to be discontinuous, non-measurable, etc.. So now suppose that all spaces involved are topological spaces, and all maps involved are required to be continuous. Then the lifting problem is not always solvable. For instance, we have a continuous projection ${x \mapsto x \hbox{ mod } 1}$ from ${{\bf R}}$ to ${{\bf R}/{\bf Z}}$ , but the identity map ${\mathrm{id}_{{\bf R}/{\bf Z}}:{\bf R}/{\bf Z} \rightarrow {\bf R}/{\bf Z}}$ cannot be lifted continuously up to ${{\bf R}}$ , because ${{\bf R}}$ is contractable and ${{\bf R}/{\bf Z}}$ is not.

However, if ${A}$ is a discrete space (every set is open), then the axiom of choice lets us solve the continuous lifting problem from ${A}$ for any continuous surjection ${\pi: X \rightarrow Y}$ , simply because every map from ${A}$ to ${X}$ is continuous. Conversely, the discrete spaces are the only ones with this property: if ${A}$ is a topological space which is not discrete, then if one lets ${A_{disc}}$ be the same space ${A}$ equipped with the discrete topology, then the only way one can continuously lift the identity map ${\mathrm{id}_A: A \rightarrow A}$ through the “projection map” ${\pi: A_{disc} \rightarrow A}$ (that maps each point to itself) is if ${A}$ is itself discrete.

These discrete spaces are the projective objects in the category of topological spaces, since in this category the concept of an epimorphism agrees with that of a surjective continuous map. Thus ${A_{disc}}$ can be viewed as the unique (up to isomorphism) projective object in this category that has a bijective continuous map to ${A}$ .

Now let us narrow the category of topological spaces to the category of compact Hausdorff (CH) spaces. Here things should be better behaved; for instance, it is a standard fact in this category that continuous bijections are homeomorphisms, and it is still the case that the epimorphisms are the continuous surjections. So we have a usable notion of a projective object in this category: CH spaces ${A}$ such that any continuous map ${f: A \rightarrow Y}$ into another CH space can be lifted via any surjective continuous map ${\pi: X \rightarrow Y}$ to another CH space.

By the previous discussion, discrete CH spaces will be projective, but this is an extremely restrictive set of examples, since of course compact discrete spaces must be finite. Are there any others? The answer was worked out by Gleason:

Proposition 1 A compact Hausdorff space ${A}$ is projective if and only if it is extremally disconnected, i.e., the closure of every open set is again open.

Proof: We begin with the “only if” direction. Let ${A}$ was projective, and let ${U}$ be an open subset of ${A}$ . Then the closure ${\overline{U}}$ and complement ${A \backslash U}$ are both closed, hence compact, subsets of ${A}$ , so the disjoint union ${\overline{U} \uplus (A \backslash U)}$ is another CH space, which has an obvious surjective continuous projection map ${\pi: \overline{U} \uplus (A \backslash U) \rightarrow A}$ to ${A}$ formed by gluing the two inclusion maps together. As ${A}$ is projective, the identity map ${\mathrm{id}_A: A \rightarrow A}$ must then lift to a continuous map ${\tilde f: A \rightarrow \overline{U} \uplus (A \backslash U) \rightarrow A}$ . One easily checks that ${f}$ has to map ${\overline{U}}$ to the first component ${\overline{U}}$ of the disjoint union, and ${A \backslash \overline{U}}$ ot the second component; hence ${f^{-1}(\overline{U}) = \overline{U}}$ , and so ${\overline{U}}$ is open, giving extremal disconnectedness.

Conversely, suppose that ${A}$ is extremally disconnected, that ${\pi: X \rightarrow Y}$ is a continuous surjection of CH spaces, and ${f: A \rightarrow Y}$ is continuous. We wish to lift ${f}$ to a continuous map ${\tilde f: A \rightarrow X}$ .

We first observe that it suffices to solve the lifting problem for the identity map ${\mathrm{id}_A: A \rightarrow A}$ , that is to say we can assume without loss of generality that ${Y=A}$ and ${f}$ is the identity. Indeed, for general maps ${f: A \rightarrow Y}$ , one can introduce the pullback space

$\displaystyle A \times_Y X := \{ (a,x) \in A \times X: \pi(x) = f(a) \}$

which is clearly a CH space that has a continuous surjection ${\tilde \pi: A \times_Y X \rightarrow A}$ . Any continuous lift of the identity map ${\mathrm{id}_A: A \rightarrow A}$ to ${A \times_Y X}$ , when projected onto ${X}$ , will give a desired lift ${\tilde f: A \rightarrow X}$ .

So now we are trying to lift the identity map ${\mathrm{id}_A: A \rightarrow A}$ via a continuous surjection ${\pi: X \rightarrow A}$ . Let us call this surjection ${\pi: X \rightarrow A}$ minimally surjective if no restriction ${\pi|_K: K \rightarrow A}$ of ${X}$ to a proper closed subset ${K}$ of ${X}$ remains surjective. An easy application of Zorn’s lemma shows that every continuous surjection ${\pi: X \rightarrow A}$ can be restricted to a minimally surjective continuous map ${\pi|_K: K \rightarrow A}$ . Thus, without loss of generality, we may assume that ${\pi}$ is minimally surjective.

The key claim now is that every minimally surjective map ${\pi: X \rightarrow A}$ into an extremally disconnected space is in fact a bijection. Indeed, suppose for contradiction that there were two distinct points ${x_1,x_2}$ in ${X}$ that mapped to the same point ${a}$ under ${X}$ . By taking contrapositives of the minimal surjectivity property, we see that every open neighborhood of ${x_1}$ must contain at least one fiber ${\pi^{-1}(\{b\})}$ of ${b}$ , and by shrinking this neighborhood one can ensure the base point is arbitrarily close to ${a = \pi(x_2)}$ . Thus, every open neighborhood of ${x_1}$ must intersect every open neighborhood of ${x_2}$ , contradicting the Hausdorff property.

It is well known that continuous bijections between CH spaces must be homeomorphisms (they map compact sets to compact sets, hence must be open maps). So ${\pi:X \rightarrow A}$ is a homeomorphism, and one can lift the identity map to the inverse map ${\pi^{-1}: A \rightarrow X}$ . $\Box$

Remark 2 The property of being “minimally surjective” sounds like it should have a purely category-theoretic definition, but I was unable to match this concept to a standard term in category theory (something along the lines of a “minimal epimorphism”, I would imagine).

In view of this proposition, it is now natural to look for extremally disconnected CH spaces (also known as Stonean spaces). The discrete CH spaces are one class of such spaces, but they are all finite. Unfortunately, these are the only “small” examples:

Lemma 3 Any first countable extremally disconnected CH space ${A}$ is discrete.

Proof: If such a space ${A}$ were not discrete, one could find a sequence ${a_n}$ in ${A}$ converging to a limit ${a}$ such that ${a_n \neq a}$ for all ${A}$ . One can sparsify the elements ${a_n}$ to all be distinct, and from the Hausdorff property one can construct neighbourhoods ${U_n}$ of each ${a_n}$ that avoid ${a}$ , and are disjoint from each other. Then ${\bigcup_{n=1}^\infty U_{2n}}$ and then ${\bigcup_{n=1}^\infty U_{2n+1}}$ are disjoint open sets that both have ${a}$ as an adherent point, which is inconsistent with extremal disconnectedness: the closure of ${\bigcup_{n=1}^\infty U_{2n}}$ contains ${a}$ but is disjoint from ${\bigcup_{n=1}^\infty U_{2n+1}}$ , so cannot be open. $\Box$

Thus for instance there are no extremally disconnected compact metric spaces, other than the finite spaces; for instance, the Cantor space ${\{0,1\}^{\bf N}}$ is not extremally disconnected, even though it is totally disconnected (which one can easily see to be a property implied by extremal disconnectedness). On the other hand, once we leave the first-countable world, we have plenty of such spaces:

Lemma 4 Let ${\mathcal{B}}$ be a complete Boolean algebra. Then the Stone dual ${\mathrm{Hom}(\mathcal{B},\{0,1\})}$ of ${\mathcal{B}}$ (i.e., the space of boolean homomorphisms ${\phi: \mathcal{B} \rightarrow \{0,1\}}$ ) is an extremally disconnected CH space.

Proof: The CH properties are standard. The elements ${E}$ of ${{\mathcal B}}$ give a basis of the topology given by the clopen sets ${B_E := \{ \phi: \phi(E) = 1\}}$ . Because the Boolean algebra is complete, we see that the closure of the open set ${\bigcup_{\alpha} B_{E_\alpha}}$ for any family ${E_\alpha}$ of sets is simply the clopen set ${B_{\bigwedge_\alpha E_\alpha}}$ , which obviously open, giving extremal disconnectedness. $\Box$

Remark 5 In fact, every extremally disconnected CH space ${X}$ is homeomorphic to a Stone dual of a complete Boolean algebra (and specifically, the clopen algebra of ${X}$ ); see Gleason’s paper.

Corollary 6 Every CH space ${X}$ is the surjective continuous image of an extremally disconnected CH space.

Proof: Take the Stone-Čech compactification ${\beta X_{disc}}$ of ${X_{disc}}$ equipped with the discrete topology, or equivalently the Stone dual of the power set ${2^X}$ (i.e., the ultrafilters on ${X}$ ). By the previous lemma, this is an extremally disconnected CH space. Because every ultrafilter on a CH space has a unique limit, we have a canonical map from ${\beta X_{disc}}$ to ${X}$ , which one can easily check to be continuous and surjective. $\Box$

Remark 7 In fact, to each CH space ${X}$ one can associate an extremally disconnected CH space ${Z}$ with a minimally surjective continuous map ${\pi: Z \rightarrow X}$ . The construction is the same, but instead of working with the entire power set ${2^X}$ , one works with the smaller (but still complete) Boolean algebra of domains – closed subsets of ${X}$ which are the closure of their interior, ordered by inclusion. This ${Z}$ is unique up to homoeomorphism, and is thus a canonical choice of extremally disconnected space to project onto ${X}$ . See the paper of Gleason for details.

Several facts in analysis concerning CH spaces can be made easier to prove by utilizing Corollary 6 and working first in extremally disconnected spaces, where some things become simpler. My vague understanding is that this is highly compatible with the modern perspective of condensed mathematics, although I am not an expert in this area. Here, I will just give a classic example of this philosophy, due to Garling and presented in this paper of Hartig:

Theorem 8 (Riesz representation theorem) Let ${X}$ be a CH space, and let ${\lambda: C(X) \rightarrow {\bf R}}$ be a bounded linear functional. Then there is a (unique) Radon measure ${\mu}$ on ${X}$ (on the Baire ${\sigma}$ -algebra, generated by ${C(X)}$ ) such ${\lambda(f) = \int_X f\ d\mu}$ for all ${f \in C(X)}$ .

Uniqueness of the measure is relatively straightforward; the difficult task is existence, and most known proofs are somewhat complicated. But one can observe that the theorem “pushes forward” under surjective maps:

Proposition 9 Suppose ${\pi: A \rightarrow X}$ is a continuous surjection between CH spaces. If the Riesz representation theorem is true for ${A}$ , then it is also true for ${X}$ .

Proof: As ${\pi}$ is surjective, the pullback map ${\pi^*: C(X) \rightarrow C(A)}$ is an isometry, hence every bounded linear functional on ${C(X)}$ can be viewed as a bounded linear functional on a subspace of ${C(A)}$ , and hence by the Hahn–Banach theorem it extends to a bounded linear functional on ${A}$ . By the Riesz representation theorem on ${A}$ , this latter functional can be represented as an integral against a Radon measure ${\mu}$ on ${A}$ . One can then check that the pushforward measure ${\pi_* \mu}$ is then a Radon measure on ${X}$ , and gives the desired representation of the bounded linear functional on ${C(X)}$ . $\Box$

In view of this proposition and Corollary 6, it suffices to prove the Riesz representation theorem for extremally disconnected CH spaces. But this is easy:

Proposition 10 The Riesz representation theorem is true for extremally disconnected CH spaces.

Proof: The Baire ${\sigma}$ -algebra is generated by the Boolean algebra of clopen sets. A functional ${\lambda: C(X)\rightarrow {\bf R}}$ induces a finitely additive measure ${\mu}$ on this algebra by the formula ${\mu(E) := \lambda(1_E)}$ . This is in fact a premeasure, because by compactness the only way to partition a clopen set into countably many clopen sets is to have only finitely many of the latter sets non-empty. By the Carathéodory extension theorem, ${\mu}$ then extends to a Baire measure, which one can check to be a Radon measure that represents ${\lambda}$ (the finite linear combinations of indicators of clopen sets are dense in ${C(X)}$ ). $\Box$

by Terence Tao at April 25, 2025 06:57 PM

Matt von Hippel — Antimatter Isn’t Magic

You’ve heard of antimatter, right?

For each type of particle, there is a rare kind of evil twin with the opposite charge, called an anti-particle. When an anti-proton meets a proton, they annihilate each other in a giant blast of energy.

I see a lot of questions online about antimatter. One recurring theme is people asking a very general question: how does antimatter work?

If you’ve just heard the pop physics explanation, antimatter probably sounds like magic. What about antimatter lets it destroy normal matter? Does it need to touch? How long does it take? And what about neutral particles like neutrons?

You find surprisingly few good explanations of this online, but I can explain why. Physicists like me don’t expect antimatter to be confusing in this way, because to us, antimatter isn’t doing anything all that special. When a particle and an antiparticle annihilate, they’re doing the same thing that any other pair of particles do when they do…basically anything else.

Instead of matter and antimatter, let’s talk about one of the oldest pieces of evidence for quantum mechanics, the photoelectric effect. Scientists shone light at a metal, and found that if the wavelength of the light was short enough, electrons would spring free, causing an electric current. If the wavelength was too long, the metal wouldn’t emit any electrons, no matter how much light they shone. Einstein won his Nobel prize for the explanation: the light hitting the metal comes in particle-sized pieces, called photons, whose energy is determined by the wavelength of the light. If the individual photons don’t have enough energy to get an electron to leave the metal, then no electron will move, no matter how many photons you use.

What happens to the photons after they hit the metal?

They go away. We say they are absorbed, an electron absorbs a photon and speeds up, increasing its kinetic energy so it can escape.

But we could just as easily say the photon is annihilated, if we wanted to.

In the photoelectric effect, you start with one electron and one photon, they come together, and you end up with one electron and no photon. In proton-antiproton annihilation, you start with a proton and an antiproton, they come together, and you end up with no protons or antiprotons, but instead “energy”…which in practice, usually means two photons.

That’s all that happens, deep down at the root of things. The laws of physics are rules about inputs and outputs. Start with these particles, they come together, you end up with these other particles. Sometimes one of the particles stays the same. Sometimes particles seem to transform, and different kinds of particles show up. Sometimes some of the particles are photons, and you think of them as “just energy”, and easy to absorb. But particles are particles, and nothing is “just energy”. Each thing, absorption, decay, annihilation, each one is just another type of what we call interactions.

What makes annihilation of matter and antimatter seem unique comes down to charges. Interactions have to obey the laws of physics: they conserve energy, they conserve momentum, and they conserve charge.

So why can an antiproton and a proton annihilate to pure photons, while two protons can’t? A proton and an antiproton have opposite charge, a photon has zero charge. You could combine two protons to make something else, but it would have to have the same charge as two protons.

What about neutrons? A neutron has no electric charge, so you might think it wouldn’t need antimatter. But a neutron has another type of charge, called baryon number. In order to annihilate one, you’d need an anti-neutron, which would still have zero electric charge but would have the opposite baryon number. (By the way, physicists have been making anti-neutrons since 1956.)

On the other hand, photons actually have no charge. So do Higgs bosons. So one Higgs boson can become two photons, without annihilating with anything else. Each of these particles can be called its own antiparticle: a photon is also an antiphoton, a Higgs is also an anti-Higgs.

Because particle-antiparticle annihilation follows the same rules as other interactions between particles, it also takes place via the same forces. When a proton and an antiproton annihilate each other, they typically do this via the electromagnetic force. This is why you end up with light, which is an electromagnetic wave. Like everything in the quantum world, this annihilation isn’t certain. Is has a chance to happen, proportional to the strength of the interaction force involved.

What about neutrinos? They also appear to have a kind of charge, called lepton number. That might not really be a conserved charge, and neutrinos might be their own antiparticles, like photons. However, they are much less likely to be annihilated than protons and antiprotons, because they don’t have electric charge, and thus their interaction doesn’t depend on the electromagnetic force, but on the much weaker weak nuclear force. A weaker force means a less likely interaction.

Antimatter might seem like the stuff of science fiction. But it’s not really harder to understand than anything else in particle physics.

(I know, that’s a low bar!)

It’s just interactions. Particles go in, particles go out. If it follows the rules, it can happen, if it doesn’t, it can’t. Antimatter is no different.

by 4gravitons at April 25, 2025 04:00 PM

Peter Rohde Dump & burn

Public google drive

https://drive.google.com/drive/folders/1764YLan-JnDS_fh9j9EWk9GMLgjh2FDA?usp=sharing

by Peter Rohde at April 25, 2025 04:41 AM

April 24, 2025

Peter Rohde The Quantum Astronaut

[CONFIDENTIAL] Incident report Download

[STRICTLY CONFIDENTIAL] Incident report followup Download

[Nb: the following added on 24 April, 2025 due to oversight]

HR response – [STRICTLY CONFIDENTIAL] Incident report follow-up Download

by Peter Rohde at April 24, 2025 06:45 AM

April 20, 2025

Doug Natelson — A Grand Bargain and its chaotic dissolution

After World War II, under the influence (direct and indirect) of people like Vannevar Bush, a "grand bargain" was effectively struck between the US government and the nation's universities. The war had demonstrated how important science and engineering research could be, through the Manhattan Project and the development of radar, among other things. University researchers had effectively and sometimes literally been conscripted into the war effort. In the postwar period, with more citizens than ever going to college because of the GI Bill, universities went through a period of rapid growth, and the government began funding research at universities on the large scale. This was a way of accomplishing multiple goals. This funding got hundreds of scientists and engineers to work on projects that agencies and the academic community itself (through peer review) thought would be important but perhaps were of such long-term or indirect economic impact that industry would be unlikely to support them. It trained the next generation of researchers and of the technically skilled workforce. It accomplished this as a complement to national laboratories and direct federal agency work.

After Sputnik, there was an enormous ramp-up of investment. This figure (see here for an interactive version) shows different contributions to investment in research and development in the US from 1953 through 2021:

Figure from NSF report on US R&D investment

A couple of days ago, the New York Times published a related figure, showing the growth in dollars of total federal funds sent to US universities, but I think this is a more meaningful graph (hat tip to Prof. Elizabeth Popp Berman at Michigan for her discussion of this). In 2021, federal investment in research (the large majority of which is happening at universities) as a percentage of GDP was at its lowest level since 1953, and it was sinking further even before this year (for those worried about US competitiveness.... Also, industry does a lot more D than they do long-term R.). There are many studies by economists showing that federal investment in research has a large return (for example, here is one by the Federal Reserve Bank of Dallas saying that returns to the US economy on federal research expenditures are between 150% and 300%). Remember, these funds are not just given to universities - they are in the form of grants and contracts, for which specific work is done and reported. These investments also helped make US higher education the envy of much of the world and led to education of international students as a tremendous effective export business for the country.

Of course, like any system created organically by people, there are problems. Universities are complicated and full of (ugh) academics. Higher education is too expensive. Compliance bureaucracy can be onerous. Any deliberative process like peer review trades efficiency for collective expertise but also the hazards of group-think. At the same time, the relationship between federally sponsored research and universities has led to an enormous amount of economic, technological, and medical benefit over the last 70 years.

Right now it looks like this whole apparatus is being radically altered, if not dismantled in part or in whole. Moreover, this is not happening as a result of a debate or discussion about the proper role and scale of federal spending at universities, or an in-depth look at the flaws and benefits of the historically developed research ecosystem. It's happening because "elections have consequences", and I'd be willing to bet that very very few people in the electorate cast their votes even secondarily because of this topic. Sincere people can have differing opinions about these issues, but decisions of such consequence and magnitude should not be taken lightly or incidentally.

(I am turning off comments on this one b/c I don't have time right now to pay close attention. Take it as read that some people would comment that US spending must be cut back and that this is a consequence.)

by Douglas Natelson at April 20, 2025 07:30 PM

April 18, 2025

Doug Natelson — US science situation updates and what's on deck

Many things have been happening in and around US science. This is a non-exhaustive list of recent developments and links:

There have been very large scale personnel cuts across HHS, FDA, CDC, NIH - see here. This includes groups like the people who monitor lead in drinking water.
There is reporting about the upcoming presidential budget requests about NASA and NOAA. The requested cuts are very deep. To quote Eric Berger's article linked above, for the science part of NASA, "Among the proposals were: A two-thirds cut to astrophysics, down to $487 million; a greater than two-thirds cut to heliophysics, down to $455 million; a greater than 50 percent cut to Earth science, down to $1.033 billion; and a 30 percent cut to Planetary science, down to $1.929 billion." The proposed cuts to NOAA are similarly deep, seeking to end climate study in the agency, as Science puts it. The full presidential budget request, including NSF, DOE, NIST, etc. is still to come. Remember, Congress in the past has often essentially ignored presidential budget requests. It is unclear if the will exists to do so now.
Speaking of NSF, the graduate research fellowship program award announcements for this year came out this past week. The agency awarded slightly under half as many of these prestigious 3-year fellowships as in each of the last 15 years. I can only presume that this is because the agency is deeply concerned about its budgets for the next couple of fiscal years.
Grants are being frozen at several top private universities - these include Columbia (new cancellations), the University of Pennsylvania (here), Harvard (here), Northwestern and Cornell (here), and Princeton (here). There are various law suits filed about all of these. Princeton and Harvard have been borrowing money (issuing bonds) to partly deal with the disruption as litigation continues. The president of Princeton has been more vocal than many about this.
There has been a surge in visa revocations and unannounced student status changes in SEVIS for international students in the US. To say that this is unsettling is an enormous understatement. See here for a limited discussion. There seems to be deep reluctance for universities to speak out about this, presumably from the worry that saying the wrong thing will end up placing their international students and scholars at greater exposure.
On Friday evening, the US Department of Energy put out a "policy flash", stating that indirect cost rates on its grants would be cut immediately to 15%. This sounds familiar. Legal challenges are undoubtedly beginning.
Added bonus: According to the Washington Post, DOGE (whatever they say they are this week) is now in control of grants.gov, the website that posts funding opportunities. As the article says, "Now the responsibility of posting these grant opportunities is poised to rest with DOGE — and if its employees delay those postings or stop them altogether, 'it could effectively shut down federal-grant making,' said one federal official who spoke on the condition of anonymity to describe internal operations."

None of this is good news for the future of science and engineering research in the US. If you are a US voter and you think that university-based research is important, I encourage you to contact your legislators and make your opinions heard.

(As I have put in my profile, what I write here are my personal opinions; I am not in any way speaking for my employer. That should be obvious, but it never hurts to state it explicitly.)

Update: NSF has "disestablished" the advisory committees associated with its directorates (except the recently created TIP directorate). Coverage here in Science. This is not good, and I worry that it bodes ill for large cutbacks.

Update 4/18: NSF is now terminating active grants, having "updated" their "priorities".

by Douglas Natelson at April 18, 2025 09:10 PM

Matt von Hippel — I’ve Felt Like a Hallucinating LLM

ChatGPT and its kin work by using Large Language Models, or LLMs.

A climate model is a pile of mathematics and code, honed on data from the climate of the past. Tell it how the climate starts out, and it will give you a prediction for what happens next.

Similarly, a language model is a pile of mathematics and code, honed on data from the texts of the past. Tell it how a text starts, and it will give you a prediction for what happens next.

We have a rough idea of what a climate model can predict. The climate has to follow the laws of physics, for example. Similarly, a text should follow the laws of grammar, the order of verbs and nouns and so forth. The creators of the earliest, smallest language models figured out how to do that reasonably well.

Texts do more than just follow grammar, though. They can describe the world. And LLMs are both surprisingly good and surprisingly bad at that. They can do a lot when used right, answering test questions most humans would struggle with. But they also “hallucinate”, confidently saying things that have nothing to do with reality.

If you want to understand why large language models make both good predictions and bad, you shouldn’t just think about abstract “texts”. Instead, think about a specific type of text: a story.

Stories follow grammar, most of the time. But they also follow their own logic. The hero sets out, saves the world, and returns home again. The evil queen falls from the tower at the climax of the final battle. There are three princesses, and only the third can break the spell.

We aren’t usually taught this logic, like we’re taught physics or grammar. We learn it from experience, from reading stories and getting used to patterns. It’s the logic, not of how a story must go, but of how a story typically goes. And that question, of what typically comes next, is exactly the question LLMs are designed to answer.

It’s also a question we sometimes answer.

I was a theatre kid, and I loved improv in particular. Some of it was improv comedy, the games and skits you might have seen on “Whose Line is it Anyway?” But some of it was more…hippy stuff.

I’d meet up with a group on Saturdays. One year we made up a creation myth, half-rehearsed and half-improvised, a collection of gods and primordial beings. The next year we moved the story forward. Civilization had risen…and fallen again. We played a group of survivors gathered around a campfire, wary groups wondering what came next.

We plotted out characters ahead of time. I was the “villain”, or the closest we had to one. An enforcer of the just-fallen empire, the oppressor embodied. While the others carried clubs, staves, and farm implements, I was the only one with a real weapon: a sword.

(Plastic in reality, but the audience knew what to do.)

In the arguments and recriminations of the story, that sword set me apart, a constant threat that turned my character from contemptible to dangerous, that gave me a seat at the table even as I antagonized and stirred the pot.

But the story had another direction. The arguments pushed and pulled, and gradually the survivors realized that they would not survive if they did not put their grievances to rest, if they did not seek peace. So, one man stepped forward, and tossed his staff into the fire.

The others followed. One by one, clubs and sticks and menacing tools were cast aside. And soon, I was the only one armed.

If I was behaving logically, if I followed my character’s interests, I would have “won” there. I had gotten what I wanted, now there was no check on my power.

But that wasn’t what the story wanted. Improv is a game of fast decisions and fluid invention. We follow our instincts, and our instincts are shaped by experience. The stories of the past guide our choices, and must often be the only guide: we don’t have time to edit, or to second-guess.

And I felt the story, and what it wanted. It was a command that transcended will, that felt like it left no room for an individual actor making an individual decision.

I cast my sword into the fire.

The instinct that brought me to do that is the same instinct that guides authors when they say that their characters write themselves, when their story goes in an unexpected direction. It’s an instinct that can be tempered and counteracted, with time and effort, because it can easily lead to nonsense. It’s why every good book needs an editor, why improv can be as repetitive as it is magical.

And it’s been the best way I’ve found to understand LLMs.

An LLM telling a story tells a typical story, based on the data used to create it. In the same way, an LLM giving advice gives typical advice, to some extent in content but more importantly in form, advice that is confident and mentions things advice often mentions. An LLM writing a biography will write a typical biography, which may not be your biography, even if your biography was one of those used to create it, because it tries to predict how a biography should go based on all the other biographies. And all of these predictions and hallucinations are very much the kind of snap judgement that disarmed me.

These days, people are trying to build on top of LLMs and make technology that does more, that can edit and check its decisions. For the most part, they’re building these checks out of LLMs. Instead of telling one story, of someone giving advice on the internet, they tell two stories: the advisor and the editor, one giving the advice and one correcting it. They have to tell these stories many times, broken up into many parts, to approximate something other than the improv actor’s first instincts, and that’s why software that does this is substantially more expensive than more basic software that doesn’t.

I can’t say how far they’ll get. Models need data to work well, decisions need reliability to be good, computers need infrastructure to compute. But if you want to understand what’s at an LLM’s beating heart, think about the first instincts you have in writing or in theatre, in stories or in play. Then think about a machine that just does that.

by 4gravitons at April 18, 2025 04:00 PM

Matt Strassler Blog on Indefinite Pause

by Matt Strassler at April 18, 2025 03:23 AM

April 16, 2025

Tommaso Dorigo — On A Roll

What? Another boring chess game?

Buzz off, this is my blog, and if I feel like posting a chess game, that's what is going to happen. But if you like the game, stay here - this is a nice game.

Again played after hiours today, and again on a 5' online blitz server (chess.com). What amazes me is that these days I seem to have a sort of touch for nice attacks and brilliant combinations. Let me show you why I am saying this.

The starting position arose after the following opening sequence:

tommasodorigo - UTOPII841, chess.com April 16 2025

by Tommaso Dorigo at April 16, 2025 07:43 PM

Scott Aaronson I speak at Harvard as it faces its biggest crisis since 1636

Every week, I tell myself I won’t do yet another post about the asteroid striking American academia, and then every week events force my hand otherwise.

No one on earth—certainly no one who reads this blog—could call me blasé about the issue of antisemitism at US universities. I’ve blasted the takeover of entire departments and unrelated student clubs and campus common areas by the dogmatic belief that the State of Israel (and only Israel, among all nations on earth) should be eradicated, by the use of that belief as a litmus test for entry. Since October 7, I’ve dealt with comments and emails pretty much every day calling me a genocidal Judeofascist Zionist.

So I hope it means something when I say: today I salute Harvard for standing up to the Trump administration. And I’ll say so in person, when I visit Harvard’s math department later this week to give the Fifth Annual Yip Lecture, on “How Much Math Is Knowable?” The more depressing the news, I find, the more my thoughts turn to the same questions that bothered Euclid and Archimedes and Leibniz and Russell and Turing. Actually, what the hell, why don’t I share the abstract for this talk?

Theoretical computer science has over the years sought more and more refined answers to the question of which mathematical truths are knowable by finite beings like ourselves, bounded in time and space and subject to physical laws. I’ll tell a story that starts with Gödel’s Incompleteness Theorem and Turing’s discovery of uncomputability. I’ll then introduce the spectacular Busy Beaver function, which grows faster than any computable function. Work by me and Yedidia, along with recent improvements by O’Rear and Riebel, has shown that the value of BB(745) is independent of the axioms of set theory; on the other end, an international collaboration proved last year that BB(5) = 47,176,870. I’ll speculate on whether BB(6) will ever be known, by us or our AI successors. I’ll next discuss the P≠NP conjecture and what it does and doesn’t mean for the limits of machine intelligence. As my own specialty is quantum computing, I’ll summarize what we know about how scalable quantum computers, assuming we get them, will expand the boundary of what’s mathematically knowable. I’ll end by talking about hypothetical models even beyond quantum computers, which might expand the boundary of knowability still further, if one is able (for example) to jump into a black hole, create a closed timelike curve, or project oneself onto the holographic boundary of the universe.

Now back to the depressing news. What makes me take Harvard’s side is the experience of Columbia. Columbia had already been moving in the right direction on fighting antisemitism, and on enforcing its rules against disruption, before the government even got involved. Then, once the government did take away funding and present its ultimatum—completely outside the process specified in Title VI law—Columbia’s administration quickly agreed to everything asked, to howls of outrage from the left-leaning faculty. Yet despite its total capitulation, the government has continued to hold Columbia’s medical research and other science funding hostage, while inventing a never-ending list of additional demands, whose apparent endpoint is that Columbia submit to state ideological control like a university in Russia or Iran.

By taking this scorched-earth route, the government has effectively telegraphed to all the other universities, as clearly as possible: “actually, we don’t care what you do or don’t do on antisemitism. We just want to destroy you, and antisemitism was our best available pretext, the place where you’d most obviously fallen short of your ideals. But we’re not really trying to cure a sick patient, or force the patient to adopt better health habits: we’re trying to shoot, disembowel, and dismember the patient. That being the case, you might as well fight us and go down with dignity!”

No wonder that my distinguished Harvard friends (and past Shtetl-Optimized guest bloggers) Steven Pinker and Boaz Barak—not exactly known as anti-Zionist woke radicals—have come out in favor of Harvard fighting this in court. So has Harvard’s past president Larry Summers, who’s welcome to guest-blog here as well. They all understand that events have given us no choice but to fight Trump as if there were no antisemitism, even while we continue to fight antisemitism as if there were no Trump.

Update (April 16): Commenter Greg argues that, in the title of this post, I probably ought to revise “Harvard’s biggest crisis since 1636” to “its biggest crisis since 1640.” Why 1640? Because that’s when the new college was shut down, over allegations that its head teacher was beating the students and that the head teacher’s wife (who was also the cook) was serving the students food adulterated with dung. By 1642, Harvard was back on track and had graduated its first class.

by Scott at April 16, 2025 12:45 PM

April 15, 2025

n-Category Café Position in Stellenbosch

$MathML-enabled post (click for more details).$

guest post by Bruce Bartlett

Stellenbosch University is hiring!

$MathML-enabled post (click for more details).$

The Mathematics Division at Stellenbosch University in South Africa is looking to hire a new permanent appointment at Lecturer / Senior Lecturer level (other levels may be considered too under the appropriate circumstances).

Preference will be given to candidates working in number theory or a related area, but those working in other areas of mathematics will definitely also be considered.

The closing date for applications is 30 April 2025. For more details, kindly see the official advertisement.

Consider a wonderful career in the winelands area of South Africa!

Tommaso Dorigo — When The Attack Plays Itself

After a very intense day at work, I sought some relaxation in online blitz chess today. And the game gave me the kick I was hoping I'd get. After a quick Alapin Sicilian opening, we reached the following position (diagram 1):

As you can see, black is threatening a checkmate with Qxg2++. However, the last move was a serious error, as it neglected the intrinsic power of my open files and diagonals against the black king. Can you find the sequence with which I quickly destroyed my opponent's position?

1. Qc2!

by Tommaso Dorigo at April 15, 2025 03:42 PM

Doug Natelson — Talk about "The Direct Democracy of Matter"

The Scientia Institute at Rice sponsors series of public lectures annually, centered around a theme. The intent is to get a wide variety of perspectives spanning across the humanities, social sciences, arts, sciences, and engineering, presented in an accessible way. The youtube channel with recordings of recent talks is here.

This past year, the theme was "democracy" in its broadest sense. I was honored to be invited last year to contribute a talk, which I gave this past Tuesday, following a presentation by my CS colleague Rodrigo Ferreira about whether AI has politics. Below I've embedded the video, with the start time set where I begin (27:00, so you can rewind to see Rodrigo).

Which (macroscopic) states of matter to we see? The ones that "win the popular vote" of the microscopic configurations.

by Douglas Natelson at April 15, 2025 01:18 PM

n-Category Café Categorical Linguistics in Quanta

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Quanta magazine has just published a feature on Tai-Danae Bradley and her work, entitled

Where Does Meaning Live in a Sentence? Math Might Tell Us.

The mathematician Tai-Danae Bradley is using category theory to try to understand both human and AI-generated language.

It’s a nicely set up Q&A, with questions like “What’s something category theory lets you see that you can’t otherwise?” and “How do you use category theory to understand language?”

Particularly interesting for me is the part towards the end where Bradley describes her work with Juan Pablo Vigneaux on magnitude of enriched categories of texts.

April 14, 2025

Matt Strassler Is Superposition Really an “OR”?

We’ll get back to measurement, interference and the double-slit experiment just as soon as I can get my math program to produce pictures of the relevant wave functions reliably. I owe you some further discussion of why measurement (and even interactions without measurement) can partially or completely eliminate quantum interference.

But in the meantime, I’ve gotten some questions and some criticism for arguing that superposition is an OR, not an AND. It is time to look closely at this choice, and understand both its strengths and its limitations, and how we have to move beyond it to fully appreciate quantum physics. [I probably should have written this article earlier — and I suspect I’ll need to write it again someday, as it’s a tricky subject.]

The Question of Superposition

Just to remind you of my definitions (we’ll see examples in a moment): objects that interact with one another form a system, and a system is at any time in a certain quantum state, consisting of one or more possibilities combined in some way and described by what is often called a “wave function”. If the number of possibilities described by the wave function is more than one, then physicists say that the state of the quantum system is a superposition of two or more basic states. [Caution: as we’ll explore in later posts, the number of states in the superposition can depend on one’s choice of “basis”.]

As an example, suppose we have two boxes, L and R for left and right, and two atoms, one of hydrogen H and one of nitrogen N. Our physical system consists of the two atoms, and depending on which box each atom is in, the system can exist in four obvious possibilities, shown in Fig. 1:

H_L N_L (i.e. both the hydrogen atom and the nitrogen atom are in the left box)
H_L N_R
H_R N_L
H_R N_R

*Figure 1: The four intuitively obvious options for how to store the two atoms in the boxes correspond to four basic states of the quantum system.*

Before quantum physics, we would have thought those were the only options; each atom must be in one box or the other. But in quantum physics there are many more non-obvious possibilities.

In particular, we could put the system in a superposition of the form H_L N_L + H_R N_R, shown in Fig. 2. In the jargon of physics, “the system is in a superposition of H_L N_L and H_R N_R“. Note the use of the word “and” here. But don’t read too much into it; jargon often involves linguistic shorthand, and can be arbitrary and imprecise. The question I’m focused on here is not “what do physicists say?”, but “what does it actually mean?”

*Figure 2: A quantum system can be in a superposition, such as this one represented by two basic states related by a “+” symbol. (This is not the most general case, as discussed below.)*

In particular, does it mean that “H_L N_L AND H_R N_R” are true? Or does it mean “H_L N_L OR H_R N_R” is true? Or does it mean something else?

The Problems with “AND”

First, let’s see why the “AND” option has a serious problem.

In ordinary language, if I say that “A AND B are true”, then I mean that one can check that A is true and also, separately, that B is true — i.e., both A and B are true. With this meaning in mind, it’s clear that experiments do not encourage us to view superposition as an AND. (There are theory interpretations of quantum physics that do encourage the use of “AND”, a point I’ll return to.)

Experiment Is Skeptical

Specifically, if a system is in a quantum superposition of two states A and B, no experiment will ever show that

A is true
AND
B is true.

Instead, in any experiment explicitly designed to check whether A is true and whether B is true, the result will only reveal, at best, that

A is true and B is not true
OR
B is true and A is not true.

The result might also be ambiguous, neither confirming nor denying that either one is true. But no measurement will ever show that both A AND B are definitively true. The two possibilities A and B are mutually exclusive in any actual measurement that is sensitive to the question.

In our case, if we go looking for our two atoms in the state H_L N_L + H_R N_R — if we do position measurements on both of them — we will either find both of them in the left box OR both of them in the right box. 1920’s quantum physics may be weird, but it does not allow measurements of an atom to find it in two places at the same time: an atom has a position, even if it is inherently uncertain, and if I make a serious attempt to locate it, I will find only one answer (within the precision of the measurement). [Measurement itself requires a long discussion, which I won’t attempt here; but see this post and the following one.]

And so, in this case, a measurement will find that one box has two atoms and the other has zero. Yet if we use “AND” in describing the superposition, we end up saying “both atoms are in the left box AND both atoms are in the right box”, which seems to imply that both atoms are in both boxes, contrary to any experiment. Again, certain theoretical approaches might argue that they are in both boxes, but we should obviously be very cautious when experiment disagrees with theoretical reasoning.

The Fortunate and/or Unfortunate Cat

The example of Schrodinger’s cat is another context in which some writers use “and” in describing what is going on.

A reminder of the cat experiment: We have an atom which may decay now or later, according to a quantum process whose timing we cannot predict. If the atom decays, it initiates a chain reaction which kills the cat. If the atom and the cat are placed inside a sealed box, isolating them completely from the rest of the universe, then the initial state, with an intact atom (A_i) and a Live cat (C_L), will evolve to a state in a superposition roughly of the form A_i C_L + A_d C_D, where A_d refers to a decayed atom and C_D refers to a Dead cat. (More precisely, the state will take the form c₁ A_i C_L + c₂ A_d C_D, where c₁ and c₂ are complex numbers with |c₁|² + |c₂|² = 1; but we can ignore these numbers for now.)

Figure 3: *As in Figure 2, a superposition can even, in principle, be applied to macroscopic objects. This includes the famous Schrodinger cat state.*

Leaving aside that the experiment is both unethical and impossible in practice, it raises an important point about the word “AND”. It includes a place where we must say “AND“; there’s no choice.

As we close the box to start the experiment, the atom is intact AND the cat is alive; both are simultaneously true, as measurement can verify. The state that we use to describe this, A_i C_L, is a mathematical product: implicitly “A_i C_L” means A_i x C_L, where x is the “times” symbol.

Figure 4: *It is unambiguous that the initial state of the cat-atom system is that the atom is intact **AND** the cat is alive: A_i x **C_L**.*

Later, the state to which the system evolves is a sum of two products — a superposition (A_i x C_L) + (A_d x C_D) which includes two “AND” relationships

1) “the atom is intact AND the cat is alive” (A_i x C_L)
2) “the atom has decayed AND the cat is dead” (A_d x C_D)

In each of these two possibilities, the state of the atom and the state of the cat are perfectly correlated; if you know one, you know the other. To use language consistent with English (and all other languages with which I am familiar), we must use “AND” to describe this correlation. (Note: in this particular example, correlation does in fact imply causation — but that’s not a requirement here. Correlation is enough.)

It is then often said that, theoretically, that “before we open the box, the cat is both alive AND dead”. But again, if we open the box to find out, experimentally, we will find out either that “the cat is alive OR the cat is dead.” So we should think this through carefully.

We’ve established that “x” must mean “AND“, as in Fig. 4. So let’s try to understand the “+” that appears in the superposition (A_i x C_L) + (A_d x C_D). It is certainly the case that such a state doesn’t tell us whether C_L is true or C_D is true, or even that it is meaningful to say that only one is true.

But suppose we decide that “+” means “AND“, also. Then we end up saying

“(the cat is alive AND the atom is intact) AND (the cat is dead AND the atom has decayed.)”

That’s very worrying. In ordinary English, if I’m referring to some possible facts A,B,C, and D, and I tell you that “(A AND B are true) AND (C AND D are true)”, the logic of the language implies that A AND B AND C AND D are all true. But that standard logic would leads to a falsehood. It is absolutely not the case, in the state (A_i x C_L) + (A_d x C_D), that C_L is true and A_d is true — we will never find, in any experiment, that the cat is alive and yet the atom has decayed. That could only happen if the system were in a superposition that includes the possibility A_d x C_L. Nor (unless we wait a few years and the cat dies of old age) can it be the case that C_D is true and A_i is true.

And so, if “x” means “AND” and “+” means “AND“, it’s clear that these are two different meanings of “AND.”

“AND” and “AND”

Is that okay? Well, lots of words have multiple meanings. Still, we’re not used to the idea of “AND” being ambiguous in English. Nor are “x” and “+” usually described with the same word. So using “AND” is definitely problematic.

(That said, people who like to think in terms of parallel “universes” or “branches” in which all possibilities happen [the many-worlds interpretation] may actually prefer to have two meanings of “AND”, one for things that happen in two different branches, and one for things that happen in the same branch. But this has some additional problems too, as we’ll see later when we get to the subtleties of “OR”.)

These issues are why, in my personal view, “OR” is better when one first learns quantum physics. I think it makes it easier to explain how quantum physics is both related to standard probabilities and yet goes beyond it. For one thing, “or” is already ambiguous in English, so we’re used to the idea that it might have multiple meanings. For another, we definitely need “+” to be conceptually different from “x“, so it is confusing, pedagogically, to start right off by saying that both mathematical operators are “AND”.

But “OR” is not without its problems.

The Problems with “OR”

In normal English, saying “the atom is intact and the cat is alive” OR “the atom has decayed and the cat is dead” would tell us two possible facts about the current contents of the box, one of which is definitely true.

But in quantum physics, the use of “OR” in the Schrodinger cat superposition does not tell us what is currently happening inside the box. It does tell us the state of the system at the moment, but all that does is predict the possible outcomes that would be observed if the box were opened right now (and their probabilities.) That’s less information than telling us the properties of what is in the closed box.

The advantage of “OR” is that it does tell us the two outcomes of opening the box, upon which we will find

“The atom is intact AND the cat is alive”
OR
“The atom has decayed AND the cat is dead”

Similarly, for our box of atoms, it tells us that if we attempt to locate the atoms, we will find that

“the hydrogen atom is in the left box AND the nitrogen atom is in the left box”
OR
“the hydrogen atom is in the right box AND the nitrogen atom is in the right box”

In other words, this use of AND and OR agrees with what experiments actually find. Better this than the alternative, it seems to me.

Nevertheless, just because it is better doesn’t mean it is unproblematic.

The Usual Or

The word “OR” is already ambiguous in usual English, in that it could mean

either A is true or B is true
A is true or B is true or both are true

Which of these two meanings is intended in an English sentence has to be determined by context, or explained by the speaker. Here I’m focused on the first meaning.

Returning to our first example of Figs. 1 and 2, suppose I hand the two atoms to you and ask you to put them in either box, whichever one you choose. You do so, but you don’t tell me what your choice was, and you head off on a long vacation.

While I wait for you to return, what can I say about the two atoms? Assuming you followed my instructions, I would say that

“both atoms are in the left box OR both atoms are in the right box”

In doing so, I’m using “or” in its “either…or…” sense in ordinary English. I don’t know which box you chose, but I still know (Fig. 5) that the system is either definitely in the H_L N_L state OR definitely in the H_R N_R state of Fig. 1. I know this without doing any measurement, and I’m only uncertain about which is which because I’m missing information that you could have provided me. The information is knowable; I just don’t have it.

Figure 5: *The atoms were definitely put into in one box or the other, but nobody told me which box was selected.*

But this uncertainty about which box the atoms are in is completely different from the uncertainty that arises from putting the atoms in the superposition state H_L N_L + H_R N_R!

The Superposition OR

If the system is in the state H_L N_L + H_R N_R, i.e. what I’ve been calling (“H_L N_L OR H_R N_R“), it is in a state of inherent uncertainty of whether the two atoms are in the left box or in the right box. It is not that I happen not to know which box the atoms are in, but rather that this information is not knowable within the rules of quantum physics. Even if you yourself put the atoms into this superposition, you don’t know which box they’re in any more than I do.

The only thing we can try to do is perform an experiment and see what the answer is. The problem is that we cannot necessarily infer, if we find both atoms in the left box, that the two atoms were in that box prior to that measurement.

If we do try to make that assumption, we find ourselves in apparent contradiction with experiment. The issue is quantum interference. If we repeat the whole process, but instead of opening the boxes to see where the atoms are, we first bring the two boxes together and measure the atoms’ properties, we will observe quantum interference effects. As I have discussed in my recent series of five posts on interference (starting here), quantum interference can only occur when a system takes at least two paths to its current state; but if the two atoms were definitely in one box or definitely in the other, then there would be only one path in Fig. 6.

Figure 6: In the superposition state, the atoms cannot simply be in definite but unknown locations, as in Fig. 5. If the boxes are joined and then opened, quantum interference will occur, implying the system has evolved via **two** paths to a single state.

Prior to the measurement, the system had inherent uncertainty about the question, and while measurement removes the current uncertainty, it does not in general remove the past uncertainty. The act of measurement changes the state of the system — more precisely, it changes the state of the larger system that includes both atoms and the measurement device — and so establishing meaningfully that the two atoms are now in the left box is not sufficient to tell us meaningfully that the two atoms were previously and definitively in the left box.

So if this is “OR“, it is certainly not what it usually means in English!

This Superposition or That One?

And it gets worse, because we can take more complex examples. As I mentioned when discussing the poor cat, the superposition H_L N_L + H_R N_R is actually one in a large class of superpositions, of the form c₁ H_L N_L + c₂ H_R N_R , where c₁ and c₂ are complex numbers. A second simple example of such a superposition is H_L N_L – H_R N_R, with a minus sign instead of a plus sign.

So suppose I had asked you to put the two atoms in a superposition either of the form H_L N_L + H_R N_R or H_L N_L – H_R N_R, your choice; and suppose you did so without telling me which superposition you chose. What would I then know?

I would know that the system is either in the state (H_L N_L + H_R N_R) or in the state (H_L N_L – H_R N_R), depending on what you chose to do. In words, what I would know is that the system is represented by

(H_L N_L OR H_R N_R) OR (H_L N_L OR H_R N_R)

Uh oh. Now we’re as badly off as we were with “AND“.

First, the “OR” in the center is a standard English “OR” — it means that the system is definitely in one superposition or the other, but I don’t know which one — which isn’t the same thing as the “OR“s in the parentheses, which are “OR“s of superposition that only tell us what the results of measurements might be.

Second, the two “OR“s in the parentheses are different, since one means “+” and the other means “–“. In some other superposition state, the OR might mean 3/5 + i 4/5, where i is the standard imaginary number equal to the square root of -1. In English, there’s obviously no room for all this complexity. [Note that I’d have the same problem if I used “AND” for superpositions instead.]

So even if “OR” is better, it’s still not up to the task. Superposition forces us to choose whether to have multiple meanings of “AND” or multiple meanings of “OR”, including meanings that don’t hold in ordinary language. In a sense, the “+” (or “-” or whatever) in a superposition is a bit more “AND” than standard English “OR”, but it’s also a bit more “OR” than a standard English “AND”. It’s something truly new and unfamiliar.

Experts in the foundational meaning of quantum physics argue over whether to use “OR” or “AND”. It’s not an argument I want to get into. My goal here is to help you understand how quantum physics works with the minimum of interpretation and the minimum of mathematics. This requires precise language, of course. But here we find we cannot avoid a small amount of math — that of simple numbers, sometimes even complex numbers — because ordinary language simply can’t capture the logic of what quantum physics can do.

I will continue, for consistency, to use “OR” for a superposition, but going forward we must admit and recognize its limitations, and become more sophisticated about what it does and doesn’t mean. One should understand my use of “OR“, and the “pre-quantum viewpoint” that I often employ, as pedagogical methodology, not a statement about nature. Specifically, I have been trying to clarify the crucial idea of the space of possibilities, and to show examples of how quantum physics goes beyond pre-quantum physics. I find the “pre-quantum viewpoint”, where it is absolutely required that we use “OR”, helps students get the basics straight. But it is true that the pre-quantum viewpoint obscures some of the full richness and complexity of quantum phenomena, much of which arises precisely because the quantum “OR” is not the standard “OR” [and similarly if you prefer “AND” instead.] So we have to start leaving it behind.

There are many more layers of subtlety yet to be uncovered [for instance, what if my system is in a state (A OR B), but I make a measurement that can’t directly tell me whether A is true or B is true?] but this is enough for today.

I’m grateful to Jacob Barandes for a discussion about some of these issues.

Conceptual Summary

When we use “A AND B” in ordinary language, we mean “A is true and B is true”.
When we use “A OR B” in ordinary language, we find “OR” is ambiguous even in English; it may mean
- “either A is true or B is true”, or
- “A is true or B is true or both are true.”
In my recent posts, when I say a superposition c₁ A + c₂ B can be expressed as “A OR B”, I mean something that I cannot mean in English, because such a meaning would never normally occur to us:
- I mean that the result of an appropriate measurement carried out at this moment will give the result A or the result B (but not both).
- I do so without generally implying that the state of the system, if I don’t carry out the measurement, is definitely A or definitely B (though unknown).
- Instead the system could be viewed as being in an uncanny state of being that we’re not used to, for which neither ordinary “AND” nor ordinary “OR” applies.
Note also that using either “AND” or “OR” is unable to capture the difference between superpositions that involve the same states but differ in the numbers c₁, c₂.

The third bullet point is open to different choices about “AND” and “OR“, and open to different interpretation about what superposition states imply about the systems that are in them. There are different consistent ways to combine the language and concepts, and the particular choice I’ve made is pragmatic, not dogmatic. For a single set of blog posts that tell a coherent story, I have to to pick a single consistent language; but it’s a choice. Once one’s understanding of quantum physics is strong, it’s both valuable and straightforward to consider other possible choices.

by Matt Strassler at April 14, 2025 10:34 PM

April 12, 2025

Jordan Ellenberg — Another thing about the White Lotus

The finale of season 3 having aired, an old post of mine about The White Lotus season 1 is getting a lot of hits. So let me just say that I think the conclusion of season 3 very much backs up my 2021 read of Belinda’s character.

by JSE at April 12, 2025 03:43 PM

Jordan Ellenberg — I Just Saw a Face

My sister-in-law was explaining to me a difference between British and US standard English — in Britain, “just” acts as a marker requiring the past perfect, but in America, that’s not the case. So the Beatles sing “I’ve Just Seen a Face,” not “I Just Saw a Face,” while Stevie Wonder sings “I Just Called To Say I Love You,” not “I’ve Just Called To Say I Fancy You.”

Is this a Beatles song you’re aware of? Not one of their biggest hits but wonderful. Paul McCartney was always just kind of finding perfect pop songs like this between his couch cushions. “I’ve just cleaned my couch,” he’d say, and there it was.

by JSE at April 12, 2025 03:38 PM

April 10, 2025

Tommaso Dorigo — Toponium Found By CMS!

The highest-mass subnuclear particle ever observed used to the the top quark. Measured for the first time by the CDF experiment in 1994, and subsequently confirmed by CDF and D0 in 1995, the top quark is the heaviest elementary particle we know of, and it is a wonderful physical system per se, which has been studied with momentum in the past thirty years at the Tevatron and at the LHC colliders.
The top quark

by Tommaso Dorigo at April 10, 2025 01:43 PM

April 08, 2025

n-Category Café Quantum Ellipsoids

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With the stock market crash and the big protests across the US, I’m finally feeling a trace of optimism that Trump’s stranglehold on the nation will weaken. Just a trace.

I still need to self-medicate to keep from sinking into depression — where ‘self-medicate’, in my case, means studying fun math and physics I don’t need to know. I’ve been learning about the interactions between number theory and group theory. But I haven’t been doing enough physics! I’m better at that, and it’s more visceral: more of a bodily experience, imagining things wiggling around.

So, I’ve been belatedly trying to lessen my terrible ignorance of nuclear physics. Nuclear physics is a fascinating application of quantum theory, but it’s less practical than chemistry and less sexy than particle physics, so I somehow skipped over it.

I’m finding it worth looking at! Right away it’s getting me to think about quantum ellipsoids.

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Nuclear physics forces you to imagine blobs of protons and neutrons wiggling around in a very quantum-mechanical way. Nuclei are too complicated to fully understand. We can simulate them on a computer, but simulation is not understanding, and it’s also very hard: one book I’m reading points out that one computation you might want to do requires diagonalizing a $10^{14} \times 10^{14}$ matrix. So I’d rather learn about the many simplified models of nuclei people have created, which offer partial understanding… and lots of beautiful math.

Protons minimize energy by forming pairs with opposite spin. Same for neutrons. Each pair acts like a particle in its own right. So nuclei act very differently depending on whether they have an even or odd number of protons, and an even or odd number of neutrons!

The ‘Interacting Boson Model’ is a simple approximate model of ‘even-even’ atomic nuclei: nuclei with an even number of protons and an even number of neutrons. It treats the nucleus as consisting of bosons, each boson being either a pair of nucleons — that is, either protons or neutrons — where the members of a pair have opposite spin but are the same in every other way. So, these bosons are a bit like the paired electrons responsible for superconductivity, called ‘Cooper pairs’.

However, in the Interacting Boson Model we assume our bosons all have either spin 0 (s-bosons) or spin 2 (d-bosons), and we ignore all properties of the bosons except their spin angular momentum. A spin-0 particle has 1 spin state, since the spin-0 representation of $\text{SO}(3)$ is 1-dimensional. A spin-2 particle has 5, since the spin-2 representation is 5-dimensional.

If we assume the maximum amount of symmetry among all 6 states, both s-boson and d-boson states, we get a theory with $\text{U}(6)$ symmetry! And part of why I got interested in this stuff was that it would be fun to see a rather large group like $\text{U}(6)$ showing up as symmetries — or approximate symmetries — in real world physics.

More sophisticated models recognize that not all these states behave the same, so they assume a smaller group of symmetries.

But there are some simpler questions to start with.

How do we make a spin-0 or spin-2 particle out of two nucleons? That’s easy. Two nucleons with opposite spin have total spin 0. But if they’re orbiting each other, they have orbital angular momentum too, so the pair can act like a particle with spin 0, 1, 2, 3, etc.

Why are these bosons in the Interacting Boson Model assumed to have spin 0 or spin 2, but not spin 1 or any other spin? This is a lot harder. I assume that at some level the answer is “because this model works fairly well”. But why does it work fairly well?

By now I’ve found two answers for this, and I’ll tell you the more exciting answer, which I found in this book:

Igal Talmi, Simple Models of Complex Nuclei: the Shell Model and Interacting Boson Model, Harwood Academic Publishers, Chur, Switzerland, 1993.

In the ‘liquid drop model’ of nuclei, you think of a nucleus as a little droplet of fluid. You can think of an even-even nucleus as a roughly ellipsoidal droplet, which however can vibrate. But we need to treat it using quantum mechanics. So we need to understand quantum ellipsoids!

The space of ellipsoids in $\mathbb{R}^3$ centered at the origin is 6-dimensional, because these ellipsoids are described by equations like

$A x^2 + B y^2 + C z^2 + D x y + E y z + F z x = 1$

and there are 6 coefficients here. Not all nuclei are close to spherical! But perhaps it’s easiest to start by thinking about ellipsoids that are close to spherical, so that

$(1 + a)x^2 + (1 + b)y^2 + (1 + c)z^2 + d x y + e y z + f z x = 1$

where $a,b,c,d,e,f$ are small. If our nucleus were classical, we’d want equations that describe how these numbers change with time as our little droplet oscillates.

But the nucleus is deeply quantum mechanical. So in the Interacting Boson Model, invented by Iachello, it seems we replace $a,b,c,d,e,f$ with operators on a Hilbert space, say $q_1, \dots, q_6$ , and introduce corresponding momentum operators $p_1, \dots, p_6$ , obeying the usual ‘canonical commutation relations’:

$[q_j, q_k] = [p_j, p_k] = 0, \qquad [p_j, q_k] = - i \hbar \delta_{j k}$

As usual, we can take this Hilbert space to either be $L^2(\mathbb{R}^6)$ or ‘Fock space’ of $\mathbb{C}^6$ : the Hilbert space completion of the symmetric algebra of $\mathbb{C}^6$ . These are two descriptions of the same thing. The Fock space of $\mathbb{C}^6$ gets an obvious representation of the unitary group $\text{U}(6)$ , since that group acts on $\mathbb{C}^6$ . And $L^2(\mathbb{R}^6)$ gets an obvious representation of $\text{SO}(3)$ , since rotations act on ellipsoids and thus on the tuples $(a,b,c,d,e,f) \in \mathbb{R}^6$ that we’re using to describe ellipsoids.

The latter description lets us see where the s-bosons and d-bosons are coming from! Our representation of $\text{SO}(3)$ on $\mathbb{R}^6$ splits into two summands:

the (real) spin-0 representation, which is 1-dimensional because it takes just one number to describe the rotation-invariant aspects of the shape of an ellipsoid centered at the origin: for example, its volume. In physics jargon this number tells us the monopole moment of the mass distribution of our nucleus.
the (real) spin-2 representation, which is 5-dimensional because it takes 5 numbers to describe all other aspects of the shape of an ellipsoid centered at the origin. You need 2 numbers to say in which direction its longest axis points, one number to say how long that axis is, 1 number to say which direction the second-longest axis point in (it’s at right angles to the longest axis), and 1 number to say how long it is. In physics jargon these 5 numbers tell us the quadrupole moment of our nucleus.

This shows us why we don’t get spin-1 bosons! We’d get them if the mass distribution of our nucleus could have a nonzero dipole moment. In other words, we’d get them if we added linear terms $G x + H y + K z$ to our equation

$A x^2 + B y^2 + C z^2 + D x y + E y z + F z x = 1$

But by conservation of momentum, we can assume the center of mass of our nucleus stays at the origin, and set these linear terms to zero.

As usual, we can take linear combinations of the operators $q_j$ and $p_j$ to get annihilation and creation operators for s-bosons and d-bosons. If we want, we can think of these bosons as nucleon pairs. But we don’t need that microscopic interpretation if we don’t want it: we can just say we’re studying the quantum behavior of an oscillating ellipsoid!

After we have our Hilbert space and these operators on it, we can write down a Hamiltonian for our nucleus, or various possible candidate Hamiltonians, in terms of these operators. Talmi’s book goes into a lot of detail on that. And then we can compare the oscillations these Hamiltonians predict to what we see in the lab. (Often we just see the frequencies of the standing waves, which are proportional to the eigenvalues of the Hamiltonian.)

So, from a high-level mathematical viewpoint, what we’ve done is try to define a manifold $M$ of ellipsoid shapes, and then form its cotangent bundle $T^\ast M$ , and then quantize that and start studying ‘quantum ellipsoids’.

Pretty cool! And there’s a lot more to say about it. But I’m wondering if there might be a better manifold of ellipsoid shapes than just $\mathbb{R}^6$ . After all, when $1+a, 1+b$ or $1+c$ become negative things go haywire: our ellipsoid can turn into a hyperboloid! The approach I’ve described is probably fine ‘perturbatively’, i.e. when $a,b,c,d,e,f$ are small. But it may not be the best when our ellipsoid oscillates so much it gets far from spherical.

I think we need a real algebraic geometer here. In both senses of the word ‘real’.

John Baez — Quantum Ellipsoids

With the stock market crash and the big protests across the US, I’m finally feeling a trace of optimism that Trump’s stranglehold on the nation will weaken. Just a trace.

I’m finding it worth looking at! Right away it’s getting me to think about quantum ellipsoids.

The ‘Interacting Boson Model‘ is a simple approximate model of ‘even-even’ atomic nuclei: nuclei with an even number of protons and an even number of neutrons. It treats the nucleus as consisting of bosons, each boson being either a pair of nucleons—that is, either protons or neutrons—where the members of a pair have opposite spin but are the same in every other way. So, these bosons are a bit like the paired electrons responsible for superconductivity, called ‘Cooper pairs’.

If we assume the maximum amount of symmetry among all 6 states, both s-boson and d-boson states, we get a theory with $\text{U}(6)$ symmetry! And part of why I got interested in this stuff was that it would be fun to see a rather large group like $\text{U}(6)$ showing up as symmetries—or approximate symmetries—in real world physics.

More sophisticated models recognize that not all these states behave the same, so they assume a smaller group of symmetries.

But there are some simpler questions to start with.

By now I’ve found two answers for this, and I’ll tell you the more exciting answer, which I found in this book:

• Igal Talmi, Simple Models of Complex Nuclei: the Shell Model and Interacting Boson Model, Harwood Academic Publishers, Chur, Switzerland, 1993.

The space of ellipsoids in $\mathbb{R}^3$ centered at the origin is 6-dimensional, because these ellipsoids are described by equations like

$A x^2 + B y^2 + C z^2 + D x y + E y z + F z x = 1$

and there are 6 coefficients here. Not all nuclei are close to spherical! But perhaps it’s easiest to start by thinking about ellipsoids that are close to spherical, so that

$(1 + a)x^2 + (1 + b)y^2 + (1 + c)z^2 + d x y + e y z + f z x = 1$

where $a,b,c,d,e,f$ are small. If our nucleus were classical, we’d want equations that describe how these numbers change with time as our little droplet oscillates.

$[q_j, q_k] = [p_j, p_k] = 0, \quad [p_j, q_k] = - i \hbar \delta_{j k}$

As usual, we can take this Hilbert space to either be $L^2(\mathbb{R}^6)$ or the ‘Fock space’ on $\mathbb{C}^6$ : the Hilbert space completion of the symmetric algebra of $\mathbb{C}^6$ . These are two descriptions of the same thing. The Fock space on $\mathbb{C}^6$ gets an obvious representation of the unitary group $\text{U}(6)$ , since that group acts on $\mathbb{C}^6$ . And $L^2(\mathbb{R}^6)$ gets an obvious representation of $\text{SO}(3)$ , since rotations act on ellipsoids and thus on the tuples $(a,b,c,d,e,f) \in \mathbb{R}^6$ that we’re using to describe ellipsoids.

The latter description lets us see where the s-bosons and d-bosons are coming from! Our representation of $\text{SO}(3)$ on $\mathbb{R}^6$ splits into two summands:

• the (real) spin-0 representation, which is 1-dimensional because it takes just one number to describe the rotation-invariant aspects of the shape of an ellipsoid centered at the origin: for example, its volume. In physics jargon this number tells us the monopole moment of our nucleus.

• the (real) spin-2 representation, which is 5-dimensional because it takes 5 numbers to describe all other aspects of the shape of an ellipsoid centered at the origin. You need 2 numbers to say in which direction its longest axis points, one number to say how long that axis is, 1 number to say which direction the second-longest axis point in (it’s at right angles to the longest axis), and 1 number to say how long it is. In physics jargon these 5 numbers tell us the quadrupole moment of our nucleus.

$A x^2 + B y^2 + C z^2 + D x y + E y z + F z x = 1$

But by conservation of momentum, we can assume the center of mass of our nucleus stays at the origin, and set these linear terms to zero.

After we have our Hilbert space and some operators on it, we can write down a Hamiltonian for our nucleous, or various possible candidate Hamiltonians, in terms of these operators. Talmi’s book goes into a lot of detail on that. And then we can compare the oscillations these Hamiltonians predict to what we see in the lab. (Often we just see the frequencies of the standing waves, which are proportional to the eigenvalues of the Hamiltonian.)

I think we need a real algebraic geometer here. In both senses of the word ‘real’.

by John Baez at April 08, 2025 04:01 AM

April 03, 2025

Matt Strassler Double Slit: Why Measurement Destroys the Interference Pattern

The quantum double-slit experiment, in which objects are sent toward a wall with two slits and then recorded on a screen behind the wall, creates an interference pattern that builds up gradually, object by object. And yet, it’s crucial that the path of each object on its way to the screen remain unknown. If one measures which of the slits each object passes through, the interference pattern never appears.

Strange things are said about this. There are vague, weird slogans: “measurement causes the wave function to collapse“; “the particle interferes with itself“; “electrons are both particles and waves“; etc. One reads that the objects are particles when they reach the screen, but they are waves when they go through the slits, causing the interference — unless their passage through the slits is measured, in which case they remain particles.

But in fact the equations of 1920s quantum physics say something different and not vague in the slightest — though perhaps equally weird. As we’ll see today, the elimination of interference by measurement is no mystery at all, once you understand both measurement and interference. Those of you who’ve followed my recent posts on these two topics will find this surprisingly straightforward; I guarantee you’ll say, “Oh, is that all?” Other readers will probably want to read

this post on measurement
- (and perhaps this one too about how to make a measurement permanent)
these posts on interference for one particle and for two particles
- (and perhaps this one and this one for more examples)

The Interference Criterion

When do we expect quantum interference? As I’ll review in a moment, there’s a simple criterion:

a system of objects (not the objects themselves!) will exhibit quantum interference if the system, initially in a superposition of possibilities, reaches a single possibility via two or more pathways.

To remind you what that means, let’s compare two contrasting cases (covered carefully in this post.) Figs. 1a and 1b show pre-quantum animations of different quantum systems, in which two balls (drawn blue and orange) are in a superposition of moving left OR moving right. I’ve chosen to stop each animation right at the moment when the blue ball in the top half of the superposition is at the same location as the blue ball in the bottom half, because if the orange ball weren’t there, this is when we’d expect it to see quantum interference.

But for interference to occur, the orange ball, too, must at that same moment be in the same place in both parts of the superposition. That does happen for the system in Fig. 1a — the top and bottom parts of the figure line up exactly, and so interference will occur. But the system in Fig. 1b, whose top and bottom parts never look the same, will not show quantum interference.

Fig. 1a: A system of two balls in a superposition, from a pre-quantum viewpoint. As the system evolves, a moment is reached when the two parts of the superposition are identical. As the system has then reached a single possibility via two routes, quantum interference may result.

Figure 1b: Similar to Fig. 1a, except that when the blue ball is at the same location in both parts of the superposition, the orange ball is at two different locations. At no moment are the two possibilities in the superposition the same, so quantum interference cannot occur.

In other words, quantum interference requires that the two possibilities in the superposition become identical at some moment in time. Partial resemblance is not enough.

The Measurement

A measurement always involves an interaction of some sort between the object we want to measure and the device doing the measurement. We will typically

use a small object to carry out the basic initial measurement, and then
amplify the result so that it can be made permanent.

For today’s purposes, the details of the second step won’t matter, so I’ll focus on the first step.

Setting Up

We’ll call the object going through the slits a “particle”, and we’ll call the measurement device a “measuring ball” (or just “ball” for short.) The setup is depicted in Fig. 2, where the particle is approaching the slits and the measuring ball lies in wait.

Figure 2: A particle (blue) approaches a wall with two slits, behind which sits a screen where the particle’s arrival will be detected. Also present is a lightweight measuring ball (black), ready to fly in and measure the particle’s position by colliding with it *as it passes through the wall*.

If No Measurement is Made at the Slits

Suppose we allow the particle to proceed and we make no measurement of its location as it passes through the slits. Then we can leave the ball where it is, at the position I’ve marked M in Fig. 3. If the particle makes it through the wall, it must pass through one slit or the other, leaving the system in a superposition of the form

the particle is near the left slit [and the ball is at position M]
OR
the particle is near the right slit [and the ball is at position M]

as shown at the top of Fig. 3. (Note: because the ball and particle are independent [unentangled] in this superposition, it can be written in factored form as in Fig. 12 of this post.)

From here, the particle (whose motion is now quite uncertain as a result of passing through a narrow slit) can proceed unencumbered to the screen. Let’s say it arrives at the point marked P, as at the bottom of Fig. 3.

Figure 3: (Top) As the particle passes through the slits, the system is set into a superposition of two possibilities in which the particle passes through the left slit OR the right slit. *(The particle’s future motion is quite uncertain*, as indicated by the green arrows.) In both possibilities, the measuring ball is at point M. (Bottom) If the particle arrives at point P on the screen, then the two possibilties in the superposition become identical, as in Fig. 1a, so quantum interference can result. This will be true no matter what point P we choose, and so an interference pattern will be seen across the whole screen.

Crucially, both halves of the superposition now describe the same situation: particle at P, ball at M. The system has arrived here via two paths:

The particle went through the left slit and arrived at the point P (with the ball always at M),
OR
The particle went through the right slit and arrived at the point P (with the ball always at M).

Therefore, since the system has reached a single possibility via two different routes, quantum interference may be observed.

Specifically, the system’s wave function, which gives the probability for the particle to arrive at any point on the screen, will display an interference pattern. We saw numerous similar examples in this post, this post and this post.

If the Measurement is Made at the Slits

But now let’s make the measurement. We’ll do it by throwing the ball rapidly toward the particle, timed carefully so that, as shown in Fig. 4, either

the particle is at the left slit, in which case the ball passes behind it and travels onward,
OR
the particle is at the right slit, in which case the ball hits it and bounces back.

(Recall that I assumed the measuring ball is lightweight, so the collision doesn’t much affect the particle; for instance, the particle might be an heavy atom, while the measuring ball is a light atom.)

Figure 4: As the particle moves through the wall, the ball is sent rapidly in motion. If the particle passes through the right slit, the ball will hit it and bounce back; if the particle passes through the left slit, the ball will miss it and will continue to the left.

The ball’s late-time behavior reveals — and thus measures — the particle’s behavior as it passed through the wall:

the ball moving to the left means the particle went through the left slit;
the ball moving to the right means the particle went through the right slit.

[Said another way, the ball and particle, which were originally independent before the measurement, have been entangled by the measurement process. Because of the entanglement, knowledge concerning the ball tells us something about the particle too.]

To make this measurement complete and permanent requires a longer story with more details; for instance, we might choose to amplify the result with a Geiger counter. But the details don’t matter, and besides, that takes place later. Let’s keep our focus on what happens next.

The Effect of the Measurement

What happens next is that the particle reaches the point P on the screen. It can do this whether it traveled via the left slit or via the right slit, just as before, and so you might think there should still be an interference pattern. However, remembering Figs. 1a and 1b and the criterion for interference, take a look at Fig. 5.

Figure 5: Following the measurement made in Fig. 4, the arrival of the particle at the point P on the screen finds the ball in two possible locations, depending on which slit the particle went through. In contrast to Fig. 3, the two parts of the superposition are not identical, and so (as in Fig. 1b) no quantum interference pattern will be observed.

Even though the particle by itself could have taken two paths to the point P, the system as a whole is still in a superposition of two different possibilities, not one — more like Fig. 1b than like Fig. 1a. Specifically,

the particle is at position P and the ball is at location M_L (which happens if, in Fig. 4, the particle was near the left slit and the ball continued to the left);
OR
the particle is at position P and the ball is at location M_R (which happens if, in Fig. 4, the particle was near the right slit and the ball bounced back to the right).

The measurement process — by the very definition of “measurement” as a procedure that segregates left-slit cases from right-slit cases — has resulted in the two parts of the superposition being different even when they both have the particle reaching the same point P. Therefore, in contrast to Fig. 3, quantum interference between the two parts of the superposition cannot occur.

And that’s it. That’s all there is to it.

Looking Ahead.

The double-slit experiment is hard to understand if one relies on vague slogans. But if one relies on the math, one sees that many of the seemingly mysterious features of the experiment are in fact straightforward.

I’ll say more about this in future posts. In particular, to convince you today’s argument is really correct, I’ll look more closely at the quantum wave function corresponding to Figs. 3-5, and will reproduce the same phenomenon in simpler examples. Then we’ll apply the resulting insights to other cases, including

measurements that do not destroy interference,
measurements that only partly destroy interference,
destruction of interference without measurement, and
double-slit experiments whose interference can’t be located in physical space,
etc.

by Matt Strassler at April 03, 2025 12:34 PM

April 01, 2025

Matt Strassler Quantum Interference 5: Coming Unglued

Now finally, we come to the heart of the matter of quantum interference, as seen from the perspective of in 1920’s quantum physics. (We’ll deal with quantum field theory later this year.)

Last time I looked at some cases of two particle states in which the particles’ behavior is independent — uncorrelated. In the jargon, the particles are said to be “unentangled”. In this situation, and only in this situation, the wave function of the two particles can be written as a product of two wave functions, one per particle. As a result, any quantum interference can be ascribed to one particle or the other, and is visible in measurements of either one particle or the other. (More precisely, it is observable in repeated experiments, in which we do the same measurement over and over.)

In this situation, because each particle’s position can be studied independent of the other’s, we can be led to think any interference associated with particle 1 happens near where particle 1 is located, and similarly for interference involving the second particle.

But this line of reasoning only works when the two particles are uncorrelated. Once this isn’t true — once the particles are entangled — it can easily break down. We saw indications of this in an example that appeared at the ends of my last two posts (here and here), which I’m about to review. The question for today is: what happens to interference in such a case?

Correlation: When “Where” Breaks Down

Let me now review the example of my recent posts. The pre-quantum system looks like this

Figure 1: *An example of a superposition, in a pre-quantum view, where the two particles are correlated and where interference will occur that involves both particles together.*

Notice the particles are correlated; either both particles are moving to the left OR both particles are moving to the right. (The two particles are said to be “entangled”, because the behavior of one depends upon the behavior of the other.) As a result, the wave function cannot be factored (in contrast to most examples in my last post) and we cannot understand the behavior of particle 1 without simultaneously considering the behavior of particle 2. Compare this to Fig. 2, an example from my last post in which the particles are independent; the behavior of particle 2 is the same in both parts of the superposition, independent of what particle 1 is doing.

Figure 2: Unlike Fig. 1, here the two particles are uncorrelated; the behavior of particle 2 is the same whether particle 1 is moving left OR right. As a result, interference can occur for particle 1 separately from any behavior of particle 2, as shown in this post.

Let’s return now to Fig. 1. The wave function for the corresponding quantum system, shown as a graph of its absolute value squared on the space of possibilities, behaves as in Fig. 3.

Figure 3: *The absolute-value-squared of the wave function for the system in Fig, 1, showing interference as the peaks cross. Note the interference fringes are diagonal relative to the x₁ and x₂ axes.*

But as shown last time in Fig. 19, at the moment where the interference in Fig. 3 is at its largest, if we measure particle 1 we see no interference effect. More precisely, if we do the experiment many times and measure particle 1 each time, as depicted in Fig. 4, we see no interference pattern.

Figure 4: The result of repeated experiments in which we measure particle 1, at the moment of maximal interference, in the system of Fig. 3. Each new experiment is shown as an orange dot; results of past experiments are shown in blue. No interference effect is seen.

We see something analogous if we measure particle 2.

Yet the interference is plain as day in Fig. 3. It’s obvious when we look at the full two-dimensional space of possibilities, even though it is invisible in Fig. 4 for particle 1 and in the analogous experiment for particle 2. So what measurements, if any, can we make that can reveal it?

The clue comes from the fact that the interference fringes lie at a 45 degree angle, perpendicular neither to the x₁ axis nor to the x₂ axis but instead to the axis for the variable ¹/₂(x₁ + x₂), the average of the positions of particle 1 and 2. It’s that average position that we need to measure if we are to observe the interference.

But doing so requires we that we measure both particles’ positions. We have to measure them both every time we repeat the experiment. Only then can we start making a plot of the average of their positions.

When we do this, we will find what is shown in Fig 5.

The top row shows measurements of particle 1.
The bottom row shows measurements of particle 2.
And the middle row shows a quantity that we infer from these measurements: their average.

For each measurement, I’ve drawn a straight orange line between the measurement of x₁ and the measurement of x₂; the center of this line lies at the average position ¹/₂(x₁+x₂). The actual averages are then recorded in a different color, to remind you that we don’t measure them directly; we infer them from the actual measurements of the two particles’ positions.

Figure 5: As in Fig. 4, the result of repeated experiments in which we measure both particles’ positions at the moment of maximal interference in Fig. 3. Top and bottom rows show the position measurements of particles 1 and 2; the middle row shows their average. Each new experiment is shown as two orange dots, they are connected by an orange line, at whose midpoint a new yellow dot is placed. Results of past experiments are shown in blue. No interference effect is seen in the individual particle positions, yet one appears in their average.

In short, the interference is not associated with either particle separately — none is seen in either the top or bottom rows. Instead, it is found within the correlation between the two particles’ positions. This is something that neither particle can tell us on its own.

And where is the interference? It certainly lies near ¹/₂(x₁+x₂)=0. But this should worry you. Is that really a point in physical space?

You could imagine a more extreme example of this experiment in which Fig. 5 shows particle 1 located in Boston and particle 2 located in New York City. This would put their average position within appropriately-named Middletown, Connecticut. (I kid you not; check for yourself.) Would we really want to say that the interference itself is located in Middletown, even though it’s a quiet bystander, unaware of the existence of two correlated particles that lie in opposite directions 90 miles (150 km) away?

After all, the interference appears in the relationship between the particles’ positions in physical space, not in the positions themselves. Its location in the space of possibilities (Fig. 3) is clear. Its location in physical space (Fig. 5) is anything but.

Still, I can imagine you pondering whether it might somehow make sense to assign the interference to poor, unsuspecting Middletown. For that reason, I’m going to make things even worse, and take Middletown out of the middle.

A Second System with No Where

Here’s another system with interference, whose pre-quantum version is shown in Figs. 6a and 6b:

Figure 6a: Another *system in a superposition with entangled particles, shown in its pre-quantum version in physical space.* In part A of the superposition both particles are stationary, while in part B they move oppositely.

Figure 6b: The same system as in Fig. 6a, depicted in the space of possibilities with its two initial possibilities labeled as stars. Possibility A remains where it is, while possibility B moves toward and intersects with possibility A, leading us to expect interference in the quantum wave function.

The corresponding wave function is shown in Fig. 7. Now the interference fringes are oriented diagonally the other way compared to Fig. 3. How are we to measure them this time?

Figure 7: *The absolute-value-squared of the wave function for the system shown in Fig. 6. The interference fringes lie on the opposite diagonal from those of Fig. 3.*

The average position ¹/₂(x₁+x₂) won’t do; we’ll see nothing interesting there. Instead the fringes are near (x₁-x₂)=4 — that is, they occur when the particles, no matter where they are in physical space, are at a distance of four units. We therefore expect interference near ¹/₂(x₁-x₂)=2. Is it there?

In Fig. 8 I’ve shown the analogue of Figs. 4 and 5, depicting

the measurements of the two particle positions x₁ and x₂, along with
their average ¹/₂(x₁+x₂) plotted between them (in yellow)
(half) their difference ¹/₂(x₁-x₂) plotted below them (in green).

That quantity ¹/₂(x₁-x₂) is half the horizontal length of the orange line. Hidden in its behavior over many measurements is an interference pattern, seen in the bottom row, where the ¹/₂(x₁-x₂) measurements are plotted. [Note also that there is no interference pattern in the measurements of ¹/₂(x₁+x₂), in contrast to Fig. 4.]

Figure 8: For the system of Figs. 6-7, repeated experiments in which the measurement of the position of particle 1 is plotted in the top row (upper blue points), that of particle 2 is plotted in the third row (lower blue points), their average is plotted between (yellow points), and half their difference is plotted below them (green points.) Each new set of measurements is shown as orange points connected by an orange line, as in Fig. 5. An interference pattern is seen only in the difference.

Now the question of the hour: where is the interference in this case? It is found near ¹/₂(x₁-x₂)=2 — but that certainly is not to be identified with a legitimate position in physical space, such as the point x=2.

First of all, making such an identification in Fig. 8 would be like saying that one particle is in New York and the other is in Boston, while the interference is 150 kilometers offshore in the ocean. But second and much worse, I could change Fig. 8 by moving both particles 10 units to the left and repeating the experiment. This would cause x₁, x₂, and ¹/₂(x₁+x₂) in Fig. 8 to all shift left by 10 units, moving them off your computer screen, while leaving ¹/₂(x₁-x₂) unchanged at 2. In short, all the orange and blue and yellow points would move out of your view, while the green points would remain exactly where they are. The difference of positions — a distance — is not a position.

If 10 units isn’t enough to convince you, let’s move the two particles to the other side of the Sun, or to the other side of the galaxy. The interference pattern stubbornly remains at ¹/₂(x₁-x₂)=2. The interference pattern is in a difference of positions, so it doesn’t care whether the two particles are in France, Antarctica, or Mars.

We can move the particles anywhere in the universe, as long as we take them together with their average distance remaining the same, and the interference pattern remains exactly the same. So there’s no way we can identify the interference as being located at a particular value of x, the coordinate of physical space. Trying to do so creates nonsense.

This is totally unlike interference in water waves and sound waves. That kind of interference happens in a someplace; we can say where the waves are, how big they are at a particular location, and where their peaks and valleys are in physical space. Quantum interference is not at all like this. It’s something more general, more subtle, and more troubling to our intuition.

[By the way, there’s nothing special about the two combinations ¹/₂(x₁+x₂) and ¹/₂(x₁-x₂), the average or the difference. It’s easy to find systems where the intereference arises in the combination x₁+2x₂, or 3x₁-x₂, or any other one you like. In none of these is there a natural way to say “where” the interference is located.]

The Profound Lesson

From these examples, we can begin to learn a central lesson of modern physics, one that a century of experimental and theoretical physics have been teaching us repeatedly, with ever greater subtlety. Imagining reality as many of us are inclined to do, as made of localized objects positioned in and moving through physical space — the one-dimensional x-axis in my simple examples, and the three-dimensional physical space that we take for granted when we specify our latitude, longitude and altitude — is simply not going to work in a quantum universe. The correlations among objects have observable consequences, and those correlations cannot simply be ascribed locations in physical space. To make sense of them, it seems we need to expand our conception of reality.

In the process of recognizing this challenge, we have had to confront the giant, unwieldy space of possibilities, which we can only visualize for a single particle moving in up to three dimensions, or for two or three particles moving in just one dimension. In realistic circumstances, especially those of quantum field theory, the space of possibilities has a huge number of dimensions, rendering it horrendously unimaginable. Whether this gargantuan space should be understood as real — perhaps even more real than physical space — continues to be debated.

Indeed, the lessons of quantum interference are ones that physicists and philosophers have been coping with for a hundred years, and their efforts to make sense of them continue to this day. I hope this series of posts has helped you understand these issues, and to appreciate their depth and difficulty.

Looking ahead, we’ll soon take these lessons, and other lessons from recent posts, back to the double-slit experiment. With fresher, better-informed eyes, we’ll examine its puzzles again.

by Matt Strassler at April 01, 2025 12:15 PM

March 31, 2025

John Preskill — How writing a popular-science book led to a Nature Physics paper

Several people have asked me whether writing a popular-science book has fed back into my research. Nature Physics published my favorite illustration of the answer this January. Here’s the story behind the paper.

In late 2020, I was sitting by a window in my home office (AKA living room) in Cambridge, Massachusetts. I’d drafted 15 chapters of my book Quantum Steampunk. The epilogue, I’d decided, would outline opportunities for the future of quantum thermodynamics. So I had to come up with opportunities for the future of quantum thermodynamics. The rest of the book had related foundational insights provided by quantum thermodynamics about the universe’s nature. For instance, quantum thermodynamics had sharpened the second law of thermodynamics, which helps explain time’s arrow, into more-precise statements. Conventional thermodynamics had not only provided foundational insights, but also accompanied the Industrial Revolution, a paragon of practicality. Could quantum thermodynamics, too, offer practical upshots?

Quantum thermodynamicists had designed quantum engines, refrigerators, batteries, and ratchets. Some of these devices could outperform their classical counterparts, according to certain metrics. Experimentalists had even realized some of these devices. But the devices weren’t useful. For instance, a simple quantum engine consisted of one atom. I expected such an atom to produce one electronvolt of energy per engine cycle. (A light bulb emits about 10²¹ electronvolts of light per second.) Cooling the atom down and manipulating it would cost loads more energy. The engine wouldn’t earn its keep.

Autonomous quantum machines offered greater hope for practicality. By autonomous, I mean, not requiring time-dependent external control: nobody need twiddle knobs or push buttons to guide the machine through its operation. Such control requires work—organized, coordinated energy. Rather than receiving work, an autonomous machine accesses a cold environment and a hot environment. Heat—random, disorganized energy cheaper than work—flows from the hot to the cold. The machine transforms some of that heat into work to power itself. That is, the machine sources its own work from cheap heat in its surroundings. Some air conditioners operate according to this principle. So can some quantum machines—autonomous quantum machines.

Thermodynamicists had designed autonomous quantum engines and refrigerators. Trapped-ion experimentalists had realized one of the refrigerators, in a groundbreaking result. Still, the autonomous quantum refrigerator wasn’t practical. Keeping the ion cold and maintaining its quantum behavior required substantial work.

My community needed, I wrote in my epilogue, an analogue of solar panels in southern California. (I probably drafted the epilogue during a Boston winter, thinking wistfully of Pasadena.) If you built a solar panel in SoCal, you could sit back and reap the benefits all year. The panel would fulfill its mission without further effort from you. If you built a solar panel in Rochester, you’d have to scrape snow off of it. Also, the panel would provide energy only a few months per year. The cost might not outweigh the benefit. Quantum thermal machines resembled solar panels in Rochester, I wrote. We needed an analogue of SoCal: an appropriate environment. Most of it would be cold (unlike SoCal), so that maintaining a machine’s quantum nature would cost a user almost no extra energy. The setting should also contain a slightly warmer environment, so that net heat would flow. If you deposited an autonomous quantum machine in such a quantum SoCal, the machine would operate on its own.

Where could we find a quantum SoCal? I had no idea.

Sunny SoCal. (Specifically, the Huntington Gardens.)

A few months later, I received an email from quantum experimentalist Simone Gasparinetti. He was setting up a lab at Chalmers University in Sweden. What, he asked, did I see as opportunities for experimental quantum thermodynamics? We’d never met, but we agreed to Zoom. Quantum Steampunk on my mind, I described my desire for practicality. I described autonomous quantum machines. I described my yearning for a quantum SoCal.

I have it, Simone said.

Simone and his colleagues were building a quantum computer using superconducting qubits. The qubits fit on a chip about the size of my hand. To keep the chip cold, the experimentalists put it in a dilution refrigerator. You’ve probably seen photos of dilution refrigerators from Google, IBM, and the like. The fridges tend to be cylindrical, gold-colored monstrosities from which wires stick out. (That is, they look steampunk.) You can easily develop the impression that the cylinder is a quantum computer, but it’s only the fridge.

The fridge, Simone said, resembles an onion: it has multiple layers. Outer layers are warmer, and inner layers are colder. The quantum computer sits in the innermost layer, so that it behaves as quantum mechanically as possible. But sometimes, even the fridge doesn’t keep the computer cold enough.

Imagine that you’ve finished one quantum computation and you’re preparing for the next. The computer has written quantum information to certain qubits, as you’ve probably written on scrap paper while calculating something in a math class. To prepare for your next math assignment, given limited scrap paper, you’d erase your scrap paper. The quantum computer’s qubits need erasing similarly. Erasing, in this context, means cooling down even more than the dilution refrigerator can manage.

Why not use an autonomous quantum refrigerator to cool the scrap-paper qubits?

I loved the idea, for three reasons. First, we could place the quantum refrigerator beside the quantum computer. The dilution refrigerator would already be cold, for the quantum computations’ sake. Therefore, we wouldn’t have to spend (almost any) extra work on keeping the quantum refrigerator cold. Second, Simone could connect the quantum refrigerator to an outer onion layer via a cable. Heat would flow from the warmer outer layer to the colder inner layer. From the heat, the quantum refrigerator could extract work. The quantum refrigerator would use that work to cool computational qubits—to erase quantum scrap paper. The quantum refrigerator would service the quantum computer. So, third, the quantum refrigerator would qualify as practical.

Over the next three years, we brought that vision to life. (By we, I mostly mean Simone’s group, as my group doesn’t have a lab.)

Postdoc Aamir Ali spearheaded the experiment. Then-master’s student Paul Jamet Suria and PhD student Claudia Castillo-Moreno assisted him. Maryland postdoc Jeffrey M. Epstein began simulating the superconducting qubits numerically, then passed the baton to PhD student José Antonio Marín Guzmán.

The experiment provided a proof of principle: it demonstrated that the quantum refrigerator could operate. The experimentalists didn’t apply the quantum refrigerator in a quantum computation. Also, they didn’t connect the quantum refrigerator to an outer onion layer. Instead, they pumped warm photons to the quantum refrigerator via a cable. But even in such a stripped-down experiment, the quantum refrigerator outperformed my expectations. I thought it would barely lower the “scrap-paper” qubit’s temperature. But that qubit reached a temperature of 22 milliKelvin (mK). For comparison: if the qubit had merely sat in the dilution refrigerator, it would have reached a temperature of 45–70 mK. State-of-the-art protocols had lowered scrap-paper qubits’ temperatures to 40–49 mK. So our quantum refrigerator outperformed our competitors, through the lens of temperature. (Our quantum refrigerator cooled more slowly than they did, though.)

Simone, José Antonio, and I have followed up on our autonomous quantum refrigerator with a forward-looking review about useful autonomous quantum machines. Keep an eye out for a blog post about the review…and for what we hope grows into a subfield.

In summary, yes, publishing a popular-science book can benefit one’s research.

by Nicole Yunger Halpern at March 31, 2025 12:02 AM

March 28, 2025

Matt Strassler Quantum Interference 4: Independence and Correlation

The quantum double-slit experiment, in which objects are sent toward and through a pair of slits in a wall,and are recorded on a screen behind the slits, clearly shows an interference pattern. It’s natural to ask, “where does the interference occur?”

The problem is that there is a hidden assumption in this way of framing the question — a very natural assumption, based on our experience with waves in water or in sound. In those cases, we can explicitly see (Fig. 1) how interference builds up between the slits and the screen.

Figure 1: *How water waves or sound waves interfere after passing through two slits.*

But when we dig deep into quantum physics, this way of thinking runs into trouble. Asking “where” is not as straightforward as it seems. In the next post we’ll see why. Today we’ll lay the groundwork.

Independence and Interference

From my long list of examples with and without interference (we saw last time what distinguishes the two classes), let’s pick a superposition whose pre-quantum version is shown in Fig. 2.

Figure 2: A pre-quantum view of a superposition in which particle 1 is moving left OR right, and particle 2 is stationary at **x=3.**

Here we have

particle 1 going from left to right, with particle 2 stationary at x=+3, OR
particle 1 going from right to left, with particle 2 again stationary at x=+3.

In Fig. 3 is what the wave function Ψ(x₁,x₂) [where x₁ is the position of particle 1 and x₂ is the position of particle 2] looks like when its absolute-value squared is graphed on the space of possibilities. Both peaks have x₂=+3, representing the fact that particle 2 is stationary. They move in opposite directions and pass through each other horizontally as particle 1 moves to the right OR to the left.

Figure 3: *The graph of the absolute-value-squared of the wave function for the quantum version of the system in Fig. 2.*

This looks remarkably similar to what we would have if particle 2 weren’t there at all! The interference fringes run parallel to the x₂ axis, meaning the locations of the interference peaks and valleys depend on x₁ but not on x₂. In fact, if we measure particle 1, ignoring particle 2, we’ll see the same interference pattern that we see when a single particle is in the superposition of Fig. 1 with particle 2 removed (Fig. 4):

Figure 4a: *The square of the absolute value of the wave function for a particle in a superposition of the form shown in Fig. 2 but with the second particle removed.*

Figure 4b: A closeup of the interference pattern that occurs at the moment when the two peaks in Fig. 4a perfectly overlap. The real and imaginary parts of the wave function are shown in red and blue, while its square is drawn in black.

We can confirm this in a simple way. If we measure the position of particle 1, ignoring particle 2, the probability of finding that particle at a specific position x₁ is given by projecting the wave function, shown above as a function of x₁ and x₂, onto the x₁ axis. [More mathematically, this is done by integrating over x₂ to leave a function of x₁ only.] Sometimes (not always!) this is essentially equivalent to viewing the graph of the wave function from one side, as in Figs. 5-6.

Figure 5: *Projecting the wave function of Fig. 3, at the moment of maximum interference, onto the x₁ axis. Compare with the black curve in Fig. 4b.*

Because the interference ridges in Fig. 3 are parallel to the x₂ axis and thus independent of particle 2’s exact position, we do indeed find, when we project onto the x₁ axis as in Fig. 5, that the familiar interference pattern of Fig. 4b reappears.

Meanwhile, if at that same moment we measure particle 2’s position, we will find results centered around x₂=+3, with no interference, as seen in Fig. 6 where we project the wave function of Fig. 3 onto the x₂ axis.

Figure 6: *Projecting the wave function of Fig. 3, at the moment of maximum interference, onto the x₂ axis. The position of particle 2 is thus close to **x₂=3**, with no interference pattern.*

Why is this case so simple, with the one-particle case in Fig. 4 and the two-particle case in Figs. 3 and 5 so closely resembling each other?

The Cause

It has nothing specifically to do with the fact that particle 2 is stationary. Another example I gave had particle 2 stationary in both parts of the superposition, but located in two different places. In Figs. 7a and 7b, the pre-quantum version of that system is shown both in physical space and in the space of possibilities [where I have, for the first time, put stars for the two possibilities onto the same graph.]

Figure 7a: *A similar system to that of Fig. 2, drawn in its pre-quantum version in physical space.*

Figure 7b: *Same as Fig. 7a, but drawn in the space of possibilities.*

You can see that the two stars’ paths will not intersect, since one remains at x₂=+3 and the other remains at x₂=-3. Thus there should be no interference — and indeed, none is seen in Fig. 8, where the time evolution of the full quantum wave function is shown. The two peaks miss each other, and so no interference occurs.

Figure 8: *The absolute-value-squared of the wave function corresponding to Figs. 7a-7b.*

If we project the wave function of Fig. 8 onto the x₁ axis at the moment when the two peaks are at x₁=0, we see (Fig. 9) a single peak (because the two peaks, with different values of x₂, are projected onto each other). No interference fringes are seen.

Figure 9: *At the moment when the first particle is near **x₁=0**, the probability of finding particle 1 as a function of x₁ shows a featureless peak, with no interference effects.*

Instead the resemblance between Figs. 3-5 has to do with the fact that particle 2 is doing exactly the same thing in each part of the superposition. For instance, as in Fig. 10, suppose particle 2 is moving to the left in both possibilities.

Figure 10: *A system similar to that of Fig. 2, but with particle 2 (orange) moving to the left in both parts of the superposition.*

(In the top possibility, particles 1 and 2 will encounter one another; but we have been assuming for simplicity that they don’t interact, so they can safely pass right through each other.)

The resulting wave function is shown in Fig. 11:

Figure 11: *The absolute-value-squared of the wave function corresponding to Fig.10.*

The two peaks cross paths when x₁=0 and x₂=2. The wave function again shows interference at that location, with fringes that are independent of x₂. If we project the wave function onto the x₁=0 axis, we’ll get exactly the same thing we saw in Fig. 5, even though the behavior of the wave function in x₂ is different.

This makes the pattern clear: if, in each part of the superposition, particle 2 behaves identically, then particle 1 will be subject to the same pattern of interference as if particle 2 were absent. Said another way, if the behavior of particle 1 is independent of particle 2 (and vice versa), then any interference effects involving one particle will be as though the other particle wasn’t even there.

Said yet another way, the two particles in Figs. 2 and 10 are uncorrelated, meaning that we can understand what either particle is doing without having to know what the other is doing.

Importantly, the examples studied in the previous post did not have this feature. That’s crucial in understanding why the interference seen at the end of that post wasn’t so simple.

Independence and Factoring

What we are seeing in Figs. 2 and 10 has an analogy in algebra. If we have an algebraic expression such as

(a c + b c),

in which c is common to both terms, then we can factor it into

(a+b)c.

The same is true of the kinds of physical processes we’ve been looking at. In Fig. 10 the two particles’ behavior is uncorrelated, so we can “factor” the pre-quantum system as follows.

Figure 12: *The “factored” form of the superposition in Fig. 10.*

What we see here is that factoring involves an AND, while superposition is an OR: the figure above says that (particle 1 is moving from left to right OR from right to left) AND (particle 2 is moving from right to left, no matter what particle 1 is doing.)

And in the quantum context, if (and only if) two particles’ behaviors are completely uncorrelated, we can literally factor the wave function into a product of two functions, one for each particle:

Ψ(x₁,x₂)=Ψ₁(x₁)Ψ₂(x₂)

In this specific case of Fig. 12, where the first particle is in a superposition whose parts I’ve labeled A and B, we can write Ψ₁(x₁) as a sum of two terms:

Ψ₁(x₁)=Ψ_A(x₁) + Ψ_B(x₁)

Specifically, Ψ_A(x₁) describes particle 1 moving left to right — giving one peak in Fig. 11 — and Ψ_B(x₁) describes particle 2 moving right to left, giving the other peak.

But this kind of factoring is rare, and not possible in general. None of the examples in the previous post (or of this post, excepting that of its Fig. 5) can be factored. That’s because in these examples, the particles are correlated: the behavior of one depends on the behavior of the other.

Superposition AND Superposition

If the particles are truly uncorrelated, we should be able to put both particles into superpositions of two possibilities. As a pre-quantum system, that would give us (particle 1 in state A OR state B) AND (particle 2 in state C OR state D) in Fig. 13.

Figure 13: *The two particles are uncorrelated, and so their behavior can be factored. The first particle is in a superposition of states A and B, the second in a superposition of states C and D.*

The corresponding factored wave function, in which (particle 1 moves left to right OR right to left) AND (particle 2 moves left to right OR right to left), can be written as a product of two superpositions:

Ψ(x₁,x₂)=Ψ₁(x₁)Ψ₂(x₂) = [Ψ_A(x₁)+Ψ_B(x₁)] [Ψ_C(x₂)+Ψ_D(x₂)]

In algebra, we can expand a similar product

(a+b)(c+d)=ac+ad+bc+bd

giving us four terms. In the same way we can expand the above wave function into four terms

Ψ(x₁,x₂)=Ψ_A(x₁)Ψ_C(x₂)+Ψ_B(x₁)Ψ_C(x₂)+Ψ_A(x₁)Ψ_D(x₂)+Ψ_B(x₁)Ψ_D(x₂)

whose pre-quantum version gives us the four possibilities shown in Fig. 14.

Figure 14: *The product in Fig. 13 is expanded into its four distinct possibilities.*

The wave function therefore has four peaks, one for each term. The wave function behaves as shown in Fig. 15.

Figure 15: *The wave function for the system in Fig. 14 shows interference of two pairs of possibilities, first for particle 1 and later for particle 2.*

The four peaks interfere in pairs. The top two and the bottom two interfere when particle 1 reaches x₁=0, creating fringes that run parallel to the x₂ axis and thus are independent of x₂. Notice that even though there are two sets of interference fringes when particle 1 reaches x₁=0 in all the superpositions, we do not observe this if we only measure particle 1. When we project the wave function onto the x₁ axis, the two sets of interference fringes line up, and we see the same single-particle interference pattern that we’ve seen so many times (Figs. 3-5). That’s all because particles 1 and 2 are uncorrelated.

Figure 16: The first instance of interference, seen in two peaks in Fig. 15 is reduced, when projected on to the x₁ axis, to the same interference pattern as seen in Figs. 3-5; the measurement of particle 1’s position will show the same interference pattern in each case, because particles 1 and 2 are uncorrelated.

If at the same moment we measure particle 2 ignoring particle 1, we find (Fig. 17) that particle 2 has equal probability of being near x=2.5 or x=-0.5, with no interference effects.

Figure 17: The first instance of interference, seen in two peaks in Fig. 15, shows two peaks with no interference when projected on to the x₂ axis. Thus measurements of particle 2’s position show no interference at this moment.

Meanwhile, the left two and the right two peaks in Fig. 15 subsequently interfere when particle 2 reaches x₂=1, creating fringes that run parallel to the x₁ axis, and thus are independent of x₁; these will show up near x=1 in measurements of particle 2’s position. This is shown (Fig. 18) by projecting the wave function at that moment onto the x₂ axis.

Figure 18: *During the second instance of interference in Fig. 15, the projection of the wave function onto the x₂ axis.*

Locating the Interference?

So far, in all these examples, it seems that we can say where the interference occurs in physical space. For instance, in this last example, it appears that particle 1 shows interference around x=0, and slightly later particle 2 shows interference around x=1.

But if we look back at the end of the last post, we can see that something is off. In the examples considered there, the particles are correlated and the wave function cannot be factored. And in the last example in Fig. 12 of that post, we saw interference patterns whose ridges are parallel neither to the x₁ axis nor to the x₂ axis. . .an effect that a factored wave function cannot produce. [Fun exercise: prove this last statement.]

As a result, projecting the wave function of that example onto the x₁ axis hides the interference pattern, as shown in Fig. 19. The same is true when projecting onto the x₂ axis.

Figure 19: Alhough Fig. 12 of the previous post shows an interference pattern, it is hidden when the wave function is projected onto the x₁ axis, leaving only a boring bump. The observable consequences are shown in Fig. 13 of that same post.

Consequently, neither measurements of particle 1’s position nor measurements of particle 2’s position can reveal the interference effect. (This is shown, for particle 1, in the previous post’s Fig. 13.) This leaves it unclear where the interference is, or even how to measure it.

But in fact it can be measured, and next time we’ll see how. We’ll also see that in a general superposition, where the two particles are correlated, interference effects often cannot be said to have a location in physical space. And that will lead us to a first glimpse of one of the most shocking lessons of quantum physics.

One More Uncorrelated Example, Just for Fun

To close, I’ll leave you with one more uncorrelated example, merely because it looks cool. In pre-quantum language, the setup is shown in Fig. 20.

Figure 20: *Another uncorrelated superposition with four possibilities.*

Now all four peaks interfere simultaneously, near (x₁,x₂)=(1,-1).

Figure 21: *The four peaks simultaneously interfere, generating a grid pattern.*

The grid pattern in the interference assures that the usual interference effects can be seen for both particles at the same time, with the interference for particle 1 near x₁=1 and that for particle 2 near x₂=-1. Here are the projections onto the two axes at the moment of maximal interference.

Figure 22a: *At the moment of maximum interference, the projection of the wave function onto the x₁ axis shows interference near **x₁=1**.*

Figure 22b: *At the moment of maximum interference, the projection of the wave function onto the x₂ axis shows interference near **x₂=-1**.*

by Matt Strassler at March 28, 2025 04:17 PM

March 27, 2025

n-Category Café The McGee Group

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This is a bit of a shaggy dog story, but I think it’s fun. There’s also a moral about the nature of mathematical research.

Once I was interested in the McGee graph, nicely animated here by Mamouka Jibladze:

This is the unique (3,7)-cage, meaning a graph such that each vertex has 3 neighbors and the shortest cycle has length 7. Since it has a very symmetrical appearance, I hoped it would be connected to some interesting algebraic structures. But which?

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I read on Wikipedia that the symmetry group of the McGee graph has order 32. Let’s call it the McGee group. Unfortunately there are many different 32-element groups — 51 of them, in fact! — and the article didn’t say which one this was. (It does now.)

I posted a general question:

MathOverflow, What algebraic structures are related to the McGee graph?

and Gordon Royle said the McGee group is “not a super-interesting group, it is SmallGroup(32,43) in either GAP or Magma”. Knowing this let me look up the McGee group on this website, which is wonderfully useful if you’re studying finite groups:

GroupProps, Holomorph of $\mathbb{Z}/8$ .

There I learned that the McGee group is the so-called holomorph of the cyclic group $\mathbb{Z}/8$ : that is, the semidirect product of $\mathbb{Z}/8$ and its automorphism group:

$Aut(\mathbb{Z}/8) \ltimes \mathbb{Z}/8$

I resisted getting sucked into the general study of holomorphs, or what happens when you iterate the holomorph construction. Instead, I wanted a more concrete description of the McGee group.

$\mathbb{Z}/8$ is not just an abelian group: it’s a ring! Since multiplication in a ring distributes over addition, we can get automorphisms of the group $\mathbb{Z}/8$ by multiplying by those elements that have multiplicative inverses. These invertible elements form a group

$(\mathbb{Z}/8)^\times = \{1,3,5,7\}$

called the multiplicative group of $\mathbb{Z}/8$ . In fact these give all the automorphisms of the group $\mathbb{Z}/8$ .

In short, the McGee group is

$(\mathbb{Z}/8)^\times \ltimes \mathbb{Z}/8$

This is very nice, because this is the group of all transformations of $\mathbb{Z}/8$ of the form

$x \mapsto g x + a \qquad g \in (\mathbb{Z}/8)^\times , \; a \in \mathbb{Z}/8$

If we think of $\mathbb{Z}/8$ as a kind of line — called the ‘affine line over $\mathbb{Z}/8$ ’ — these are precisely all the affine transformations of this line. Thus, the McGee group deserves to be called

$\text{Aff}(\mathbb{Z}/8) = (\mathbb{Z}/8)^\times \ltimes \mathbb{Z}/8$

This suggests that we can build the McGee graph in some systematic way starting from the affine line over $\mathbb{Z}/8$ . This turns out to be a bit complicated, because the vertices come in two kinds. That is, the McGee group doesn’t act transitively on the set of vertices. Instead, it has two orbits, shown as red and blue dots here:

The 8 red vertices correspond straightforwardly to the 8 points of the affine line, but the 16 blue vertices are more tricky. There are also the edges to consider: these come in three kinds! Greg Egan figured out how this works, and I wrote it up:

The McGee graph, Visual Insight, September 15, 2015.

Then a decade passed.

About two weeks ago, I gave a Zoom talk at the Illustrating Math Seminar about some topics on my blog Visual Insight. I mentioned that the McGee group is SmallGroup(32,43) and the holomorph of $\mathbb{Z}/8$ . And then someone — alas, I forget who — instantly typed in the chat that this is one of the two smallest groups with an amazing property! Namely, this group has an outer automorphism that maps each element to an element conjugate to it.

I didn’t doubt this for a second. To paraphrase what Hardy said when he received Ramanujan’s first letter, nobody would have the balls to make up this shit. So, I posed a challenge to find such an exotic outer automorphism:

The McGee group, Mathstodon.

By reading around, I soon learned that people have studied this subject quite generally:

Martin Hertweck, Class-preserving automorphisms of finite groups, Journal of Algebra 241 (2001), 1–26.
Manoj K. Yadav, Class preserving automorphisms of finite p-groups: a survey, Journal of the London Mathematical Society 75 (2007), 755–772.

An automorphism $f \colon G \to G$ is class-preserving if for each $g \in G$ there exists some $h \in G$ such that

$f(g) = h g h^{-1}$

If you can use the same $h$ for every $g$ we call $f$ an inner automorphism. But some groups have class-preserving automorphisms that are not inner! These are the class-preserving outer automorphisms.

I don’t know if class-preserving outer automorphisms are good for anything, or important in any way. They mainly just seem intriguingly spooky. An outer automorphism that looks inner if you examine its effect on any one group element is nothing I’d ever considered. So I wanted to see an example.

Rising to my challenge, Greg Egan found a nice explicit formula for some class-preserving outer automorphisms of the McGee group.

As we’ve seen, any element of the McGee group is a transformation

$x \mapsto g x + a \qquad g \in (\mathbb{Z}/8)^\times , \; a \in \mathbb{Z}/8$

so let’s write it as a pair $(g,a)$ . Greg Egan looked for automorphisms of the McGee group that are of the form

$f(g,a) = (g, a + D(g))$

for some function

$D \colon (\mathbb{Z}/8)^\times \to \mathbb{Z}/8$

It is easy to check that $f$ is an automorphism if and only if

$D(g g') = D(g) + g D(g')$

Moreover, $f$ is an inner automorphism if and only if

$D(g) = g b - b$

for some $b \in \mathbb{Z}/8$ .

Now comes something cool noticed by Joshua Grochow: these formulas are an instance of a general fact about group cohomology!

Suppose we have a group $G$ acting as automorphisms of an abelian group $A$ . Then we can define the cohomology $H^n(G,A)$ to be the group of $n$ -cocycles modulo $n$ -coboundaries. We only need the case $n = 1$ here. A 1-cocycle is none other than a function $D \colon G \to A$ obeying

$D(g g') = D(g) + g D(g')$

while a 1-coboundary is one of the form

$D(g) = g b - b$

for some $b \in A$ . You can check that every 1-coboundary is a 1-cocycle. $H^1(G,A)$ is the group of 1-cocycles modulo 1-coboundaries.

In this situation we can define the semidirect product $G \ltimes A$ , and for any $D \colon G \to A$ we can define a function

$f \colon G \ltimes A \to G \ltimes A$

$f(g,a) = (g, a + D(g))$

Now suppose $G = \text{Aut}(A)$ and suppose $G$ is abelian. Then by straightforward calculations we can check:

$f$ is an automorphism iff $D$ is a 1-cocycle

and

$f$ is an inner automorphism iff $D$ is a 1-coboundary!

Thus, $G \ltimes A$ will have outer automorphisms if $H^1(G,A) \ne 0$ .

When $A = \mathbb{Z}/8$ then $G = \text{Aut}(A)$ is abelian and $G \ltimes A$ is the McGee group. This puts Egan’s idea into a nice context. But we still need to actually find maps $D$ that give outer automorphisms of the McGee group, and then find class-preserving ones. I don’t know how to do that using general ideas from cohomology. Maybe someone smart could do the first part, but the ‘class-preserving’ condition doesn’t seem to emerge naturally from cohomology.

Anyway, Egan didn’t waste his time with such effete generalities: he actually found all choices of $D \colon (\mathbb{Z}/8)^\times \to \mathbb{Z}/8$ for which

$f(g,a) = (g, a + D(g))$

is a class-preserving outer automorphism of the McGee group. Namely:

$\begin{array}{ccl} (D(1), D(3), D(5), D(7)) &=& (0, 0, 4, 4) \\ (D(1), D(3), D(5), D(7)) &=& (0, 2, 0, 2) \\ (D(1), D(3), D(5), D(7)) &=& (0, 4, 4, 0) \\ (D(1), D(3), D(5), D(7)) &=& (0, 6, 0, 6) \end{array}$

Last Saturday after visiting my aunt in Santa Barbara I went to Berkeley to visit the applied category theorists at the Topos Institute. I took a train, to lessen my carbon footprint a bit. The trip took 9 hours — a long time, but a beautiful ride along the coast and then through forests and fields.

The day before taking the train, I discovered my laptop was no longer charging! So, I bought a pad of paper. And then, while riding the train, I checked by hand that Egan’s first choice of $D$ really is a cocycle, and really is not a coboundary, so that it defines an outer automorphism of the McGee group. Then — and this was fairly easy — I checked that it defines a class-preserving automorphism. It was quite enjoyable, since I hadn’t done any long calculations recently.

One moral here is that interesting ideas often arise from the interactions of many people. The results here are not profound, but they are certainly interesting, and they came from online conversations with Greg Egan, Gordon Royle, Joshua Grochow, the mysterious person who instantly knew that the McGee group was one of the two smallest groups with a class-preserving outer automorphism, and others.

But what does it all mean, mathematically? Is there something deeper going on here, or is it all just a pile of curiosities?

What did we actually do, in the end? Following the order of logic rather than history, maybe this. We started with a commutative ring $A$ , took its group of affine transformations $\text{Aff}(A)$ , and saw this group must have outer automorphisms if

$H^1(A^\times, A) \ne 0$

We saw this cohomology group really is nonvanishing when $A = \mathbb{Z}/n$ and $n = 8$ . Furthermore, we found a class-preserving outer automorphism of $\text{Aff}(\mathbb{Z}/8)$ .

This raises a few questions:

What is the cohomology $H^1((\mathbb{Z}/n)^\times, \mathbb{Z}/n)$ in general?
What are the outer automorphisms of $\text{Aff}(\mathbb{Z}/n)$ ?
When does $\text{Aff}(\mathbb{Z}/n)$ have class-preserving outer automorphisms?

I saw bit about the last question in this paper:

Peter A. Brooksbank and Matthew S. Mizuhara, On groups with a class-preserving outer automorphism, Involve, a Journal of Mathematics 7 (2013),171–179.

They say that this paper:

G. E. Wall, Finite groups with class-preserving outer automorphisms, Journal of the London Mathematical Society 22 (1947), 315–320.

proves $\text{Aff}(\mathbb{Z}/n)$ has a class-preserving outer automorphism when $n$ is a multiple of 8.

Does this happen only for multiples of 8? Is this somehow related to the most famous thing with period 8 — namely, Bott periodicity? I don’t know.

March 20, 2025

John Preskill — The first and second centuries of quantum mechanics

At this week’s American Physical Society Global Physics Summit in Anaheim, California, John Preskill spoke at an event celebrating 100 years of groundbreaking advances in quantum mechanics. Here are his remarks.

Welcome, everyone, to this celebration of 100 years of quantum mechanics hosted by the Physical Review Journals. I’m John Preskill and I’m honored by this opportunity to speak today. I was asked by our hosts to express some thoughts appropriate to this occasion and to feel free to share my own personal journey as a physicist. I’ll embrace that charge, including the second part of it, perhaps even more that they intended. But over the next 20 minutes I hope to distill from my own experience some lessons of broader interest.

I began graduate study in 1975, the midpoint of the first 100 years of quantum mechanics, 50 years ago and 50 years after the discovery of quantum mechanics in 1925 that we celebrate here. So I’ll seize this chance to look back at where quantum physics stood 50 years ago, how far we’ve come since then, and what we can anticipate in the years ahead.

As an undergraduate at Princeton, I had many memorable teachers; I’ll mention just one: John Wheeler, who taught a full-year course for sophomores that purported to cover all of physics. Wheeler, having worked with Niels Bohr on nuclear fission, seemed implausibly old, though he was actually 61. It was an idiosyncratic course, particularly because Wheeler did not refrain from sharing with the class his current research obsessions. Black holes were a topic he shared with particular relish, including the controversy at the time concerning whether evidence for black holes had been seen by astronomers. Especially notably, when covering the second law of thermodynamics, he challenged us to ponder what would happen to entropy lost behind a black hole horizon, something that had been addressed by Wheeler’s graduate student Jacob Bekenstein, who had finished his PhD that very year. Bekenstein’s remarkable conclusion that black holes have an intrinsic entropy proportional to the event horizon area delighted the class, and I’ve had had many occasions to revisit that insight in the years since then. The lesson being that we should not underestimate the potential impact of sharing our research ideas with undergraduate students.

Stephen Hawking made that connection between entropy and area precise the very next year when he discovered that black holes radiate; his resulting formula for black hole entropy, a beautiful synthesis of relativity, quantum theory, and thermodynamics ranks as one of the shining achievements in the first 100 years of quantum mechanics. And it raised a deep puzzle pointed out by Hawking himself with which we have wrestled since then, still without complete success — what happens to information that disappears inside black holes?

Hawking’s puzzle ignited a titanic struggle between cherished principles. Quantum mechanics tells us that as quantum systems evolve, information encoded in a system can get scrambled into an unrecognizable form, but cannot be irreversibly destroyed. Relativistic causality tells us that information that falls into a black hole, which then evaporates, cannot possibly escape and therefore must be destroyed. Who wins – quantum theory or causality? A widely held view is that quantum mechanics is the victor, that causality should be discarded as a fundamental principle. This calls into question the whole notion of spacetime — is it fundamental, or an approximate property that emerges from a deeper description of how nature works? If emergent, how does it emerge and from what? Fully addressing that challenge we leave to the physicists of the next quantum century.

I made it to graduate school at Harvard and the second half century of quantum mechanics ensued. My generation came along just a little too late to take part in erecting the standard model of particle physics, but I was drawn to particle physics by that intoxicating experimental and theoretical success. And many new ideas were swirling around in the mid and late 70s of which I’ll mention only two. For one, appreciation was growing for the remarkable power of topology in quantum field theory and condensed matter, for example the theory of topological solitons. While theoretical physics and mathematics had diverged during the first 50 years of quantum mechanics, they have frequently crossed paths in the last 50 years, and topology continues to bring both insight and joy to physicists. The other compelling idea was to seek insight into fundamental physics at very short distances by searching for relics from the very early history of the universe. My first publication resulted from contemplating a question that connected topology and cosmology: Would magnetic monopoles be copiously produced in the early universe? To check whether my ideas held water, I consulted not a particle physicist or a cosmologist, but rather a condensed matter physicist (Bert Halperin) who provided helpful advice. The lesson being that scientific opportunities often emerge where different subfields intersect, a realization that has helped to guide my own research over the following decades.

Looking back at my 50 years as a working physicist, what discoveries can the quantumists point to with particular pride and delight?

I was an undergraduate when Phil Anderson proclaimed that More is Different, but as an arrogant would be particle theorist at the time I did not appreciate how different more can be. In the past 50 years of quantum mechanics no example of emergence was more stunning than the fractional quantum Hall effect. We all know full well that electrons are indivisible particles. So how can it be that in a strongly interacting two-dimensional gas an electron can split into quasiparticles each carrying a fraction of its charge? The lesson being: in a strongly-correlated quantum world, miracles can happen. What other extraordinary quantum phases of matter await discovery in the next quantum century?

Another thing I did not adequately appreciate in my student days was atomic physics. Imagine how shocked those who elucidated atomic structure in the 1920s would be by the atomic physics of today. To them, a quantum measurement was an action performed on a large ensemble of similarly prepared systems. Now we routinely grab ahold of a single atom, move it, excite it, read it out, and induce pairs of atoms to interact in precisely controlled ways. When interest in quantum computing took off in the mid-90s, it was ion-trap clock technology that enabled the first quantum processors. Strong coupling between single photons and single atoms in optical and microwave cavities led to circuit quantum electrodynamics, the basis for today’s superconducting quantum computers. The lesson being that advancing our tools often leads to new capabilities we hadn’t anticipated. Now clocks are so accurate that we can detect the gravitational redshift when an atom moves up or down by a millimeter in the earth’s gravitational field. Where will the clocks of the second quantum century take us?

Surely one of the great scientific triumphs of recent decades has been the success of LIGO, the laser interferometer gravitational-wave observatory. If you are a gravitational wave scientist now, your phone buzzes so often to announce another black hole merger that it’s become annoying. LIGO would not be possible without advanced laser technology, but aside from that what’s quantum about LIGO? When I came to Caltech in the early 1980s, I learned about a remarkable idea (from Carl Caves) that the sensitivity of an interferometer can be enhanced by a quantum strategy that did not seem at all obvious — injecting squeezed vacuum into the interferometer’s dark port. Now, over 40 years later, LIGO improves its detection rate by using that strategy. The lesson being that theoretical insights can enhance and transform our scientific and technological tools. But sometimes that takes a while.

What else has changed since 50 years ago? Let’s give thanks for the arXiv. When I was a student few scientists would type their own technical papers. It took skill, training, and patience to operate the IBM typewriters of the era. And to communicate our results, we had no email or world wide web. Preprints arrived by snail mail in Manila envelopes, if you were lucky enough to be on the mailing list. The Internet and the arXiv made scientific communication far faster, more convenient, and more democratic, and LaTeX made producing our papers far easier as well. And the success of the arXiv raises vexing questions about the role of journal publication as the next quantum century unfolds.

I made a mid-career shift in research direction, and I’m often asked how that came about. Part of the answer is that, for my generation of particle physicists, the great challenge and opportunity was to clarify the physics beyond the standard model, which we expected to provide a deeper understanding of how nature works. We had great hopes for the new phenomenology that would be unveiled by the Superconducting Super Collider, which was under construction in Texas during the early 90s. The cancellation of that project in 1993 was a great disappointment. The lesson being that sometimes our scientific ambitions are thwarted because the required resources are beyond what society will support. In which case, we need to seek other ways to move forward.

And then the next year, Peter Shor discovered the algorithm for efficiently finding the factors of a large composite integer using a quantum computer. Though computational complexity had not been part of my scientific education, I was awestruck by this discovery. It meant that the difference between hard and easy problems — those we can never hope to solve, and those we can solve with advanced technologies — hinges on our world being quantum mechanical. That excited me because one could anticipate that observing nature through a computational lens would deepen our understanding of fundamental science. I needed to work hard to come up to speed in a field that was new to me — teaching a course helped me a lot.

Ironically, for 4 ½ years in the mid-1980s I sat on the same corridor as Richard Feynman, who had proposed the idea of simulating nature with quantum computers in 1981. And I never talked to Feynman about quantum computing because I had little interest in that topic at the time. But Feynman and I did talk about computation, and in particular we were both very interested in what one could learn about quantum chromodynamics from Euclidean Monte Carlo simulations on conventional computers, which were starting to ramp up in that era. Feynman correctly predicted that it would be a few decades before sufficient computational power would be available to make accurate quantitative predictions about nonperturbative QCD. But it did eventually happen — now lattice QCD is making crucial contributions to the particle physics and nuclear physics programs. The lesson being that as we contemplate quantum computers advancing our understanding of fundamental science, we should keep in mind a time scale of decades.

Where might the next quantum century take us? What will the quantum computers of the future look like, or the classical computers for that matter? Surely the qubits of 100 years from now will be much different and much better than what we have today, and the machine architecture will no doubt be radically different than what we can currently envision. And how will we be using those quantum computers? Will our quantum technology have transformed medicine and neuroscience and our understanding of living matter? Will we be building materials with astonishing properties by assembling matter atom by atom? Will our clocks be accurate enough to detect the stochastic gravitational wave background and so have reached the limit of accuracy beyond which no stable time standard can even be defined? Will quantum networks of telescopes be observing the universe with exquisite precision and what will that reveal? Will we be exploring the high energy frontier with advanced accelerators like muon colliders and what will they teach us? Will we have identified the dark matter and explained the dark energy? Will we have unambiguous evidence of the universe’s inflationary origin? Will we have computed the parameters of the standard model from first principles, or will we have convinced ourselves that’s a hopeless task? Will we have understood the fundamental constituents from which spacetime itself is composed?

There is an elephant in the room. Artificial intelligence is transforming how we do science at a blistering pace. What role will humans play in the advancement of science 100 years from now? Will artificial intelligence have melded with quantum intelligence? Will our instruments gather quantum data Nature provides, transduce it to quantum memories, and process it with quantum computers to discern features of the world that would otherwise have remained deeply hidden?

To a limited degree, in contemplating the future we are guided by the past. Were I asked to list the great ideas about physics to surface over the 50-year span of my career, there are three in particular I would nominate for inclusion on that list. (1) The holographic principle, our best clue about how gravity and quantum physics fit together. (2) Topological quantum order, providing ways to distinguish different phases of quantum matter when particles strongly interact with one another. (3) And quantum error correction, our basis for believing we can precisely control very complex quantum systems, including advanced quantum computers. It’s fascinating that these three ideas are actually quite closely related. The common thread connecting them is that all relate to the behavior of many-particle systems that are highly entangled.

Quantum error correction is the idea that we can protect quantum information from local noise by encoding the information in highly entangled states such that the protected information is inaccessible locally, when we look at just a few particles at a time. Topological quantum order is the idea that different quantum phases of matter can look the same when we observe them locally, but are distinguished by global properties hidden from local probes — in other words such states of matter are quantum memories protected by quantum error correction. The holographic principle is the idea that all the information in a gravitating three-dimensional region of space can be encoded by mapping it to a local quantum field theory on the two-dimensional boundary of the space. And that map is in fact the encoding map of a quantum error-correcting code. These ideas illustrate how as our knowledge advances, different fields of physics are converging on common principles. Will that convergence continue in the second century of quantum mechanics? We’ll see.

As we contemplate the long-term trajectory of quantum science and technology, we are hampered by our limited imaginations. But one way to loosely characterize the difference between the past and the future of quantum science is this: For the first hundred years of quantum mechanics, we achieved great success at understanding the behavior of weakly correlated many-particles systems relevant to for example electronic structure, atomic and molecular physics, and quantum optics. The insights gained regarding for instance how electrons are transported through semiconductors or how condensates of photons and atoms behave had invaluable scientific and technological impact. The grand challenge and opportunity we face in the second quantum century is acquiring comparable insight into the complex behavior of highly entangled states of many particles which are well beyond the reach of current theory or computation. This entanglement frontier is vast, inviting, and still largely unexplored. The wonders we encounter in the second century of quantum mechanics, and their implications for human civilization, are bound to supersede by far those of the first century. So let us gratefully acknowledge the quantum heroes of the past and present, and wish good fortune to the quantum explorers of the future.

by preskill at March 20, 2025 09:11 PM

n-Category Café Visual Insights (Part 2)

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From August 2013 to January 2017 I ran a blog called Visual Insight, which was a place to share striking images that help explain topics in mathematics. Here’s the video of a talk I gave last week about some of those images:

Visual Insights.

It was fun showing people the great images created by Refurio Anachro, Greg Egan, Roice Nelson, Gerard Westendorp and many other folks. For more info on the images I talked about, read on….

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Here are the articles I spoke about:

You can see the whole blog at the AMS website or my website, or you can check out individual articles here:

Is that 79 articles? If I’d stopped at 78, that would be the dimension of E₆.

March 17, 2025

John Preskill — Developing an AI for Quantum Chess: Part 1

In January 2016, Caltech’s Institute for Quantum Information and Matter unveiled a YouTube video featuring an extraordinary chess showdown between actor Paul Rudd (a.k.a. Ant-Man) and the legendary Dr. Stephen Hawking. But this was no ordinary match—Rudd had challenged Hawking to a game of Quantum Chess. At the time, Fast Company remarked, “Here we are, less than 10 days away from the biggest ~~advertising~~ football day of the year, and one of the best ads of the week is a 12-minute video of quantum chess from Caltech.” But a Super Bowl ad for what, exactly?

For the past nine years, Quantum Realm Games, with continued generous support from IQIM and other strategic partnerships, has been tirelessly refining the rudimentary Quantum Chess prototype showcased in that now-viral video, transforming it into a fully realized game—one you can play at home or even on a quantum computer. And now, at long last, we’ve reached a major milestone: the launch of Quantum Chess 1.0. You might be wondering—what took us so long?

The answer is simple: developing an AI capable of playing Quantum Chess.

Before we dive into the origin story of the first-ever AI designed to master a truly quantum game, it’s important to understand what enables modern chess AI in the first place.

Chess AI is a vast and complex field, far too deep to explore in full here. For those eager to delve into the details, the Chess Programming Wiki serves as an excellent resource. Instead, this post will focus on what sets Quantum Chess AI apart from its classical counterpart—and the unique challenges we encountered along the way.

So, let’s get started!

Depth Matters

credit: https://www.freecodecamp.org/news/simple-chess-ai-step-by-step-1d55a9266977/

With Chess AI, the name of the game is “depth”, at least for versions based on the Minimax strategy conceived by John von Neumann in 1928 (we’ll say a bit about Neural Network based AI later). The basic idea is that the AI will simulate the possible moves each player can make, down to some depth (number of moves) into the future, then decide which one is best based on a set of evaluation criteria (minimizing the maximum loss incurred by the opponent). The faster it can search, the deeper it can go. And the deeper it can go, the better its evaluation of each potential next move is.

Searching into the future can be modelled as a branching tree, where each branch represents a possible move from a given position (board configuration). The average branching factor for chess is about 35. That means that for a given board configuration, there are about 35 different moves to choose from. So if the AI looks 2 ply (moves) ahead, it sees 35×35 moves on average, and this blows up quickly. By 4 ply, the AI already has 1.5 million moves to evaluate.

Modern chess engines, like Stockfish and Leela, gain their strength by looking far into the future. Depth 10 is considered low in these cases; you really need 20+ if you want the engine to return an accurate evaluation of each move under consideration. To handle that many evaluations, these engines use strong heuristics to prune branches (the width of the tree), so that they don’t need to calculate the exponentially many leaves of the tree. For example, if one of the branches involves losing your Queen, the algorithm may decide to prune that branch and all the moves that come after. But as experienced players can see already, since a Queen sacrifice can sometimes lead to massive gains down the road, such a “naive” heuristic may need to be refined further before it is implemented. Even so, the tension between depth-first versus breadth-first search is ever present.

So I heard you like branches…

https://www.sciencenews.org/article/leonardo-da-vinci-rule-tree-branch-wrong-limb-area-thickness

The addition of split and merge moves in Quantum Chess absolutely explodes the branching factor. Early simulations have shown that it may be in the range of 100-120, but more work is needed to get an accurate count. For all we know, branching could be much bigger. We can get a sense by looking at a single piece, the Queen.

On an otherwise empty chess board, a single Queen on d4 has 27 possible moves (we leave it to the reader to find them all). In Quantum Chess, we add the split move: every piece, besides pawns, can move to any two empty squares it can reach legally. This adds every possible paired combination of standard moves to the list.

But wait, there’s more!

Order matters in Quantum Chess. The Queen can split to d3 and c4, but it can also split to c4 and d3. These subtly different moves can yield different underlying phase structures (given their implementation via a square-root iSWAP gate between the source square and the first target, followed by an iSWAP gate between the source and the second target), potentially changing how interference works on, say, a future merge move. So you get 27*26 = 702 possible moves! And that doesn’t include possible merge moves, which might add another 15-20 branches to each node of our tree.

Do the math and we see that there are roughly 30 times as many moves in Quantum Chess for that queen. Even if we assume the branching factor is only 100, by ply 4 we have 100 million moves to search. We obviously need strong heuristics to do some very aggressive pruning.

But where do we get strong heuristics for a new game? We don’t have centuries of play to study and determine which sequences of moves are good and which aren’t. This brings us to our first attempt at a Quantum Chess AI. Enter StoQfish.

StoQfish

Quantum Chess is based on chess (in fact, you can play regular Chess all the way through if you and your opponent decide to make no quantum moves), which means that chess skill matters. Could we make a strong chess engine work as a quantum chess AI? Stockfish is open source, and incredibly strong, so we started there.

Given the nature of quantum states, the first thing you think about when you try to adapt a classical strategy into a quantum one, is to split the quantum superposition underlying the state of the game into a series of classical states and then sample them according to their (squared) amplitude in the superposition. And that is exactly what we did. We used the Quantum Chess Engine to generate several chess boards by sampling the current state of the game, which can be thought of as a quantum superposition of classical chess configurations, according to the underlying probability distribution. We then passed these boards to Stockfish. Stockfish would, in theory, return its own weighted distribution of the best classical moves. We had some ideas on how to derive split moves from this distribution, but let’s not get ahead of ourselves.

This approach had limited success and significant failures. Stockfish is highly optimized for classical chess, which means that there are some positions that it cannot process. For example, consider the scenario where a King is in superposition of being captured and not captured; upon capture of one of these Kings, samples taken after such a move will produce boards without a King! Similarly, what if a King in superposition is in check, but you’re not worried because the other half of the King is well protected, so you don’t move to protect it? The concept of check is a problem all around, because Quantum Chess doesn’t recognize it. Things like moving “through check” are completely fine.

You can imagine then why whenever Stockfish encounters a board without a King it crashes. In classical Chess, there is always a King on the board. In Quantum Chess, the King is somewhere in the chess multiverse, but not necessarily in every board returned by the sampling procedure.

You might wonder if we couldn’t just throw away boards that weren’t valid. That’s one strategy, but we’re sampling probabilities so if we throw out some of the data, then we introduce bias into the calculation, which leads to poor outcomes overall.

We tried to introduce a King onto boards where he was missing, but that became its own computational problem: how do you reintroduce the King in a way that doesn’t change the assessment of the position?

We even tried to hack Stockfish to abandon its obsession with the King, but that caused a cascade of other failures, and tracing through the Stockfish codebase became a problem that wasn’t likely to yield a good result.

This approach wasn’t working, but we weren’t done with Stockfish just yet. Instead of asking Stockfish for the next best move given a position, we tried asking Stockfish to evaluate a position. The idea was that we could use the board evaluations in our own Minimax algorithm. However, we ran into similar problems, including the illegal position problem.

So we decided to try writing our own minimax search, with our own evaluation heuristics. The basics are simple enough. A board’s value is related to the value of the pieces on the board and their location. And we could borrow from Stockfish’s heuristics as we saw fit.

This gave us Hal 9000. We were sure we’d finally mastered quantum AI. Right? Find out what happened, in the next post.

by Chris Cantwell at March 17, 2025 04:42 PM

March 11, 2025

Matt Leifer — The Confused Chapman Student’s Guide to the APS Global Summit

This guide is intended for the Chapman undergraduate students who are attending this year’s APS Global Summit. It may be useful for others as well.

The APS Global Summit is a ginormous event, featuring dozens of parallel sessions at any given time. It can be exciting for first-time attendees, but also overwhelming. Here, I compile some advice on how to navigate the meeting and some suggestions for sessions and events you might like to attend.

General Advice

Use the online schedule and the mobile app to help you navigate the meeting. If you create a login, the online schedule allows you to add things to your personalized schedule, which you can view on the app at the meeting. This is a very useful thing to do because making decisions of where to go on the fly is difficult.
Do not overschedule yourself. I know it is tempting to figure out how to go to as many things as you can, and run between sessions on opposite sides of the convention center. This will be harder to accomplish than you imagine. The meeting gets very crowded and it is exhausting to sit through a full three-hour session of talks. Schedule some break time and, where possible, schedule blocks of time in one location rather than running all over the place.
You will have noticed that most talks at the meeting are 12min long (10min + 2min). These are called contributed talks. Since they are so short, they are more like adverts for the work than a detailed explanation. They are usually aimed at experts and, quite frankly, many speakers do not know how to give these talks well. It is not worth attending these talks unless one of the following applies:
- You are already an expert in that research area.
- You are strongly considering doing research in that area.
- You are there to support your friends and colleagues who are speaking in that session.
- You are so curious about the research area that you are prepared to sit through a lot of opaque talks to get some idea of what is going on in the area.
- The session is on a topic that is unusually accessible or the session is aimed at undergraduate students.
Instead, you should prioritize attending the following kinds of talks, which you can search for using the filters on the schedule:
- Plenary talks: These are aimed at a general physics audience and are usually by famous speakers (famous by physics standards anyway). Some of these might also be…
- Popular science talks: Aimed at the general public.
- Invited Sessions: These sessions consist of 30min talks by invited speakers in a common research area. There is no guarantee that they will be accessible to novices, but it is much more likely than with the contributed talks. Go to any invited sessions on areas of physics you are curious about.
- Focus Sessions: Focus sessions consist mainly of contributed talks, but they also have one or two 30min invited talks. It is not considered rude to switch sessions between talks, so do not be afraid to just attend the invited talks. They are not always scheduled at the beginning of the session. In fact, some groups deliberately stagger the times of the invited talks so that people can see the invited talks in more than one focus session.
There are sessions that list “Undergraduate Students” as part of their target audience. A lot of these are “Undergraduate Research” sessions. It can be interesting to go to one or two of these to see the variety of undergraduate research experiences that are on offer. However, I would not advise only going to sessions on this list. For one thing, undergraduate research projects are not banned from the other sessions, so many of the best undergraduate projects will not be in those sessions. Going to sessions by topic is a better bet most of the time.
It is helpful to filter the sessions on the schedule by the organizing Unit (Division, Topical Group, or Forum). You can find a list of APS units here. For example, if you are particularly interested in Quantum Information and Computation then you will want to look at the sessions organized by DQI (Division of Quantum Information). Sessions organized by Forums are often particularly accessible, as they tend to be about less technical issues (DEI, Education, History and Philosophy, etc.)

The next sections contain some more specific suggestions about events, talks and sessions that you might like to attend.

Orientation and Networking Events

I have never been to an orientation or networking event at the APS meeting, but then again I did not go to the APS meeting as a student. Networking is one of the best things you can do at the meeting, so do take any opportunities to meet and talk to people.

Sunday March 16

Time	Event	Location
2:00pm – 3:00pm	First Time Attendee Orientation	Anaheim Convention Center, 201AB (Level 2)
3:00pm – 4:00pm	Undergraduate Student Get Together	Anaheim Convention Center, 201AB (Level 2)

Tuesday March 18

Time	Event	Location
12:30pm – 2:00pm	Students Lunch with the Experts	Anaheim Convention Center, Exhibit Hall B

The student lunch with the Experts is especially worth it because you get a one-on-eight meeting with a physicist who works on a topic you are interested in. You also get a free lunch. Spaces are limited, so you need to sign up for it on the Sunday, and early if you want to get your choice of expert.

Generally speaking, food is very expensive in the convention center. Therefore, the more places you can get free food the better. There are networking events, some of which are aimed at students and some of which have free meals. Other good bets for free food include the receptions and business meetings. (With a business meeting you may have to first sit through a boring administrative meeting for an APS unit, but at least the DQI meeting will feature me talking about The Quantum Times.)

Sessions Chaired by Chapman Faculty

The next few sections highlight talks and sessions that involve people at Chapman. You may want to come to these not only to support local people, but also to find out more about areas of research that you might want to do undergraduate research projects in.

The following sessions are being chaired by Chapman faculty. The chair does not give a talk during the session, but acts as a host. But chairs usually work in the areas that the session is about, so it is a good way to get more of an overview of things they are interested in.

Day	Time	Chair	Session Title	Location
Monday 17	11:30pm – 1:54pm	Matt Leifer	Quantum Foundations: Bell Inequalities and Causality	Anaheim Convention Center, 256B (Level 2)
Wednesday 19	8:00am – 10:48am	Andrew Jordan	Optimal Quantum Control	Anaheim Convention Center, 258A (Level 2)
Wednesday 19	11:30am – 1:30pm	Bibek Bhandari	Explorations in Quantum Computing	Virtual Only, Room 1

Talks involving Chapman Faculty, Postdocs and Students

The talks listed below all have someone who is currently affiliated with Chapman as one or more of the authors. The Chapman person is not necessarily the person giving the talk.

The people giving the talks, especially if they are students or postdocs, would appreciate your support. It is also a good way of finding out more about research that is going on at Chapman.

Monday March 17

Time	Speaker	Title	Location
9:36am – 9:48am	Irwin Huang	Beyond Single Photon Dissipation in Kerr Cat Qubits	Ahaheim Convention Center, 161 (Level 1)
9:48am – 10am	Bingcheng Qing	Benchmarking Single-Qubit Gates on a Noise-Biased Qubit: Kerr cat qubit	Anaheim Convention Center, 161 (Level 1)
10:12am – 10:24am	Ahmed Hjar	Strong light-matter coupling to protect quantum information with Schrodinger cat states	Anaheim Convention Center, 161 (Level 1)
10:24am – 10:36am	Bibek Bhandari	Decoherence in dynamically protected qubits	Anaheim Convention Center, 161 (Level 1)
10:36am – 10:48am	Ke Wang	Control-Z two-qubit gate on 2D Kerr cats	Anaheim Convention Center, 161 (Level 1)
4:12pm – 4:24pm	Adithi Ajith	Stabilizing two-qubit entanglement using stochastic path integral formalism	Anaheim Convention Center, 258A (Level 2)
4:36pm – 4:48 pm	Alok Nath Singh	Capturing an electron during a virtual transition via continuous measurement	Anaheim Convention Center, 252B (Level 2)

Tuesday March 18

Time	Speaker	Title	Location
8:48am – 9:00am	Alexandria O Udenkwo	Characterizing the energy and efficiency of an entanglement fueled engine in a circuit QED processor	Anaheim Convention Center, 162 (Level 1)
12:30pm – 12:42pm	Yile Ying	A review and analysis of six extended Wigner’s friend arguments	Anaheim Convention Center, 256B (Level 2)
1:54pm – 2:06pm	Indrajit Sen	ΡΤ-symmetric axion electrodynamics: A pilot-wave approach	Anaheim Marriott, Platinum 1
3:48pm – 4:00pm	Chuanhong Liu	Planar Fluxonium Qubits Design with 4-way Coupling	Anaheim Convention Center, 162 (Level 1)
4:36pm – 4:48pm	Robert Czupryniak	Reinforcement Learning Meets Quantum Control – Artificially Intelligent Maxwell’s Demon	Anaheim Convention Center, 258A (Level 2)

Wednesday March 19

Time	Speaker	Title	Location
10:36am – 10:48am	Dominic Briseno-Colunga	Dynamical Sweet Spot Manifolds of Bichromatically Driven Floquet Qubits	Anaheim Convention Center, 162 (Level 1)
2:30pm – 2:42pm	Sayani Ghosh	Equilibria and Effective Rates of Transition in Astromers	Anaheim Marriott, Platinum 7
3:00pm – 3:12pm	Matt Leifer	A Foundational Perspective on PT-Symmetric Quantum Theory	Anaheim Convention Center, 151 (Level 1)
5:36pm – 5:48pm	Sacha Greenfield	A unified picture for quantum Zeno and anti-Zeno effects	Anaheim Convention Center, 161 (Level 1)

Thursday March 20

Time	Speaker	Title	Location
1:18pm – 1:30pm	Lucas Burns	Delayed Choice Lorentz Transformations on a Qubit	Anaheim Convention Center, 256B (Level 2)
4:48pm – 5:00pm	Noah J Stevenson	Design of fluxonium coupling and readout via SQUID couplers	Anaheim Convention Center, 161 (Level 1)
5:00pm – 5:12pm	Kagan Yanik	Flux-Pumped Symmetrically Threaded SQUID Josephson Parametric Amplifier	Anaheim Convention Center, 204C (Level 2)
5:00pm – 5:12pm	Abhishek Chakraborty	Two-qubit gates for fluxonium qubits using a tunable coupler	Anaheim Convention Center, 161 (Level 1)

Friday March 21

Time	Speaker	Title	Location
10:12am – 10:24am	Nooshin M. Estakhri	Distinct statistical properties of quantum two-photon backscattering	Anaheim Convention Center, 253A (Level 2)
10:48am – 11:00am	Le Hu	Entanglement dynamics in collision models and all-to-all entangled states	Anaheim Hilton, San Simeon AB (Level 4)
11:54am – 12:06pm	Luke Valerio	Optimal Design of Plasmonic Nanotweezers with Genetic Algorithm	Anaheim Convention Center, 253A (Level 2)

Posters involving Chapman Faculty, Postdocs and Students

Poster sessions last longer than talks, so you can view the posters at your leisure. The presenter is supposed to stand by their poster and talk to people who come to see it. The following posters are being presented by Chapman undergraduates. Please drop by and support them.

Thursday March 20, 10:00am – 1:00pm, Anaheim Convention Center, Exhibit Hall A

Poster Number	Presenter	Title
267	Ponthea Zahraii	Machine learning-assisted characterization of optical forces near gradient metasurfaces
400	Clara Hunt	What the white orchid can teach us about radiative cooling
401	Nathan Taormina	Optimizing Insulation and Geometrical Designs for Enhanced Sub-Ambient Radiative Cooling Efficiency

Leifer’s Recommendations

These are sessions that reflect my own interests. It is a good bet that you will find me at one of these, unless I am teaching, or someone I know is speaking somewhere else. There are multiple sessions at the same time, but what I will typically do is select the one that has the most interesting looking talk at the time and switch sessions from time to time or take a break from sessions entirely if I get bored.

Monday March 17

Time	Session Title	Location
8:00am – 11:00am	Quantum Science and Technology at the National DOE Research Centers: Progress and Opportunities	Anaheim Convention Center, 158 (Level 1)
8:00am – 11:00am	Learning and Benchmarking Quantum Channels	Anaheim Convention Center, 258A (Level 2)
10:45am – 12:33pm	Beginners Guide to Quantum Gravity	Anaheim Marriott, Grand Ballroom Salon E
11:30am – 1:54pm	Quantum Foundations: Bell Inequalities and Causality	Anaheim Convention Center, 256B (Level 2)
1:30pm – 3:18pm	History and Physics of the Manhattan Project and the Bombings of Hiroshima and Nagasaki	Anaheim Marriott, Platinum 9
3:00pm – 6:00pm	DQI Thesis Award Session	Anaheim Convention Center, 158 (Level 1)

Tuesday March 18

Time	Session Title	Location
8:30am – 10:18am	Forum on Outreach and Engagement of the Public Invited Session	Anaheim Marriott, Orange County Salon 1
10:45am – 12:33pm	Pais Prize Session	Anaheim Marriott, Platinum 2
11:30am – 2:30pm	Applied Quantum Foundations	Anaheim Convention Center, 256B (Level 2)
1:30pm – 3:18pm	Mini-Symposium: Research Validated Assessments in Education	Anaheim Marriott, Grand Ballroom Salon D
1:30pm – 3:18pm	Research in Quantum Mechanics Instruction	Anaheim Marriott, Orange County Salon 1
3:00pm – 5:24pm	Landauer-Bennett Award Prize Symposium	Anaheim Convention Center, 158 (Level 1)
3:00pm – 6:00pm	Undergraduate and Graduate Education I	Anaheim Convention Center, 263A (Level 2)
3:00pm – 6:00pm	Invited Session for the Forum on Outreach and Engagement of the Public	Anaheim Convention Center, 155 (Level 1)
3:45pm – 5:33pm	Highlights from the Special Collections of AJP and TPT on Teaching About Quantum	Anaheim Marriott, Platinum 3
6:15pm – 9:00pm	DQI Business Meeting	Anaheim Convention Center, 160 (Level 1)

Wednesday March 19

Time	Session Title	Location
11:30am – 2:30pm	Quantum Information: Thermodynamics out of Equilibrium	Anaheim Hilton, San Simeon AB (Level 4)
3:00pm – 5:36pm	Quantum Foundations: Measurements, Contextuality, and Classicality	Anaheim Convention Center, 151 (Level 1)
3:00pm – 6:00pm	Beyond Knabenphysik: Women in the History of Quantum Physics	Anaheim Convention Center, 154 (Level 1)

Thursday March 20

Time	Session Title	Location
8:00am – 10:48am	Undergraduate Education	Anaheim Convention Center, 263A (Level 2)
8:00am – 11:00am	Open Quantum Systems and Many-Body Dynamics	Anaheim Hilton, San Simeon AB (Level 4)
11:30am – 2:30pm	Time in Quantum Mechanics and Thermodynamics	Anaheim Hilton, California C (Ballroom Level)
11:30am – 2:30pm	Intersections of Quantum Science and Society	Anaheim Convention Center, 159 (Level 1)
11:30am – 2:18pm	Quantum Foundations: Relativity, Gravity, and Geometry	Anaheim Convention Center, 256B (Level 2)
3:00pm – 6:00pm	The Early History of Quantum Information Physics	Anaheim Convention Center, 154 (Level 1)
3:00pm – 6:00pm	Quantum Thermalization: Understanding the Dynamical Foundation of Quantum Thermodynamics	Anaheim Hilton, California A (Ballroom Level)

Friday March 21

Time	Session Title	Location
8:00am – 11:00am	Structu res in Quantum Systems	Anaheim Convention Center, 258A (Level 2)
8:00am – 10:24am	Science Communication in an Age of Misinformation and Disinformation	Anaheim Convention Center, 156 (Level 1)

The Exhibition Hall

It is worthwhile to spend some time in the exhibit hall. It features a Careers Fair and a Grad School Fair, which will be larger and more relevant to physics students than other such fairs you might attend in the area.

But, of course, the main purpose of going to the exhibition hall is to acquire SWAG. Some free items I have obtained from past APS exhibit halls include:

Rubik’s cubes
Balls that light up when you bounce them
Yo-Yos
Wooden model airplanes
Snacks
T-shits
Tote bags
Enough stationery items to last for the rest of your degree
Free magazines and journals
Free or heavily discounted books

I recommend going when the hall first opens to get the highest quality SWAG.

Fun Stuff

Other fun stuff to do at this year’s meeting includes:

QuantumFest: This starts with the Quantum Jubilee event on Saturday, but there are events all week some of which you have to be registered for the meeting for. Definitely reserve a spot for the LabEscape escpae room. I have done one of their rooms before and it is fun.
Physics Rock-n-Roll Singalong: A very nerdy APS meeting tradition. Worth attending once in your life. Probably only once though.

by admin at March 11, 2025 11:14 PM

March 03, 2025

Clifford Johnson — Valuable Instants

This week’s lectures on instantons in my gauge theory class (a very important kind of theory for understanding many phenomenon in nature – light is an example of a phenomenon that is described by gauge theory) were a lot of fun to do, and mark the culmination of a month-long … Click to continue reading this post →

The post Valuable Instants appeared first on Asymptotia.

by Clifford at March 03, 2025 04:58 AM

February 22, 2025

Robert Helling — The Bohm-GHZ paper is out

I had this neat calculation in my drawer and on the occasion of quantum mechanic's 100th birthday in 2025, I decided I submit a talk about it to the March meeting of the DPG, the German physical society, in Göttingen. And to have to show something, I put it out on the arxiv today. The idea is as follows:

The GHZ experiment is a beautiful version of Bell's inequality that demonstrates you get to wrong conclusions when you assume that a property of a quantum system has to have some (unknown) value even when you don't measure it. I would say it shows quantum theory is not realistic, in the sense that unmeasured properties do not have secret values (different for example from classical statistical mechanics where you could imagine to actually measure the exact position of molecule number 2342 in your container of gas). For details, see the paper or this beautiful explanation by Coleman. I should mention here that there is another way out by assuming some non-local forces that conspire to make the result come out right never the less.

On the other hand there is Bohmian mechanics. This is well known to be a non-local theory (as the time evolution of its particles depend on the positions of all other particles in the system or even universe) but what I found more interesting is also realistic: There, it is claimed that all that matters are particles positions (including the positions of pointers on your measurement devices that you might interpret as showing something different than positions for example velocities or field strengths or whatever) and those have all (possibly unknown) values at all times even if you don't measure them.

So how can the two be brought together? There might be an obstacle in the fact that GHZ is usually presented to be a correlation of spins and in the Bohmian literature spins are not really positions, you will always have to make use of some Stern-Gerlach experiments to translate those into actual positions. But we can circumvent this the other way: We don't really need spins, we just need observables of the commutation relation of Pauli matrices. You might think that those cannot be realised with position measurements as they always commute but this is only true as you do the position measurements at equal times. If you wait between them, you can in fact have almost Pauli type operators.

So we can set up a GHZ experiment in terms of three particles in three boxes and for each particle you measure whether it is in the left or the right half of the box but for each particle you decide if you do it at time 0 or at a later moment. You can look at the correlation of the three measurements as a function of time (of course, as you measure different particles, the actual measurements you do still commute independent of time) and what you find is the blue line in

GHZ correlations vs. Bohmian correlations

You can also (numerically) solve the Bohmian equation of motion and compute the expectation of the correlation of positions of the three particles at different times which gives the orange line, clearly something else. No surprise, the realistic theory cannot predict the outcome of an experiment that demonstrates that quantum theory is not realistic. And the non-local character of the evolution equation does not help either.

To save the Bohmian theory, one can in fact argue that I have computed the wrong thing: After measuring the position of one particle at time 0 or by letting it interact with a measuring device, the future time evolution of all particles is affected and one should compute that correlation with the corrected (effectively collapsed) wave function. That, however, I cannot do and I claim is impossible since it would depend on the details of how the first particle's position is actually measured (whereas the orthodox prediction above is independent of those details as those interactions commute with the later observations). In any case, at least my interpretation is that if you don't want to predict the correlation wrong the best you can do is to say you cannot do the calculation as it depends on unknown details (but the result of course shouldn't).

In any case, the standard argument why Bohmian mechanics is indistinguishable from more conventional treatments is that all that matters are position correlations and since those are given by psi-squared they are the same for all approaches. But I show this is not the case for these multi-time correlations.

Post script: What happens when you try to discuss physics with a philosopher:

by Robert at February 22, 2025 05:31 PM

January 15, 2025

Andrew Jaffe — The Only Gaijin in the Onsen

After living in Japan for about four months, we left in mid-December. We miss it already.

One of the pleasures we discovered is the onsen, or hot spring. Originally referring to the natural volcanic springs themselves, and the villages around them, there are now onsens all over Japan. Many hotels have an onsen, and most towns will have several. Some people still use them as their primary bath and shower for keeping clean. (Outside of actual volcanic locations, these are technically sento rather than onsen.) You don’t actually wash yourself in the hot baths themselves; they are just for soaking, and there are often several, at different temperatures, mineral content, indoor and outdoor locations, whirlpools and even “electric baths” with muscle-stimulating currents. For actual cleaning, there is a bank of hand showers, usually with soap and shampoo. Some can be very basic, some much more like a posh spa, with massages, saunas, and a restaurant.

Our favourite, about 25 minutes away by bicycle, was Kirari Onsen Tsukuba. When not traveling, we tried to go every weekend, spending a day soaking in the hot water, eating the good food, staring at the gardens, snacking on Hokkaido soft cream — possibly the best soft-serve ice cream in the world (sorry, Carvel!), and just enjoying the quiet and peace. Even our seven- and nine-year old girls have found the onsen spirit, calming and quieting themselves down for at least a few hours.

Living in Tsukuba, lovely but not a common tourist destination, although with plenty of foreigners due to the constellation of laboratories and universities, we were often one of only one or two western families in our local onsen. It sometimes takes Americans (and those from other buttoned-up cultures) some time to get used to their sex-segregated but fully-naked policies of the baths themselves. The communal areas, however, are mixed, and fully-clothed. In fact, many hotels and fancier onsen facilities supply a jinbei, a short-sleeve pyjama set in which you can softly pad around the premises during your stay. (I enjoyed wearing jinbei so much that I purchased a lightweight cotton set for home, and am also trying to get my hands on samue, a somewhat heavier style of traditional Japanese clothing.)

And my newfound love for the onsen is another reason not to get a tattoo beyond the sagging flesh and embarrassment of my future self: in Japan, tattoos are often a symbol of the yakuza, and are strictly forbidden in the onsen, even for foreigners.

Later in our sabbatical, we will be living in the Netherlands, which also has a good public bath culture, but it will be hard to match the calm of the Japanese onsen.

by defjaf at January 15, 2025 01:05 AM

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