I’m giving a talk on the math of tuning systems at Claremont McKenna College on January 30th at 11 am. If you’re around, please come! You can read my slides here:

But my slides don’t contain most of what I’ll write here… the stuff I’ll say out loud in my talk.

If you look at a piano keyboard you’ll see groups of 2 black notes alternating with groups of 3. So the pattern repeats after 5 black notes, but if you count you’ll see there are also 7 white notes in this repetitive pattern. So: the pattern repeats each 12 notes.

Some people who never play the piano claim it would be easier if had all white keys, or simply white alternating with black. But in fact the pattern makes it easier to keep track of where you are – and it’s not arbitrary, it’s musically significant.

For one thing white notes give a 7-note scale all their own. Most very simple songs use only this scale! The black notes also form a useful scale. And the white and black notes together form a 12-tone scale.

Starting at any note and going up 12 notes, we reach a note whose frequency is almost exactly double the one we started with. Other spacings correspond to other frequency ratios.

I don’t want to overwhelm you with numbers. So I’m only showing you a few of the simplest and most important ratios. These are really worth remembering.

We give the notes letter names. This goes back at least to Boethius, the guy famous for writing The Consolations of Philosophy before he was tortured and killed at the order of Theodoric the Great. (Yeah, “Great”.) Boethius was a counselor to Theodoric, but he really would have done better to stay out of politics – he was quite good at math and music theory.

Boethius may be the reason the lowest note on the piano is called A. We now repeat the names of the white notes as shown in the picture: seven white notes A,B,C,D,E,F,G and then it repeats.

So the scale used to start at A, using only white notes. But due to the irregular spacing of white notes, a scale of all white notes sounds different depending on where you start. Starting at A gives you the ‘minor scale’, which sounds kinda sad. Now we often start at C, since that gives us the scale most people like best: the ‘major’ scale.

(Good musicians start wherever they want, and get different sounds that way. But ‘C major’ is like the vanilla ice cream of scales—now. It wasn’t always this way.)

From the late 1100s to about 1600 people called pitches that lie outside 7-tone system ‘musica ficta’: ‘false’ or ‘fictitious’ notes. But gradually these notes—the black keys on the piano when you’re playing in C major—became more accepted.

To keep things simple for mathematicians, I’ll usually denote these with the ‘flat’ symbol, ♭. For example, G♭ is the black note one down from the white note G.

(Musicians really need both flats and sharps, and they’d also call G♭ something else: F♯. I’ll actually need both G♭ and F♯ at some points in this talk!)

Since starting the scale with the letter C takes a little practice, I’ll do it a different way that mathematicians may like better. I’ll start with 1 and count up. Musicians put little hats on these numbers, and I’ll do that.

For example, we’ll call the fifth white note up the scale the ‘fifth’ and write it as $\hat{5}.$

Now for the math of tuning systems!

The big question is: how do we choose the frequency of each note? This is literally how many times per second the air vibrates, when we play that note.

Since 1850, by far the most common method for tuning keyboards has been ’12-tone equal temperament’. Here we divide each octave into 12 equal parts.

What do I mean by this, exactly? I mean that each note on the piano produces a sound that vibrates faster than the note directly below it by a factor of the 12th root of 2.

But we can contemplate ‘N-tone equal temperament’ for N = 1, 2, 3, …. – and some people do use these other tuning systems!

Here’s a picture of the most popular modern tuning system: 12-tone equal temperament. As we march around clockwise, each note has a frequency of $2^{1/12}$ times the note directly before it.

When we go all the way around the circle, we’ve gone up an octave. That is, we’ve reached a frequency that’s twice the one we started with.

But a note that’s an octave higher sounds ‘the same, only higher’. So in a funny way we’re back where we started.

But now for a big question: why do we use a scale with 12 notes?

To start answering, notice that we actually use three scales: one with 5 notes (the black keys), one with 7 (the white keys) and one with 12 (all the keys).

As mathematicians we can detect a highly nonobvious pattern here.

What’s so good about scales with 5, 7 or 12 notes?

A crucial clue seems to be the ‘fifth’. If you go up to the fifth white note here, its frequency is about 3/2 times the first. This is one of the simplest fractions, and it sounds incredibly simple and pure. So it’s important. It’s a dominant force in western music.

We can make a chart to see how close an approximation to the fraction 3/2 we get in a scale with N equally spaced notes.

N = 5 does better than any scale with fewer notes!

N = 7 does better than any scale with fewer notes!

N = 12 does better than any scale with fewer notes! And it does much better. To beat it, we have to go all the way up to N = 29—and even that is only slightly better.

Here’s a chart of how close we can get to a frequency ratio of 3/2 using N-tone equal temperament.

See how great 12-tone equal temperament is?

There are also some neat patterns. See the stripes of even numbers and stripes of odd numbers? That’s not a coincidence. For more charts like this, and much more cool stuff along these lines, go here.

Here’s the ‘star of fifths’ in 12-tone equal temperament!

12-tone equal temperament is most popular tuning system since maybe 1810, or definitely by 1850. But it’s mathematically the most boring of the tuning systems that have dominated Western music since the Middle Ages. Now let’s go back much earlier, to Pythagorean tuning.

When you chop the octave into 12 equal parts, the frequency ratios of all your notes are irrational numbers… except when you go up or down some number of octaves.

The Pythagoreans disliked irrational numbers. People even say they drowned Hippasus at sea after he proved that the square root of 2 is irrational! That’s just a myth, but it illustrates how people connected Pythagoras to a love of rational numbers. In Pythagorean tuning, people wanted a lot of frequency ratios of 3/2.

In equal temperament, where we chop the octave into 12 equal parts, when we start at any note and go up 7 of these parts (a so-called ‘fifth’), we reach a note that vibrates about 1.4981 times as fast. That’s close enough to 3/2 for most ears. But it’s not the Pythagorean ideal!

As we’ll see, seeking the Pythagorean ideal causes trouble. It will unleash the devil in music.

Start at some note and keep multiplying the frequency by 3/2, like a good Pythagorean. After doing this 12 times, you reach a note that’s close to 7 octaves higher. But not exactly, since the 12th power of 3/2 is

129.746338

which is a bit more than

2⁷ = 128

The ratio of these two is called the ‘Pythagorean comma’:

p = (3/2)¹² / 2⁷ = 3¹² / 2¹⁹ ≈ 1.0136

This is like an unavoidable lump in the carpet when you use Pythagorean tuning.

It’s good to stick the lump in your carpet under your couch. And it’s good to stick the Pythagorean comma near the so-called ‘tritone’—a very dissonant note that you’d tend to avoid in medieval music. This note is halfway around the circle of fifths.

In Pythagorean tuning, going 6 steps clockwise around the circle of fifths doesn’t give you the same note as going 6 steps counterclockwise! We call one of them ♭5 and the other ♯4.

Their frequency ratio is the Pythagorean comma!

In equal temperament, the tritone is exactly halfway up the octave: 6 notes up. Since going up an octave doubles the frequency, going up a tritone multiplies the frequency by √2. It’s no coincidence that this is the irrational number that got Hippasus in trouble.

In Pythagorean tuning, going 6 steps up the scale doesn’t match jumping up an octave and then going 6 steps down. We call one of them ♭5 and the other ♯4. They’re both decent approximations to √2, built from powers of 2 and 3.

Their frequency ratio is the Pythagorean comma!

The tritone is sometimes called ‘diabolus in musica’: the devil in music. Some say this interval was actually banned by the Catholic church! But that’s another myth.

It could have gotten its name because it sounds so dissonant—but mathematically, the ‘devil’ here is that the square root of 2 is irrational. If we’re trying to use only numbers built from powers of 2 and 3, we have to arbitrarily choose one to approximate √2.

In Pythagorean tuning we can choose either

1024/729 ≈ 1.4047

called the sharped fourth, ♯4, or

729/512 ≈ 1.4238

called the flatted fifth, ♭5, to be our tritone. In this chart I’ve chosen the ♭5.

No matter which you choose, one fifth in the circle of fifths will be noticeably smaller than the rest. It’s called the ‘wolf fifth’ because it howls like a wolf.

You can hear a wolf fifth here:

If you’re playing medieval music, you can easily avoid the wolf fifth: just don’t play one of the two fifths that contains the tritone!

A more practical problem concerns the ‘third’: the third white note in the scale. Ideally this vibrates 5/4 as fast as the first. But in Pythagorean tuning it vibrates 81/64 times as fast. That’s annoyingly high!

Sure, 81/64 is a rational number. But it’s not the really simple rational number our ears are hoping for when we hear a third.

Indeed, Pythagorean tuning punishes the ear with some very complicated fractions. The first, fourth, fifth and octave are great. But the rest of the notes are not. There’s no way that 243/128 sounds better than an irrational number!

In the 1300s, when thirds were becoming more important in music, theorists embraced a beautiful solution to this problem, called ‘just intonation’. Now let’s talk about that.

It’s an amazing fact that in western composed music, harmony became important only around 1200 AD, when Perotin expanded the brand new use of two-part harmony to four-part harmony.

This put pressure on musicians to use a new tuning system—or rather, to revive an old tuning system. It’s often called ‘just intonation’ (though experts will find that vague). We can get using a cool trick, though I doubt this is how it was originally discovered.

First, draw a hexagonal grid of notes. Put a note with frequency 1 in the middle. Label the other notes by saying that moving one step to the right multiplies the frequency of your note by 3/2, while going up and to the right multiplies it by 5/4.

Next, cut out a portion of the grid to use for our scale. We use this particular parallelogram—you’ll soon see what’s so great about it.

Now, multiply each number in our parallelogram by whatever power of 2 it takes to get a number between 1 and 2.

We do this because we want frequencies that lie within an octave, to be notes in a scale. Remember: if 1 is the note we started with, 2 is the note an octave up.

Now we want to curl up our parallelogram to get a torus. If we do this, gluing together opposite edges, there will be exactly 12 numbers on our torus—just right for a scale! This is a remarkable coincidence.

There’s a problem: the numbers at the corners are not all equal. But they’re pretty close! And they’re close to √2: the frequency of the tritone, the ‘devil in music’.

25/18 = 1.3888…
45/32 = 1.40625
64/45 = 1.4222…
36/25 = 1.44

So we’ll just pick one.

When we curl up our parallelogram to get a torus, there’s also another problem. The numbers along the left edge aren’t equal to the corresponding numbers at the right edge. But they’re close! Each number at right is 81/80 times the corresponding number at left. I’ve drawn red lines connecting them.

So, we just choose one from each of these 4 pairs. We’ve already picked one number for all the corners, so we just need to do this for the remaining 2 pairs.

So, here are the various choices for notes in our scale!

For the tritone we have 4 choices. That’s okay because this note sucks anyway. That is: in Western music from the 1300s, it was considered very dissonant. So there’s no obviously best choice of how it should sound.

For the 2 we have two choices, and for the ♭7 we also have 2 choices. So there’s a total of 16 possible scales here.

Regardless of how we make our choices, we’ll get really nice simple fractions for the 1, ♭3, 3, 4, 5 ,♭6, 6, and 8. And that makes this approach, called ‘just intonation’, really great!

(If you like math: notice the ‘up-down symmetry’ in this whole setup. For example the minor second is 16/15, but the reciprocal of that is 15/16, which is the seventh… at least after we double it to get a number between 1 and 2, getting 15/8.)

Here’s a chart of all possible just intonation scales: start at the top and take any route you want to the bottom. There are 16 possible routes.

A single step between notes in a 12-tone scale is called a ‘semitone’, since most white notes are two steps apart. In just intonation the semitones come in 4 different sizes, which is kind of annoying.

Notice that if we choose our route cleverly, we can completely avoid the large diatonic semitone. Or, we can avoid the greater chromatic semitone. But we can’t avoid both. So, we can get a scale with just 3 sizes of semitone, but not fewer.

How should we choose???

This is the most commonly used form of just intonation, I think. It has a few nice features:

1) It has up-down symmetry except right next to the tritone in the middle, where this symmetry is impossible.

2) It uses 9/8 for the second rather than 10/9, which is a bit nicer: a simpler fraction.

3) It completely avoids the large diatonic semitone, which is the largest possible semitone.

These don’t single out this one scale. I’d like to find some nice features that only this one of the 16 possibilities has.

But let’s see what this scale looks like on the keyboard!

Here’s the most common scale in just intonation!

The white notes are perhaps the most important here, since those give the major scale. The fractions here are beautifully simple.

Well, okay: the second (9/8) and seventh (15/8) are not so simple. But that’s to be expected, since these notes are the most dissonant! Of these, the seventh was more important in the music of the 1300s, and even today. It’s called the ‘leading-tone’, because we often play it right near the end of a piece of music, or a passage within a piece of music, and its dissonance leads us up to the octave, with a tremendous sense of relief.

Here’s the really great thing about the white notes in just intonation. They form three groups, each with frequencies in the ratios

1 : 5/4 : 3/2

or in other words,

4 : 5 : 6

This pattern is called a ‘major triad’ and it’s absolutely fundamental to music—perhaps not so much in the 1300s, but certainly as music unfolded later. Major triads became the bread and butter of music, and still are.

The fact that every white note—that is, every note in the 7-note major scale—lies in a mathematically perfect major triad is a gigantic feature in favor of just intonation.

Listen to the difference between some simple chords in just intonation and in equal temperament. You probably won’t hate equal temperament, but you can hear the difference. Equal temperament vibrates as the notes drift in and out of phase.

But let’s take a final peek at the dark underbelly of just intonation: the tritone. As I mentioned, there are four choices of tritone in just intonation. You can divide them into two pairs that are separated by a ratio of 81/80, or two pairs separated by a ratio of 128/125.

These numbers are fundamental glitches in the fabric of music. They have names! People have been thinking about them at least since Boethius around 500 AD, but probably earlier.

• The ‘syntonic comma’, 81/80, is all about trying to approximate a power of 3 by products of 2’s and 5’s.

• The ‘lesser diesis’, 128/125, is all about trying to approximate powers of 2 by powers of 5.

If these numbers were 1, music would be beautiful in a very simple way. But reality cannot be wished away.

And as we’ll see, these numbers are lurking in the spacing between notes in just intonation—not just near the tritone, but everywhere!

Look! The four kinds of semitone in just intonation are related by the lesser diesis and syntonic comma!

In this chart, adding vectors corresponds to multiplying numbers. For example, the green arrow followed by the red one gives the dark blue one, so

25/24 × 81/80 = 135/138

Or in music terminology: the lesser chromatic semitone times the syntonic comma is the greater chromatic semitone.

And so on.

The parallelogram here is secretly related to the parallelogram we curled up to get the just intonation scale. Think about it! Music holds many mysteries.

Just intonation is great if you’re playing in just one ‘key’, always ending each passage with the note I’ve been calling 1. But when people started trying to ‘change keys’, musicians were pressed into other tuning systems.

This is a long story, which I don’t have time to tell right now. If you’re curious, read my blog articles about it!

• For more on Pythagorean tuning, read this.

• For more on just intonation, read this series.

• For more on quarter-comma meantone tuning, read this series.

• For more on well-tempered scales, read this series.

• for more on equal temperament, read this series.

It’s sad in a way that this historical development winds up with equal temperament: the most boring of all the systems, which is equally good, and thus equally bad, in every key. But the history of music is not done, and computers make it vastly easier than ever before to explore tuning systems.

by John Baez at January 01, 2026 02:57 PM

December 30, 2025

John Baez — Just Intonation (Part 6)

In this series I’ve been explaining 12-tone scales in just intonation—or more precisely, ‘5-limit’ just intonation, where all the frequency ratios are integer powers of the primes 2, 3 and 5. There are various choices involved in building such a scale. A lot of famous mathematicians have tried their hand at it. Kepler, Descartes, Mersenne, Newton, Mercator, and Euler are among them. They didn’t agree on the best scale: they came up with different scales.

Newton did his work on this in college when he was 22. This was 1665, the year he later fled Trinity College to avoid the Great Plague, went to the countryside, invented calculus, began thinking about gravity, and discovered that a prism can recombine colors of light to make white light.

Given this, I can’t resist classifying all possible scales of this sort. Today we’ll see that by a certain precise definition, there are 174,240 such scales! It will take a bit of combinatorics to work this out. Among this large collection of scales we will also find smaller sets of scales with nice properties. But I still don’t know why those mathematicians chose the scales they did.

In studying this, and indeed in all my work on just intonation, I was greatly helped by this wonderful paper:

• Daniel Muzzulini, Isaac Newton’s microtonal approach to just intonation, Empirical Musicology Review 15 (2021), 223–248.

It’s full of interesting diagrams:

Anyway, let’s get going!

In Part 2 of this series, I examined the choices involved in building a just intonation scale. I described a general recipe for building such scales. These leads to 2 × 4 × 2 = 16 different scales, based on how you make the choices here:

tonic		1
minor 2nd		16/15
major 2nd		10/9 or 9/8
minor 3rd		6/5
major 3rd		5/4
perfect 4th		4/3
tritone		25/18 or 45/32 or 64/45 or 36/25
perfect 5th		3/2
minor 6th		8/5
major 6th		5/3
minor 7th		16/9 or 9/5
major 7th		15/8
octave		2

Newton’s scale is one of these 16. Marin Mersenne had created the same scale in 1636, but Newton probably didn’t know this. In fact I studied this scale in Part 4, where I claimed that it’s the most popular just intonation scale of all! It’s hard to be sure of that—but I certainly think it’s the nicest one.

Here it is:

The intervals between the notes come in 3 different sizes, which we will discuss soon. In Part 4, I explained some reasons this scale is nice. For example, the intervals here are nearly palindromic! The first interval is the same as the last, and so on—except right near the middle of the scale, the ‘tritone’, where this symmetry is impossible because it would force $\sqrt{2}$ to be a rational number.

In Part 4, I also considered another less popular scale among the 16 generated by my recipe:

In this one the intervals come in 4 different sizes! Let’s make up abbreviations for them. In order of increasing size, they are:

• c: the lesser chromatic semitone, with frequency ratio 25/24 = 1.041666…

• C: the greater chromatic semitone, with frequency ratio 135/128 = 1.0546875.

• d: the diatonic semitone, with a frequency ratio of 16/15 = 1.0666…

• D: the large diatonic semitone, with frequency ratio 27/25 = 1.08.

With this notation, Newton’s scale is

d C d c d C d d c d C d

I’ll say this scale has type (2,3,7,0) since it has 2 c’s, 3 C’s, 7 d’s and 0 D’s. The less popular scale I mentioned is

d C d c d c D d c d C d

This scale has type (3,2,6,1). Arguably this scale is worse, because the large diatonic semitone is quite large compared to all the rest.

Muzzulini also describes some other just intonation scales. Here’s one that Nicolas Mercator created around 1660—not the Mercator with the map, the one who discovered the power series for the logarithm:

c D d c d c D c d d C d

This is striking because it has two large diatonic semitones: it’s of type (4,1,5,2).

Here’s one that the music theorist William Holder wrote down in 1694:

c d D c d c D c d D c d

This has three diatonic semitones—the most possible! It’s of type (5,0,4,3).

Leonhard Euler came up with this scale in 1739:

c D c d d C d c d C d d

This has type (3,2,6,1).

It would be interesting to find out, if possible, why various authors chose the scales they did. Did they scan the universe of possibilities and try to pick a scale that was optimal in some way—or did they did they just make one up? Answering this would require some historical investigation.

All these ruminations led me to some questions about enumerating and classifying scales, which I included as puzzles in Part 4. Now let me finally answer them!

Puzzle 1. As we’ve seen, the most popular 12-tone just intonation scale is of type (2,3,7,0). That is, it has 2 lesser chromatic semitones, 3 greater chromatic semitones, 7 diatonic semitones, and no large diatonic semitones. By permuting these semitones we can get many other scales. How many different scales can we get this way?

Answer. We have a 12-element set and we’re asking: in how many ways can we partition it into a 2-element set, a 3-element set and a 7-element set? This is the kind of question that multinomial coefficients were designed to answer. The answer is

$\displaystyle{ \frac{12!}{2! \cdot 3! \cdot 7!} = 7920 }$ █

Puzzle 2. Our second, less popular 12-tone just intonation scale is of type (3,2,6,1): it has 3 lesser chromatic semitones, 2 greater chromatic semitones, 6 diatonic semitones and 1 large diatonic semitone. How many other scales can we get by permuting these semitones?

Answer. By the same reasoning, we have

$\displaystyle{ \frac{12!}{3! \cdot 2! \cdot 6! \cdot 1!} = 55,440 }$

such scales. █

These puzzles were warmups for a bigger question:

Puzzle 3. How many 12-tone scales are there where the spacing between each pair of successive notes is either a lesser chromatic semitone, a greater chromatic semitone, a diatonic semitone, or a large diatonic semitone?

Answer. The only types of scales allowed are quadruples $(i,j,k,\ell)$ of nonnegative integers where

$\displaystyle{ \left(\frac{25}{24}\right)^i \left( \frac{135}{128} \right)^j \left( \frac{16}{15} \right)^k \left( \frac{27}{25} \right)^\ell = 2 }$

or equivalently,

$\displaystyle{ i \ln\left(\frac{25}{24}\right) + j \ln\left( \frac{135}{128} \right) + k \ln\left( \frac{16}{15} \right) + \ell \ln \left( \frac{27}{25} \right) = \ln 2 }$

The four numbers

$\ln\left(\frac{25}{24}\right), \ln\left( \frac{135}{128} \right),\ln\left( \frac{16}{15} \right), \ln \left( \frac{27}{25} \right)$

span the 3-dimensional rational vector space with basis $\ln 2, \ln 3, \ln 5,$ so they must obey one linear relation with integer coefficients (and others following from this one). This relation is

$\displaystyle{ \ln\left(\frac{25}{24}\right) + \ln \left( \frac{27}{25} \right) = \ln\left( \frac{135}{128} \right) + \ln\left( \frac{16}{15} \right) }$

This says cD = Cd: the lesser chromatic semitone followed by the large diatonic semitone takes you up to a frequency 9/8 higher, just like the greater chromatic semitone followed by the diatonic semitone.

This means that if a type $(i,j,k,\ell)$ is allowed, so is $(i+1,j-1,k-1,\ell+1)$ if $j-1,k-1 \ge 0.$ Furthermore, it means this move (and its inverse) can take you from any allowed type to all other allowed types.

So, let’s start with the type where $\ell,$ the number of large diatonic semitones, is as small as possible. This is our friend

(2,3,7,0)

We can get all other allowed types by repeatedly adding 1 to the first and last component of this vector and subtracting 1 from the other components. Thus, these are all the allowed types:

(2,3,7,0)
(3,2,6,1)
(4,1,5,2)
(5,0,4,3)

We can now use the methods of Puzzles 1 and 2 to count the scales of each type. We get:

$\displaystyle{ \frac{12!}{2! \cdot 3! \cdot 7! \cdot 0!} }$ = 7,920 scales of type (2,3,7,0).

$\displaystyle{ \frac{12!}{3! \cdot 2! \cdot 6! \cdot 1!} }$ = 55,440 scales of type (3,2,6,1).

$\displaystyle{ \frac{12!}{4! \cdot 1! \cdot 5! \cdot 2!} }$ = 83,160 scales of type (4,1,5,2).

$\displaystyle{ \frac{12!}{5! \cdot 0! \cdot 4! \cdot 3!} }$ = 27,720 scales of type (5,0,4,3).

So, we get a total of

7,920 + 55,440 + 83,160 + 27,720 = 174,240 scales. █

This is a ridiculously large number of scales! But of course, not all are equally good. Let’s impose some extra constraints.

The whole point of just intonation was to make the third equal to 5/4, and we also want to keep the fourth at 4/3 and the fifth at 3/2, as we had in Pythagorean tuning. When it comes to the second, either 10/9 or 9/8 are considered acceptable in just intonation. I like 9/8 a bit better, so let’s do this:

Puzzle 4. How many 12-tone scales are there where the spacing between each pair of successive notes is either a lesser chromatic semitone, a greater chromatic semitone, a diatonic semitone, a large diatonic semitone, and:

• the second is 9/8
• the third is 5/4
• the fourth is 4/3
• the fifth is 3/2?

Answer. With these constraints there are 1,600 allowed scales. The idea is this:

• There are 4 ways to go from 1 up to 9/8 in two semitones, since only Cd, dC, cD and Dc multiply to 9/8.

• There are 2 ways to go from 9/8 up to 5/4 in two semitones, since only cd and dc multiply to 10/9.

• There is 1 way to go from 5/4 up to 4/3, since d is 16/15.

• There are 4 ways to go from 4/3 up to 3/2, since only Cd, dC, cD and Dc multiply to 9/8.

• There are 500 ways to go from 3/2 to 2 in five steps. Here we need to count ordered quintuples of c, C, d and D that multiply to 4/3. I did this with a computer.

So, we get 4 × 2 × 1 × 4 × 500 = 1,600 scales of this sort. █

All these scales have the second being the greater major second, 9/8. But you might prefer the lesser major second, 10/9. So let’s think about that:

Puzzle 5. What about the same question as before, but where we constrain the second to be 10/9 instead of 9/8?

Answer. Again there are 1600 scales. In Puzzle 4 our scales went up from 1 to 9/8 by choosing two semitones that multiply to 9/8, and then from 9/8 to 5/4 by choosing two that multiply to 10/9. Now the only difference is that we’re going things in the other order: we’re going up from 1 to 10/9 by choosing two semitones that multiply to 10/9, and then from 10/9 to 5/4 by choosing two that multiply to 9/8. So the overall count is the same as before. █

Since they differ only by switching some semitones, the 1,600 scales with a greater major second have the same distribution of types as the 1,600 with a lesser major second. Using a computer, I calculated that in each case there are

• 160 of type (2,3,7,0)
• 560 of type (3,2,6,1)
• 640 of type (4,1,5,2)
• 240 of type (5,0,4,3).

How can we pick out a smaller number of ‘better’ scales? We’ve imposed a lot of constraints on the tones from the first to the fifth, but none on the tones above that. To impose constraints on the higher tones, we can demand that our scale be palindromic, except that we can’t require that the interval from the fourth to the tritone equals the interval from the tritone to the fifth, because $\sqrt{2}$ is irrational. So, I’ll call scales with the following properties nearly palindromic:

• the interval from 1 to ♭2 equals that from 7 to 8
• the interval from ♭2 to 2 equals that from ♭7 to 7
• the interval from 2 to ♭3 equals that from 6 to ♭7
• the interval from ♭3 to 3 equals that from ♭6 to 6
• the interval from 3 to 4 equals that from 5 to ♭6.

Puzzle 6. How many nearly palindromic 12-tone scales are there where the spacing between each pair of successive notes is either a lesser chromatic semitone, a greater chromatic semitone, a diatonic semitone, a large diatonic semitone, and:

• the second is 9/8
• the third is 5/4
• the fourth is 4/3?

Answer. There are 32 scales with these properties. First note that the above properties force other facts:

• the fifth is 3/4 × 2 = 3/2
• the minor sixth is 4/5 × 2 = 8/5
• the minor seventh is 8/9 × 2 = 16/9.

Thus, we have the following choices:

• There are 4 ways to go from 1 up to 9/8 in two semitones, since only Cd, dC, cD and Dc multiply to 9/8.

• There are 2 ways to go from 9/8 up to 5/4 in two semitones, since only cd and dc multiply to 10/9.

• There is 1 way to go from 5/4 up to 4/3, since d is 16/15.

• There are 4 ways to go from 4/3 up to 3/2, since only Cd, dC, cD and Dc multiply to 9/8.

and from then on, our choices are forced by the nearly palindromic nature of the scale.

There are thus a total of

4 × 2 × 1 × 4 = 32

choices. █

These 32 scales come in two kinds:

• the 16 scales discussed in Part 4, where the minor second is the diatonic semitone, d = 16/15

• 16 others, where the minor second is the greater chromatic semitone, C = 135/128.

Newton’s scale is of the first kind.

All 32 of these scales use the greater major second. A similar story holds with the lesser major second.

Puzzle 7. How many nearly palindromic 12-tone scales are there where the spacing between each pair of successive notes is either a lesser chromatic semitone, a greater chromatic semitone, a diatonic semitone, a large diatonic semitone, and:

• the second is 10/9
• the third is 5/4
• the fourth is 4/3?

Answer. By the symmetry we used to answer Puzzle 5, this question has the same answer as Puzzle 6: there are again 32 choices. █

These 32 scales again come in two kinds:

• 16 scales where the interval from the second to the minor third is the diatonic semitone, d = 16/15

• 16 others where the interval from the second to the minor third is the greater chromatic semitone, C = 135/128.

If you’ve made it this far, congratulations! I was lured in by how many famous mathematicians had studied this subject, and I wanted to join the fun.

For more on Pythagorean tuning, read this series:

• Pythagorean tuning.

For more on just intonation, read these:

• Part 1: The history of just intonation. Just intonation versus Pythagorean tuning. The syntonic comma.

• Part 2: Just intonation from the Tonnetz. The four possible tritones in just intonation. The small and large just whole tones. Ptolemy’s intense diatonic scale, and its major triads.

• Part 3: Curling up a parallelogram in the Tonnetz to get just intonation. The frequency ratios of the four possible tritones: the syntonic comma, the lesser and greater diesis, and the diaschisma.

• Part 4: Choices involved in just intonation. Two symmetrical 13-tone scales, and two 12-tone scales obtained from these by removing the diminished fifth. The four kinds of half-tone that appear in these scales: the diatonic, large diatonic, lesser chromatic and greater chromatic semitones.

• Part 5: Frequency ratios between the four possible tritones in just intonation, and how they are related to frequency ratios between the four kinds of half-tone. The syntonic comma, lesser and greater diesis, diaschisma, and the relations they obey.

• Part 6: Classifying all 174,240 12-tone scales where the intervals between successive notes are always diatonic, large diatonic, lesser chromatic and greater chromatic semitones. The scales of Isaac Newton, Nicolas Mercator, William Holder and Leonhard Euler.

For more on quarter-comma meantone tuning, read this series:

• Quarter-comma meantone.

For more on well-tempered scales, read this series:

• Well temperaments.

For more on equal temperament, read this series:

• Equal temperament.

by John Baez at December 30, 2025 05:10 PM

December 29, 2025

John Preskill — Quantum computing in the second quantum century

On December 10, I gave a keynote address at the Q2B 2025 Conference in Silicon Valley. This is a transcript of my remarks. The slides I presented are here.

The first century

We are nearing the end of the International Year of Quantum Science and Technology, so designated to commemorate the 100^th anniversary of the discovery of quantum mechanics in 1925. The story goes that 23-year-old Werner Heisenberg, seeking relief from severe hay fever, sailed to the remote North Sea Island of Helgoland, where a crucial insight led to his first, and notoriously obscure, paper describing the framework of quantum mechanics.

In the years following, that framework was clarified and extended by Heisenberg and others. Notably among them was Paul Dirac, who emphasized that we have a theory of almost everything that matters in everyday life. It’s the Schrödinger equation, which captures the quantum behavior of many electrons interacting electromagnetically with one another and with atomic nuclei. That describes everything in chemistry and materials science and all that is built on those foundations. But, as Dirac lamented, in general the equation is too complicated to solve for more than a few electrons.

Somehow, over 50 years passed before Richard Feynman proposed that if we want a machine to help us solve quantum problems, it should be a quantum machine, not a classical machine. The quest for such a machine, he observed, is “a wonderful problem because it doesn’t look so easy,” a statement that still rings true.

I was drawn into that quest about 30 years ago. It was an exciting time. Efficient quantum algorithms for the factoring and discrete log problems were discovered, followed rapidly by the first quantum error-correcting codes and the foundations of fault-tolerant quantum computing. By late 1996, it was firmly established that a noisy quantum computer could simulate an ideal quantum computer efficiently if the noise is not too strong or strongly correlated. Many of us were then convinced that powerful fault-tolerant quantum computers could eventually be built and operated.

Three decades later, as we enter the second century of quantum mechanics, how far have we come? Today’s quantum devices can perform some tasks beyond the reach of the most powerful existing conventional supercomputers. Error correction had for decades been a playground for theorists; now informative demonstrations are achievable on quantum platforms. And the world is investing heavily in advancing the technology further.

Current NISQ machines can perform quantum computations with thousands of two-qubit gates, enabling early explorations of highly entangled quantum matter, but still with limited commercial value. To unlock a wide variety of scientific and commercial applications, we need machines capable of performing billions or trillions of two-qubit gates. Quantum error correction is the way to get there.

I’ll highlight some notable developments over the past year—among many others I won’t have time to discuss. (1) We’re seeing intriguing quantum simulations of quantum dynamics in regimes that are arguably beyond the reach of classical simulations. (2) Atomic processors, both ion traps and neutral atoms in optical tweezers, are advancing impressively. (3) We’re acquiring a deeper appreciation of the advantages of nonlocal connectivity in fault-tolerant protocols. (4) And resource estimates for cryptanalytically relevant quantum algorithms have dropped sharply.

Quantum machines for science

A few years ago, I was not particularly excited about running applications on the quantum platforms that were then available; now I’m more interested. We have superconducting devices from IBM and Google with over 100 qubits and two-qubit error rates approaching 10^{-3}. The Quantinuum ion trap device has even better fidelity as well as higher connectivity. Neutral-atom processors have many qubits; they lag behind now in fidelity, but are improving.

Users face tradeoffs: The high connectivity and fidelity of ion traps is an advantage, but their clock speeds are orders of magnitude slower than for superconducting processors. That limits the number of times you can run a given circuit, and therefore the attainable statistical accuracy when estimating expectations of observables.

Verifiable quantum advantage

Much attention has been paid to sampling from the output of random quantum circuits, because this task is provably hard classically under reasonable assumptions. The trouble is that, in the high-complexity regime where a quantum computer can reach far beyond what classical computers can do, the accuracy of the quantum computation cannot be checked efficiently. Therefore, attention is now shifting toward verifiable quantum advantage — tasks where the answer can be checked. If we solved a factoring or discrete log problem, we could easily check the quantum computer’s output with a classical computation, but we’re not yet able to run these quantum algorithms in the classically hard regime. We might settle instead for quantum verification, meaning that we check the result by comparing two quantum computations and verifying the consistency of the results.

A type of classical verification of a quantum circuit was demonstrated recently by BlueQubit on a Quantinuum processor. In this scheme, a designer builds a family of so-called “peaked” quantum circuits such that, for each such circuit and for a specific input, one output string occurs with unusually high probability. An agent with a quantum computer who knows the circuit and the right input can easily identify the preferred output string by running the circuit a few times. But the quantum circuits are cleverly designed to hide the peaked output from a classical agent — one may argue heuristically that the classical agent, who has a description of the circuit and the right input, will find it hard to predict the preferred output. Thus quantum agents, but not classical agents, can convince the circuit designer that they have reliable quantum computers. This observation provides a convenient way to benchmark quantum computers that operate in the classically hard regime.

The notion of quantum verification was explored by the Google team using Willow. One can execute a quantum circuit acting on a specified input, and then measure a specified observable in the output. By repeating the procedure sufficiently many times, one obtains an accurate estimate of the expectation value of that output observable. This value can be checked by any other sufficiently capable quantum computer that runs the same circuit. If the circuit is strategically chosen, then the output value may be very sensitive to many-qubit interference phenomena, in which case one may argue heuristically that accurate estimation of that output observable is a hard task for classical computers. These experiments, too, provide a tool for validating quantum processors in the classical hard regime. The Google team even suggests that such experiments may have practical utility for inferring molecular structure from nuclear magnetic resonance data.

Correlated fermions in two dimensions

Quantum simulations of fermionic systems are especially compelling, since electronic structure underlies chemistry and materials science. These systems can be hard to simulate in more than one dimension, particularly in parameter regimes where fermions are strongly correlated, or in other words profoundly entangled. The two-dimensional Fermi-Hubbard model is a simplified caricature of two-dimensional materials that exhibit high-temperature superconductivity and hence has been much studied in recent decades. Large-scale tensor-network simulations are reasonably successful at capturing static properties of this model, but the dynamical properties are more elusive.

Dynamics in the Fermi-Hubbard model has been simulated recently on both Quantinuum (here and here) and Google processors. Only a 6 x 6 lattice of electrons was simulated, but this is already well beyond the scope of exact classical simulation. Comparing (error-mitigated) quantum circuits with over 4000 two-qubit gates to heuristic classical tensor-network and Majorana path methods, discrepancies were noted, and the Phasecraft team argues that the quantum simulation results are more trustworthy. The Harvard group also simulated models of fermionic dynamics, but were limited to relatively low circuit depths due to atom loss. It’s encouraging that today’s quantum processors have reached this interesting two-dimensional strongly correlated regime, and with improved gate fidelity and noise mitigation we can go somewhat further, but expanding system size substantially in digital quantum simulation will require moving toward fault-tolerant implementations. We should also note that there are analog Fermi-Hubbard simulators with thousands of lattice sites, but digital simulators provide greater flexibility in the initial states we can prepare, the observables we can access, and the Hamiltonians we can reach.

When it comes to many-particle quantum simulation, a nagging question is: “Will AI eat quantum’s lunch?” There is surging interest in using classical artificial intelligence to solve quantum problems, and that seems promising. How will AI impact our quest for quantum advantage in this problem space? This question is part of a broader issue: classical methods for quantum chemistry and materials have been improving rapidly, largely because of better algorithms, not just greater processing power. But for now classical AI applied to strongly correlated matter is hampered by a paucity of training data. Data from quantum experiments and simulations will likely enhance the power of classical AI to predict properties of new molecules and materials. The practical impact of that predictive power is hard to clearly foresee.

The need for fundamental research

Today is December 10^th, the anniversary of Alfred Nobel’s death. The Nobel Prize award ceremony in Stockholm concluded about an hour ago, and the Laureates are about to sit down for a well-deserved sumptuous banquet. That’s a fitting coda to this International Year of Quantum. It’s useful to be reminded that the foundations for today’s superconducting quantum processors were established by fundamental research 40 years ago into macroscopic quantum phenomena. No doubt fundamental curiosity-driven quantum research will continue to uncover unforeseen technological opportunities in the future, just as it has in the past.

I have emphasized superconducting, ion-trap, and neutral atom processors because those are most advanced today, but it’s vital to continue to pursue alternatives that could suddenly leap forward, and to be open to new hardware modalities that are not top-of-mind at present. It is striking that programmable, gate-based quantum circuits in neutral-atom optical-tweezer arrays were first demonstrated only a few years ago, yet that platform now appears especially promising for advancing fault-tolerant quantum computing. Policy makers should take note!

The joy of nonlocal connectivity

As the fault-tolerant era dawns, we increasingly recognize the potential advantages of the nonlocal connectivity resulting from atomic movement in ion traps and tweezer arrays, compared to geometrically local two-dimensional processing in solid-state devices. Over the past few years, many contributions from both industry and academia have clarified how this connectivity can reduce the overhead of fault-tolerant protocols.

Even when using the standard surface code, the ability to implement two-qubit logical gates transversally—rather than through lattice surgery—significantly reduces the number of syndrome-measurement rounds needed for reliable decoding, thereby lowering the time overhead of fault tolerance. Moreover, the global control and flexible qubit layout in tweezer arrays increase the parallelism available to logical circuits.

Nonlocal connectivity also enables the use of quantum low-density parity-check (qLDPC) codes with higher encoding rates, reducing the number of physical qubits needed per logical qubit for a target logical error rate. These codes now have acceptably high accuracy thresholds, practical decoders, and—thanks to rapid theoretical progress this year—emerging constructions for implementing universal logical gate sets. (See for example here, here, here, here.)

A serious drawback of tweezer arrays is their comparatively slow clock speed, limited by the timescales for atom transport and qubit readout. A millisecond-scale syndrome-measurement cycle is a major disadvantage relative to microsecond-scale cycles in some solid-state platforms. Nevertheless, the reductions in logical-gate overhead afforded by atomic movement can partially compensate for this limitation, and neutral-atom arrays with thousands of physical qubits already exist.

To realize the full potential of neutral-atom processors, further improvements are needed in gate fidelity and continuous atom loading to maintain large arrays during deep circuits. Encouragingly, active efforts on both fronts are making steady progress.

Approaching cryptanalytic relevance

Another noteworthy development this year was a significant improvement in the physical qubit count required to run a cryptanalytically relevant quantum algorithm, reduced by Gidney to less than 1 million physical qubits from the 20 million Gidney and Ekerå had estimated earlier. This applies under standard assumptions: a two-qubit error rate of 10^{-3} and 2D geometrically local processing. The improvement was achieved using three main tricks. One was using approximate residue arithmetic to reduce the number of logical qubits. (This also suppresses the success probability and therefore lengthens the time to solution by a factor of a few.) Another was using a more efficient scheme to reduce the number of physical qubits for each logical qubit in cold storage. And the third was a recently formulated scheme for reducing the spacetime cost of non-Clifford gates. Further cost reductions seem possible using advanced fault-tolerant constructions, highlighting the urgency of accelerating migration from vulnerable cryptosystems to post-quantum cryptography.

Looking forward

Over the next 5 years, we anticipate dramatic progress toward scalable fault-tolerant quantum computing, and scientific insights enabled by programmable quantum devices arriving at an accelerated pace. Looking further ahead, what might the future hold? I was intrigued by a 1945 letter from John von Neumann concerning the potential applications of fast electronic computers. After delineating some possible applications, von Neumann added: “Uses which are not, or not easily, predictable now, are likely to be the most important ones … they will … constitute the most surprising extension of our present sphere of action.” Not even a genius like von Neumann could foresee the digital revolution that lay ahead. Predicting the future course of quantum technology is even more hopeless because quantum information processing entails an even larger step beyond past experience.

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-particle systems, leading for example to transformative semiconductor and laser technologies. 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, behavior well beyond the scope of current theory or computation. The wonders we encounter in the second century of quantum mechanics, and their implications for human civilization, may far surpass those of the first century. So we should gratefully acknowledge the quantum pioneers of the past century, and wish good fortune to the quantum explorers of the future.

by preskill at December 29, 2025 04:42 PM

December 27, 2025

Tommaso Dorigo — A Great Year For Experiment Design

While 2025 will arguably not be remembered as a very positive year for humankind, for many reasons - first and foremost, raging wars and raising inequalities -, as we near its end some have tried to find good things to say about this particular revolution of our planet around the Sun.
And who am I to blow against the wind? I have to tell you, 2025 for me has been a formidable year. But before I go into a list of achievements, let me paint this rosy picture in broad strokes.

Professional achievements

by Tommaso Dorigo at December 27, 2025 06:29 PM

December 26, 2025

Matt von Hippel — For Newtonmas, One Seventeenth of a New Collider

Individual physicists don’t ask for a lot for Newtonmas. Big collaborations ask for more.

This year, CERN got its Newtonmas gift early: a one billion dollar pledge from a group of philanthropists and foundations, to be spent on their proposed new particle collider.

That may sound like a lot of money (and of course it is), but it’s only a fraction of the 15 billion euros that the collider is estimated to cost. That makes this less a case of private donors saving the project, and more of a nudge, showing governments they can get results for a bit cheaper than they expected.

I do wonder if the donation has also made CERN more bold about their plans, since it was announced shortly after a report from the update process for the European Strategy for Particle Physics, in which the European Strategy Group recommended a backup plan for the collider that is just the same collider with 15% budget cuts. Naturally people started making fun of this immediately.

There were more serious objections from groups that had proposed more specific backup plans earlier in the process, who are frustrated that their ideas were rejected in favor of a 15% tweak that was not even discussed and seems not to really have been evaluated.

I don’t have any special information about what’s going on behind the scenes, or where this is headed. But I’m amused, and having fun with the parallels this season. I remember writing lists as a kid, trying to take advantage of the once-a-year opportunity to get what seemed almost like a genie’s wish. Whatever my incantations, the unreasonable requests were never fulfilled. Still, I had enough new toys to fill my time, and whet my appetite for the next year.

We’ll see what CERN’s Newtonmas gift brings.

by 4gravitons at December 26, 2025 05:00 PM

December 25, 2025

Jordan Ellenberg — Merry Jewish Christmas!

The traditional celebration is Chinese food and a movie, so in that spirit: AB and I tried a new kind of dumpling on our recent trip to New York, sheng jian bao. These are soup dumplings, but with a thicker, crispier wrapper than the xiao long bao I’m more familiar with. Excellent!

As for a movie, we all re-watched Trading Places last night. Except it turns out Dr. Mrs. Q has never actually seen Trading Places! Arguably the very greatest Christmas movie.

by JSE at December 25, 2025 04:07 PM

Scott Aaronson My Christmas gift: telling you about PurpleMind, which brings CS theory to the YouTube masses

Merry Christmas, everyone! Ho³!

Here’s my beloved daughter baking chocolate chip cookies, which she’ll deliver tomorrow morning with our synagogue to firemen, EMTs, and others who need to work on Christmas Day. My role was limited to taste-testing.

While (I hope you’re sitting down for this) the Aaronson-Moshkovitzes are more of a latke/dreidel family, I grew up surrounded by Christmas and am a lifelong enjoyer of the decorations, the songs and movies (well, some of them), the message of universal goodwill, and even gingerbread and fruitcake.

Therefore, as a Christmas gift to my readers, I hereby present what I now regard as one of the great serendipitous “discoveries” in my career, alongside students like Paul Christiano and Ewin Tang who later became superstars.

Ever since I was a pimply teen, I dreamed of becoming the prophet who’d finally bring the glories of theoretical computer science to the masses—who’d do for that systematically under-sung field what Martin Gardner did for math, Carl Sagan for astronomy, Richard Dawkins for evolutionary biology, Douglas Hofstadter for consciousness and Gödel. Now, with my life half over, I’ve done … well, some in that direction, but vastly less than I’d dreamed.

A month ago, I learned that maybe I can rest easier. For a young man named Aaron Gostein is doing the work I wish I’d done—and he’s doing it using tools I don’t have, and so brilliantly that I could barely improve a pixel.

Aaron recently graduated from Carnegie Mellon, majoring in CS. He’s now moved back to Austin, TX, where he grew up, and where of course I now live as well. (Before anyone confuses our names: mine is Scott Aaronson, even though I’ve gotten hundreds of emails over the years calling me “Aaron.”)

Anyway, here in Austin, Aaron is producing a YouTube channel called PurpleMind. In starting this channel, Aaron was directly inspired by Grant Sanderson’s 3Blue1Brown—a math YouTube channel that I’ve also praised to the skies on this blog—but Aaron has chosen to focus on theoretical computer science.

I first encountered Aaron a month ago, when he emailed asking to interview me about … which topic will it be this time, quantum computing and Bitcoin? quantum computing and AI? AI and watermarking? no, diagonalization as a unifying idea in mathematical logic. That got my attention.

So Aaron came to my office and we talked for 45 minutes. I didn’t expect much to come of it, but then Aaron quickly put out this video, in which I have a few unimportant cameos:

After I watched this, I brought Dana and the kids and even my parents to watch it too. The kids, whose attention spans normally leave much to be desired, were sufficiently engaged that they made me pause every 15 seconds to ask questions (“what would go wrong if you diagonalized a list of all whole numbers, where we know there are only ℵ₀ of them?” “aren’t there other strategies that would work just as well as going down the diagonal?”).

Seeing this, I sat the kids down to watch more PurpleMind. Here’s the video on the P versus NP problem:

Here’s one on the famous Karatsuba algorithm, which reduced the number of steps needed to multiply two n-digit numbers from ~n² to only ~n^1.585, and thereby helped inaugurate the entire field of algorithms:

Here’s one on RSA encryption:

Here’s one on how computers quickly generate the huge random prime numbers that RSA and other modern encryption methods need:

These are the only ones we’ve watched so far. Each one strikes me as close to perfection. There are many others (for example, on Diffie-Hellman encryption, the Bernstein-Vazirani quantum algorithm, and calculating pi) that I’m guessing will be equally superb.

In my view, what makes these videos so good is their concreteness, achieved without loss of correctness. When, for example, Aaron talks about Gödel mailing a letter to the dying von Neumann posing what we now know as P vs. NP, or any other historical event, he always shows you an animated reconstruction. When he talks about an algorithm, he always shows you his own Python code, and what happened when he ran the code, and then he invites you to experiment with it too.

I might even say that the results singlehandedly justify the existence of YouTube, as the ten righteous men would’ve saved Sodom—with every crystal-clear animation of a CS concept canceling out a thousand unboxing videos or screamingly-narrated Minecraft play-throughs in the eyes of God.

Strangely, the comments below Aaron’s YouTube videos attack him relentlessly for his use of AI to help generate the animations. To me, it seems clear that AI is the only thing that could let one person, with no production budget to speak of, create animations of this quality and quantity. If people want so badly for the artwork to be 100% human-generated, let them volunteer to create it themselves.

Even as I admire the PurpleMind videos, or the 3Blue1Brown videos before them, a small part of me feels melancholic. From now until death, I expect that I’ll have only the same pedagogical tools that I acquired as a young’un: talking; waving my arms around; quizzing the audience; opening the floor to Q&A; cracking jokes; drawing crude diagrams on a blackboard or whiteboard until the chalk or the markers give out; typing English or LaTeX; the occasional PowerPoint graphic that might (if I’m feeling ambitious) fade in and out or fly across the screen.

Today there are vastly better tools, both human and AI, that make it feasible to create spectacular animations for each and every mathematical concept, as if transferring the imagery directly from mind to mind. In the hands of a master explainer like Grant Sanderson or Aaron Gostein, these tools are tractors to my ox-drawn plow. I’ll be unable to compete in the long term.

But then I reflect that at least I can help this new generation of math and CS popularizers, by continuing to feed them raw material. I can do cameos in their YouTube productions. Or if nothing else, I can bring their jewels to my community’s attention, as I’m doing right now.

Peace on Earth, and to all a good night.

by Scott at December 25, 2025 05:40 AM

December 24, 2025

Doug Natelson — Public comment period re US science, ends Dec 26

For those in the US: Here is a link for submitting a public comment regarding OSTP's request for information about "Accelerating the American Scientific Enterprise". The US government does this at some rate, requesting public feedback and input on policies under consideration or development. Unfortunately, this public comment period ends on December 26.

Here is the slightly longer version of what I submitted (I had to trim it back b/c of character limits). It doesn't touch on everything in the RFI, but it's a start. Many readers will likely disagree with what I wrote, and that's fine. Submit your own comments. Better that OSTP hear from a variety of perspectives.

Update: I’ve had some ask me what the point of this is, since the comments will likely not be read in a meaningful way. I assume they will feed the comments through an AI tool and have staffers spot check ones that are flagged as interesting (by whatever criteria). I know I’m old fashioned, but I still feel like silence is acquiescence edging toward complicity. Saying something at least helped me organize my ideas a bit.

----

I appreciate the desire and need to improve the American scientific enterprise. Other rival nations are making enormous investments in basic and applied scientific research, and it is critical for US competitiveness that the US not flag or falter.

I have two overarching suggestions before delving into the specific questions posed in the RFI.

First, it is of vital importance that the US scientific enterprise solicit advice and input from practicing scientists and engineers through advisory panels and committees. In the last year, the US government research agencies have dissolved or disbanded a huge fraction of advisory bodies. I think this is a mistake. While there are always concerns about whether experts are too entrenched to be bold, across-the-board devaluing expertise is not the way to go.

Second, there needs to be coherence between priorities and financial allocations. Complaining that the US is falling behind in critical research areas (e.g. advanced materials) while simultaneously slashing federal support of those research areas is both self-defeating and internally inconsistent. There have been large scale cuts across many agencies in critical scientific areas, seemingly at odds with the stated policies about innovation and competitiveness.

Regarding specific points from the RFI:

Encouraging public-private collaboration runs into the problem that existing economic incentives (the constant need for short-term returns) disfavor companies investing in research that doesn't have clear, nearly-immediate payoffs. Norm Augustine has spoken publicly about how opening a research laboratory caused Lockheed Martin's stock to fall. (see here: https://www.aaas.org/news/basic-research-needs-sustained-federal-investment-says-norman-augustine) Moreover, since many very wealthy corporations (e.g. Tesla, 3M) already pay almost no federal taxes, it is challenging to encourage public-private partnerships through offering companies tax incentives. The issue is less of a problem for small and startup companies, in part thanks to programs like SBIR and STTR. Programs like ARPA-E and ARPA-H also are important to consider and expand.

The most financially well-off sectors, all of which depend critically on a spectrum of research from basic to the applied and near to long term, are the financial industry, energy, biomedical/pharma, and tech/semiconductors (especially tied into AI). In the past, research consortia like International Sematech were very effective at guiding research of tremendous economic benefit. Some state governments have had interesting and impactful programs (e.g., the Cancer Prevention Research Institute in Texas, supported by state bonds). The US could encourage the development of industrial consortia aligned to specific aspects of research; these could be supported financially by joint investment of the constituting companies and special bond issues expressly for these topics, with the proviso that funds be used to support use-inspired basic and early-stage applied research. It is critical that any such plan have actual oversight, to make sure that this does not become a giant give-away to the companies that have the best lobbyists.

In terms of supporting models for research that complement traditional university structures and enable projects that require vast resources, interdisciplinary coordination, or extended timelines: There are already large-scale center/institute programs that have been deployed in the past by various federal agencies. While not perfect, these are not a bad model - in the last year, these have suffered greatly due to budgetary uncertainties and outright cancellations. You can't complain about failing to do research requiring extended timelines if funding is annualized and perpetually at risk. One approach to dealing with this would be to endow such structures at the outset for multiyear support. Congress would have to be willing to do this, and given the level of impasse that seems very difficult, but with executive branch support it could be possible. The short version: Don't complain about lack of long-term stickiness if the US government cannot be considered a reliable partner year over year.

In terms of identifying and developing scientific talent across the country: the RFI mentions "leveraging digital tools", which sounds a lot like trying to use AI to identify people. This is frought with risk. Programs such as the NSF graduate research fellowship, the NDSEG, the SCGSR, and others are essential at developing talent, as are many research experience for undergraduate programs and internship programs at national laboratories. The recent cuts to these programs are short-sighted and counterproductive. If we want the US to develop top technical talent and have people choose technical paths over "easier" trajectories, then we need to make it financially worthwhile for students to pursue these aims. Federally supported undergraduate scholarship, graduate fellowships, policies that reward companies for providing internships, policies that, e.g. reduce endowment taxes if university resources are spent providing such support, etc. are all worth considering. Again, an advisory task force could likely provide quantitative information about what strategies are likely to work best.

I could go on, but these are a starting point for a discussion. I would be happy to talk further with interested parties and engage in discussions going forward, if that would be helpful.

by Douglas Natelson at December 24, 2025 06:17 PM

December 23, 2025

Jordan Ellenberg — Self-portrait with about one quarter of Richard Serra’s sculpture Equal

by JSE at December 23, 2025 02:33 PM

December 22, 2025

Terence Tao — The story of Erdős problem #1026

Problem 1026 on the Erdős problem web site recently got solved through an interesting combination of existing literature, online collaboration, and AI tools. The purpose of this blog post is to try to tell the story of this collaboration, and also to supply a complete proof.

The original problem of Erdős, posed in 1975, is rather ambiguous. Erdős starts by recalling his famous theorem with Szekeres that says that given a sequence of ${k^2+1}$ distinct real numbers, one can find a subsequence of length ${k+1}$ which is either increasing or decreasing; and that one cannot improve the ${k^2+1}$ to ${k^2}$ , by considering for instance a sequence of ${k}$ blocks of length ${k}$ , with the numbers in each block decreasing, but the blocks themselves increasing. He also noted a result of Hanani that every sequence of length ${k(k+3)/2}$ can be decomposed into the union of ${k}$ monotone sequences. He then wrote “As far as I know the following question is not yet settled. Let ${x_1,\dots,x_n}$ be a sequence of distinct numbers, determine

$\displaystyle S(x_1,\dots,x_n) = \max \sum_r x_{i_r}$

where the maximum is to be taken over all monotonic sequences ${x_{i_1},\dots,x_{i_m}}$ “.

This problem was added to the Erdős problem site on September 12, 2025, with a note that the problem was rather ambiguous. For any fixed ${n}$ , this is an explicit piecewise linear function of the variables ${x_1,\dots,x_n}$ that could be computed by a simple brute force algorithm, but Erdős was presumably seeking optimal bounds for this quantity under some natural constraint on the ${x_i}$ . The day the problem was posted, Desmond Weisenberg proposed studying the quantity ${c(n)}$ , defined as the largest constant such that

$\displaystyle S(x_1,\dots,x_n) \geq c(n) \sum_{i=1}^n x_i$

for all choices of (distinct) real numbers ${x_1,\dots,x_n}$ . Desmond noted that for this formulation one could assume without loss of generality that the ${x_i}$ were positive, since deleting negative or vanishing ${x_i}$ does not increase the left-hand side and does not decrease the right-hand side. By a limiting argument one could also allow collisions between the ${x_i}$ , so long as one interpreted monotonicity in the weak sense.

Though not stated on the web site, one can formulate this problem in game theoretic terms. Suppose that Alice has a stack of ${N}$ coins for some large ${N}$ . She divides the coins into ${n}$ piles of consisting of ${x_1,\dots,x_n}$ coins each, so that ${\sum_{i=1}^n x_i = N}$ . She then passes the piles to Bob, who is allowed to select a monotone subsequence of the piles (in the weak sense) and keep all the coins in those piles. What is the largest fraction ${c(n)}$ of the coins that Bob can guarantee to keep, regardless of how Alice divides up the coins? (One can work with either a discrete version of this problem where the ${x_i}$ are integers, or a continuous one where the coins can be split fractionally, but in the limit ${N \rightarrow \infty}$ the problems can easily be seen to be equivalent.)

AI-generated images continue to be problematic for a number of reasons, but here is one such image that somewhat manages at least to convey the idea of the game:

For small ${n}$ , one can work out ${c(n)}$ by hand. For ${n=1}$ , clearly ${c(1)=1}$ : Alice has to put all the coins into one pile, which Bob simply takes. Similarly ${c(2)=1}$ : regardless of how Alice divides the coins into two piles, the piles will either be increasing or decreasing, so in either case Bob can take both. The first interesting case is ${n=3}$ . Bob can again always take the two largest piles, guaranteeing himself ${2/3}$ of the coins. On the other hand, if Alice almost divides the coins evenly, for instance into piles ${((1/3 + \varepsilon)N, (1/3-2\varepsilon) N, (1/3+\varepsilon)N)}$ for some small ${\varepsilon>0}$ , then Bob cannot take all three piles as they are non-monotone, and so can only take two of them, allowing Alice to limit the payout fraction to be arbitrarily close to ${2/3}$ . So we conclude that ${c(3)=2/3}$ .

An hour after Desmond’s comment, Stijn Cambie noted (though not in the language I used above) that a similar construction to the one above, in which Alice divides the coins into ${k^2}$ pairs that are almost even, in such a way that the longest monotone sequence is of length ${k}$ , gives the upper bound ${c(k^2) \leq 1/k}$ . It is also easy to see that ${c(n)}$ is a non-increasing function of ${n}$ , so this gives a general bound ${c(n) \leq (1+o(1))/\sqrt{n}}$ . Less than an hour after that, Wouter van Doorn noted that the Hanani result mentioned above gives the lower bound ${c(n) \geq (\frac{1}{\sqrt{2}}-o(1))/\sqrt{n}}$ , and posed the problem of determining the asymptotic limit of ${\sqrt{n} c(n)}$ as ${n \rightarrow \infty}$ , given that this was now known to range between ${1/\sqrt{2}-o(1)}$ and ${1+o(1)}$ . This version was accepted by Thomas Bloom, the moderator of the Erdős problem site, as a valid interpretation of the original problem.

The next day, Stijn computed the first few values of ${c(n)}$ exactly:

$\displaystyle 1, 1, 2/3, 1/2, 1/2, 3/7, 2/5, 3/8, 1/3.$

While the general pattern was not yet clear, this was enough data for Stijn to conjecture that ${c(k^2)=1/k}$ , which would also imply that ${\sqrt{n} c(n) \rightarrow 1}$ as ${n \rightarrow \infty}$ . (EDIT: as later located by an AI deep research tool, this conjecture was also made in Section 12 of this 1980 article of Steele.) Stijn also described the extremizing sequences for this range of ${n}$ , but did not continue the calculation further (a naive computation would take runtime exponential in ${n}$ , due to the large number of possible subsequences to consider).

The problem then lay dormant for almost two months, until December 7, 2025, in which Boris Alexeev, as part of a systematic sweep of the Erdős problems using the AI tool Aristotle, was able to get this tool to autonomously solve this conjecture ${c(k^2)=1/k}$ in the proof assistant language Lean. The proof converted the problem to a rectangle-packing problem.

This was one further addition to a recent sequence of examples where an Erdős problem had been automatically solved in one fashion or another by an AI tool. Like the previous cases, the proof turned out to not be particularly novel. Within an hour, Koishi Chan gave an alternate proof deriving the required bound ${c(k^2) \geq 1/k}$ from the original Erdős-Szekeres theorem by a standard “blow-up” argument which we can give here in the Alice-Bob formulation. Take a large ${M}$ , and replace each pile of ${x_i}$ coins with ${(1+o(1)) M^2 x_i^2}$ new piles, each of size ${(1+o(1)) x_i}$ , chosen so that the longest monotone subsequence in this collection is ${(1+o(1)) M x_i}$ . Among all the new piles, the longest monotone subsequence has length ${(1+o(1)) M S(x_1,\dots,x_n)}$ . Applying Erdős-Szekeres, one concludes the bound

$\displaystyle M S(x_1,\dots,x_n) \geq (1-o(1)) (\sum_{i=1}^{k^2} M^2 x_i^2)^{1/2}$

and on canceling the ${M}$ ‘s, sending ${M \rightarrow \infty}$ , and applying Cauchy-Schwarz, one obtains ${c(k^2) \geq 1/k}$ (in fact the argument gives ${c(n) \geq 1/\sqrt{n}}$ for all ${n}$ ).

Once this proof was found, it was natural to try to see if it had already appeared in the literature. AI deep research tools have successfully located such prior literature in the past, but in this case they did not succeed, and a more “old-fashioned” Google Scholar job turned up some relevant references: a 2016 paper by Tidor, Wang and Yang contained this precise result, citing an earlier paper of Wagner as inspiration for applying “blowup” to the Erdős-Szekeres theorem.

But the story does not end there! Upon reading the above story the next day, I realized that the problem of estimating ${c(n)}$ was a suitable task for AlphaEvolve, which I have used recently as mentioned in this previous post. Specifically, one could task to obtain upper bounds on ${c(n)}$ by directing it to produce real numbers (or integers) ${x_1,\dots,x_n}$ summing up to a fixed sum (I chose ${10^6}$ ) with a small a value of ${S(x_1,\dots,x_n)}$ as possible. After an hour of run time, AlphaEvolve produced the following upper bounds on ${c(n)}$ for ${1 \leq n \leq 16}$ , with some intriguingly structured potential extremizing solutions:

The numerical scores (divided by ${10^6}$ ) were pretty obviously trying to approximate simple rational numbers. There were a variety of ways (including modern AI) to extract the actual rational numbers they were close to, but I searched for a dedicated tool and found this useful little web page of John Cook that did the job:

$\displaystyle 1, 1, 2/3, 1/2, 1/2, 3/7, 2/5, 3/8, 1/3, 1/4.$

$\displaystyle 1/3, 4/13, 3/10, 4/14, 3/11, 4/15, 1/4.$

I could not immediately see the pattern here, but after some trial and error in which I tried to align numerators and denominators, I eventually organized this sequence into a more suggestive form:

$\displaystyle 1,$

$\displaystyle 1/1, \mathbf{2/3}, 1/2,$

$\displaystyle 2/4, \mathbf{3/7}, 2/5, \mathbf{3/8}, 2/6,$

$\displaystyle 3/9, \mathbf{4/13}, 3/10, \mathbf{4/14}, 3/11, \mathbf{4/15}, 3/12.$

This gave a somewhat complicated but predictable conjecture for the values of the sequence ${c(n)}$ . On posting this, Boris found a clean formulation of the conjecture, namely that

$\displaystyle c(k^2 + 2a + 1) = \frac{k}{k^2+a} \ \ \ \ \ (1)$

whenever ${k \geq 1}$ and ${-k \leq a \leq k}$ . After a bit of effort, he also produced an explicit upper bound construction:

Proposition 1 If ${k \geq 1}$ and ${-k \leq a \leq k}$ , then ${c(k^2+2a+1) \leq \frac{k}{k^2+a}}$ .

Proof: Consider a sequence ${x_1,\dots,x_{k^2+2a+1}}$ of numbers clustered around the “red number” ${|a|}$ and “blue number” ${|a+1|}$ , consisting of ${|a|}$ blocks of ${k-|a|}$ “blue” numbers, followed by ${|a+1|}$ blocks of ${|a+1|}$ “red” numbers, and then ${k-|a|}$ further blocks of ${k}$ “blue” numbers. When ${a \geq 0}$ , one should take all blocks to be slightly decreasing within each block, but the blue blocks should be are increasing between each other, and the red blocks should also be increasing between each other. When ${a < 0}$ , all of these orderings should be reversed. The total number of elements is indeed

$\displaystyle |a| \times (k-|a|) + |a+1| \times |a+1| + (k-|a|) \times k$

$\displaystyle = k^2 + 2a + 1$

and the total sum is close to

$\displaystyle |a| \times (k-|a|) \times |a+1| + |a+1| \times |a+1| \times |a|$

$+ (k-|a|) \times k \times |a+1| = (k^2 + a) |a+1|.$

With this setup, one can check that any monotone sequence consists either of at most ${|a+1|}$ red elements and at most ${k-|a|}$ blue elements, or no red elements and at most ${k}$ blue elements, in either case giving a monotone sum that is bounded by either

$\displaystyle |a+1| \times |a| + (k-|a|) \times |a+1| = k |a+1|$

$\displaystyle 0 + k \times |a+1| = k |a+1|,$

giving the claim. $\Box$

Here is a figure illustrating the above construction in the ${a \geq 0}$ case (obtained after starting with a ChatGPT-provided file and then manually fixing a number of placement issues):

Here is a plot of $1/c(n)$ (produced by ChatGPT Pro), showing that it is basically a piecewise linear approximation to the square root function:

Shortly afterwards, Lawrence Wu clarified the connection between this problem and a square packing problem, which was also due to Erdős (Problem 106). Let ${f(n)}$ be the least number such that, whenever one packs ${n}$ squares of sidelength ${d_1,\dots,d_n}$ into a square of sidelength ${D}$ , with all sides parallel to the coordinate axes, one has

$\displaystyle \sum_{i=1}^n d_i \leq f(n) D.$

Proposition 2 For any ${n}$ , one has
$\displaystyle c(n) \geq \frac{1}{f(n)}.$

Proof: Given ${x_1,\dots,x_n}$ and ${1 \leq i \leq n}$ , let ${S_i}$ be the maximal sum over all increasing subsequences ending in ${x_i}$ , and ${T_i}$ be the maximal sum over all decreasing subsequences ending in ${x_i}$ . For ${i < j}$ , we have either ${S_j \geq S_i + x_j}$ (if ${x_j \geq x_i}$ ) or ${T_j \geq T_i + x_j}$ (if ${x_j \leq x_i}$ ). In particular, the squares ${(S_i-x_i, T_i-x_i)}$ and ${(S_j-x_j, T_j-x_j)}$ are disjoint. These squares pack into the square ${[0, S(x_1,\dots,x_n)]^2}$ , so by definition of ${f}$ , we have

$\displaystyle \sum_{i=1}^n x_i \leq f(n) S(x_1,\dots,x_n),$

and the claim follows. $\Box$

This idea of using packing to prove Erdős-Szekeres type results goes back to a 1959 paper of Seidenberg, although it was a discrete rectangle-packing argument that was not phrased in such an elegantly geometric form. It is possible that Aristotle was “aware” of the Seidenberg argument via its training data, as it had incorporated a version of this argument in its proof.

Here is an illustration of the above argument using the AlphaEvolve-provided example

$\displaystyle[99998, 99997, 116305, 117032, 116304,$

$\displaystyle 58370, 83179, 117030, 92705, 99080]$

for $n=10$ to convert it to a square packing (image produced by ChatGPT Pro):

At this point, Lawrence performed another AI deep research search, this time successfully locating a paper from just last year by Baek, Koizumi, and Ueoro, where they show that

Theorem 3 For any ${k \geq 1}$ , one has
$\displaystyle f(k^2+1) \leq k$

which, when combined with a previous argument of Praton, implies

Theorem 4 For any ${k \geq 1}$ and ${c \in {\bf Z}}$ with ${k^2+2c+1 \geq 1}$ , one has
$\displaystyle f(k^2+2c+1) \leq k + \frac{c}{k}.$

This proves the conjecture!

There just remained the issue of putting everything together. I did feed all of the above information into a large language model, which was able to produce a coherent proof of (1) assuming the results of Baek-Koizumi-Ueoro and Praton. Of course, LLM outputs are prone to hallucination, so it would be preferable to formalize that argument in Lean, but this looks quite doable with current tools, and I expect this to be accomplished shortly. But I was also able to reproduce the arguments of Baek-Koizumi-Ueoro and Praton, which I include below for completeness.

Proof: (Proof of Theorem 3, adapted from Baek-Koizumi-Ueoro) We can normalize ${D=k}$ . It then suffices to show that if we pack the length ${k}$ torus ${({\bf Z}/k{\bf Z})^2}$ by ${k^2+1}$ axis-parallel squares of sidelength ${d_1,\dots,d_{k^2+1}}$ , then

$\displaystyle \sum_{i=1}^{k^2+1} d_i \leq k^2.$

Pick ${x_0, y_0 \in {\bf R}/k{\bf Z}}$ . Then we have a ${k \times k}$ grid

$\displaystyle (x_0 + {\bf Z}) \times (y_0 + {\bf Z}) \pmod {k{\bf Z}^2}$

inside the torus. The ${i^{th}}$ square, when restricted to this grid, becomes a discrete rectangle ${A_{i,x_0} \times B_{i,y_0}}$ for some finite sets ${A_{i,x_0}, B_{i,y_0}}$ with

$\displaystyle |\# A_{i,x_0} -\# B_{i,y_0}| \leq 1. \ \ \ \ \ (2)$

By the packing condition, we have

$\displaystyle \sum_{i=1}^{k^2+1} \# A_{i,x_0} \# B_{i,y_0} \leq k^2.$

From (2) we have

$\displaystyle (\# A_{i,x_0} - 1) (\# B_{i,y_0} - 1) \geq 0$

hence

$\displaystyle \# A_{i,x_0} \# B_{i,y_0} \geq \# A_{i,x_0} + \# B_{i,y_0} - 1.$

Inserting this bound and rearranging, we conclude that

$\displaystyle \sum_{i=1}^{k^2+1} \# A_{i,x_0} + \sum_{i=1}^{k^2+1} \# B_{i,y_0} \leq 2k^2 + 1.$

Taking the supremum over ${x_0,y_0}$ we conclude that

$\displaystyle \sup_{x_0} \sum_{i=1}^{k^2+1} \# A_{i,x_0} + \sup_{y_0} \sum_{i=1}^{k^2+1} \# B_{i,y_0} \leq 2k^2 + 1$

so by the pigeonhole principle one of the summands is at most ${k^2}$ . Let’s say it is the former, thus

$\displaystyle \sup_{x_0} \sum_{i=1}^{k^2+1} \# A_{i,x_0} \leq k^2.$

In particular, the average value of ${\sum_{i=1}^{k^2+1} \# A_{i,x_0}}$ is at most ${k^2}$ . But this can be computed to be ${\sum_{i=1}^{k^2+1} d_i}$ , giving the claim. Similarly if it is the other sum. $\Box$

UPDATE: Actually, the above argument also proves Theorem 4 with only minor modifications. Nevertheless, we give the original derivation of Theorem 4 using the embedding argument of Praton below for sake of completeness.

Proof: (Proof of Theorem 4, adapted from Praton) We write ${c = \epsilon |c|}$ with ${\epsilon = \pm 1}$ . We can rescale so that the square one is packing into is ${[0,k]^2}$ . Thus, we pack ${k^2+2\varepsilon |c|+1}$ squares of sidelength ${d_1,\dots,d_{k^2+2\varepsilon |c|+1}}$ into ${[0,k]^2}$ , and our task is to show that

$\displaystyle \sum_{i=1}^{k^2+2\varepsilon|c|+1} d_i \leq k^2 + \varepsilon |c|.$

We pick a large natural number ${N}$ (in particular, larger than ${k}$ ), and consider the three nested squares

$\displaystyle [0,k]^2 \subset [0,N]^2 \subset [0,N + |c| \frac{N}{N-\varepsilon}]^2.$

We can pack ${[0,N]^2 \backslash [0,k]^2}$ by ${N^2-k^2}$ unit squares. We can similarly pack

$\displaystyle [0,N + |c| \frac{N}{N-\varepsilon}]^2 \backslash [0,N]^2$

$\displaystyle =[0, \frac{N}{N-\varepsilon} (N+|c|-\varepsilon)]^2 \backslash [0, \frac{N}{N-\varepsilon} (N-\varepsilon)]^2$

into ${(N+|c|-\varepsilon)^2 - (N-\varepsilon)^2}$ squares of sidelength ${\frac{N}{N-\varepsilon}}$ . All in all, this produces

$\displaystyle k^2+2\varepsilon |c|+1 + N^2-k^2 + (N+|c|-\varepsilon)^2 - (N-\varepsilon)^2$

$\displaystyle = (N+|c|)^2 + 1$

squares, of total length

$\displaystyle (\sum_{i=1}^{k^2+2\varepsilon |c|+1} d_i) +(N^2-k^2) + ((N+|c|-\varepsilon)^2 - (N-\varepsilon)^2) \frac{N}{N-\varepsilon}.$

Applying Theorem 3, we conclude that

$\displaystyle (\sum_{i=1}^{k^2+2\varepsilon |c|+1} d_i) +(N^2-k^2)$

$\displaystyle + ((N+|c|-\varepsilon)^2 - (N-\varepsilon)^2) \frac{N}{N-\varepsilon} \leq (N+|c|) (N + |c| \frac{N}{N-\varepsilon}).$

The right-hand side is

$\displaystyle N^2 + 2|c| N + |c|^2 + \varepsilon |c| + O(1/N)$

and the left-hand side similarly evaluates to

$\displaystyle (\sum_{i=1}^{k^2+2c+1} d_i) + N^2 -k^2 + 2|c| N + |c|^2 + O(1/N)$

and so we simplify to

$\displaystyle \sum_{i=1}^{k^2+2\varepsilon |c|+1} d_i \leq k^2 + \varepsilon |c| + O(1/N).$

Sending ${N \rightarrow \infty}$ , we obtain the claim. $\Box$

One striking feature of this story for me is how important it was to have a diverse set of people, literature, and tools to attack this problem. To be able to state and prove the precise formula for ${c(n)}$ required multiple observations, including some version of the following:

The sequence can be numerically computed as a sequence of rational numbers.
When appropriately normalized and arranged, visible patterns in this sequence appear that allow one to conjecture the form of the sequence.
This problem is a weighted version of the Erdős-Szekeres theorem.
Among the many proofs of the Erdős-Szekeres theorem is the proof of Seidenberg in 1959, which can be interpreted as a discrete rectangle packing argument.
This problem can be reinterpreted as a continuous square packing problem, and in fact is closely related to (a generalized axis-parallel form of) Erdős problem 106, which concerns such packings.
The axis-parallel form of Erdős problem 106 was recently solved by Baek-Koizumi-Ueoro.
The paper of Praton shows that Erdős Problem 106 implies the generalized version needed for this problem. This implication specializes to the axis-parallel case.

It was only through the combined efforts of all the contributors and their tools that all these key inputs were able to be assembled within 48 hours. It seems plausible that a more traditional effort involving just one or two mathematicians and simpler programming and literature search tools may eventually have been able to put all these pieces together, but I believe this process would have taken much longer (on the order of weeks or even months).

Another key ingredient was the balanced AI policy on the Erdős problem website, which encourages disclosed AI usage while strongly discouraging undisclosed use. To quote from that policy: “Comments prepared with the assistance of AI are permitted, provided (a) this is disclosed, (b) the contents (including mathematics, code, numerical data, and the existence of relevant sources) have been carefully checked and verified by the user themselves without the assistance of AI, and (c) the comment is not unreasonably long.”

by Terence Tao at December 22, 2025 05:44 PM

December 21, 2025

John Baez — Formal Scientific Modeling

In January I’m going to a workshop on category theory for modeling, with a focus on epidemiology.

• Formal scientific modeling: a case study in global health, 2026 January 12-16, American Institute of Mathematics, Pasadena, California. Organized by Nina Fefferman, Tim Hosgood, and Mary Lou Zeeman.

It’s sponsored by American Institute of Mathematics, the NSF, the Topos Institute, and the US NSF Center for Analysis and Prediction of Pandemic Expansion. Here are some of the goals:

1. Get a written problem list from a bunch of modelling experts, i.e. statements of the form “I’ll be interested in categorical approaches to modelling when they can do X”, or “how would category theory think about this specific dynamical behaviour, or is this actually not a category theory question at all?”, or … and so on.

2. Make academic friends. There will be people who are not at all category theorists (many of them haven’t even heard of the subject) but who have elected to spend 5 days at a working conference to actually work with some category theorists.

3. There will probably be a lot of conversations that are essentially 5–15 minute speed tutorials in “what is agro-ecology”, or “how do diabetes models work”, or “what does it mean to implement climate databases in a non-trivial way”.

I think looking at examples of existing successful collaborations between category theorists and modelers will help this meeting work better. I’m hoping to give a little talk about the one I’ve been involved in.

I really had very little idea how category theory could actually help modelers until Nate Osgood, Xiaoyan Li, Kris Brown, Evan Patterson and I spent about 5 years thinking about it. We used category theory to develop radically new software for modeling in epidemiology. It was crucial that Nate and Xiaoyan do modeling for a living, while Kris and Evan design category-based software for a living. And it was crucial that we worked together for a long, long time.

But I’m hoping that what we learned can help future collaborations. I’ve written up a few insights here:

• Applied category theory for modeling.

by John Baez at December 21, 2025 11:34 PM

Scott Aaronson More on whether useful quantum computing is “imminent”

These days, the most common question I get goes something like this:

A decade ago, you told people that scalable quantum computing wasn’t imminent. Now, though, you claim it plausibly is imminent. Why have you reversed yourself??

I appreciated the friend of mine who paraphrased this as follows: “A decade ago you said you were 35. Now you say you’re 45. Explain yourself!”

A couple weeks ago, I was delighted to attend Q2B in Santa Clara, where I gave a keynote talk entitled “Why I Think Quantum Computing Works” (link goes to the PowerPoint slides). This is one of the most optimistic talks I’ve ever given. But mostly that’s just because, uncharacteristically for me, here I gave short shrift to the challenge of broadening the class of problems that achieve huge quantum speedups, and just focused on the experimental milestones achieved over the past year. With every experimental milestone, the little voice in my head that asks “but what if Gil Kalai turned out to be right after all? what if scalable QC wasn’t possible?” grows quieter, until now it can barely be heard.

Going to Q2B was extremely helpful in giving me a sense of the current state of the field. Ryan Babbush gave a superb overview (I couldn’t have improved a word) of the current status of quantum algorithms, while John Preskill’s annual where-we-stand talk was “magisterial” as usual (that’s the word I’ve long used for his talks), making mine look like just a warmup act for his. Meanwhile, Quantinuum took a victory lap, boasting of their recent successes in a way that I considered basically justified.

After returning from Q2B, I then did an hour-long podcast with “The Quantum Bull” on the topic “How Close Are We to Fault-Tolerant Quantum Computing?” You can watch it here:

As far as I remember, this is the first YouTube interview I’ve ever done that concentrates entirely on the current state of the QC race, skipping any attempt to explain amplitudes, interference, and other basic concepts. Despite (or conceivably because?) of that, I’m happy with how this interview turned out. Watch if you want to know my detailed current views on hardware—as always, I recommend 2x speed.

Or for those who don’t have the half hour, a quick summary:

In quantum computing, there are the large companies and startups that might succeed or might fail, but are at least trying to solve the real technical problems, and some of them are making amazing progress. And then there are the companies that have optimized for doing IPOs, getting astronomical valuations, and selling a narrative to retail investors and governments about how quantum computing is poised to revolutionize optimization and machine learning and finance. Right now, I see these two sets of companies as almost entirely disjoint from each other.
The interview also contains my most direct condemnation yet of some of the wild misrepresentations that IonQ, in particular, has made to governments about what QC will be good for (“unlike AI, quantum computers won’t hallucinate because they’re deterministic!”)
The two approaches that had the most impressive demonstrations in the past year are trapped ions (especially Quantinuum but also Oxford Ionics) and superconducting qubits (especially Google but also IBM), and perhaps also neutral atoms (especially QuEra but also Infleqtion and Atom Computing).
Contrary to a misconception that refuses to die, I haven’t dramatically changed my views on any of these matters. As I have for a quarter century, I continue to profess a lot of confidence in the basic principles of quantum computing theory worked out in the mid-1990s, and I also continue to profess ignorance of exactly how many years it will take to realize those principles in the lab, and of which hardware approach will get there first.
But yeah, of course I update in response to developments on the ground, because it would be insane not to! And 2025 was clearly a year that met or exceeded my expectations on hardware, with multiple platforms now boasting >99.9% fidelity two-qubit gates, at or above the theoretical threshold for fault-tolerance. This year updated me in favor of taking more seriously the aggressive pronouncements—the “roadmaps”—of Google, Quantinuum, QuEra, PsiQuantum, and other companies about where they could be in 2028 or 2029.
One more time for those in the back: the main known applications of quantum computers remain (1) the simulation of quantum physics and chemistry themselves, (2) breaking a lot of currently deployed cryptography, and (3) eventually, achieving some modest benefits for optimization, machine learning, and other areas (but it will probably be a while before those modest benefits win out in practice). To be sure, the detailed list of quantum speedups expands over time (as new quantum algorithms get discovered) and also contracts over time (as some of the quantum algorithms get dequantized). But the list of known applications “from 30,000 feet” remains fairly close to what it was a quarter century ago, after you hack away the dense thickets of obfuscation and hype.

I’m going to close this post with a warning. When Frisch and Peierls wrote their now-famous memo in March 1940, estimating the mass of Uranium-235 that would be needed for a fission bomb, they didn’t publish it in a journal, but communicated the result through military channels only. As recently as February 1939, Frisch and Meitner had published in Nature their theoretical explanation of recent experiments, showing that the uranium nucleus could fission when bombarded by neutrons. But by 1940, Frisch and Peierls realized that the time for open publication of these matters had passed.

Similarly, at some point, the people doing detailed estimates of how many physical qubits and gates it’ll take to break actually deployed cryptosystems using Shor’s algorithm are going to stop publishing those estimates, if for no other reason than the risk of giving too much information to adversaries. Indeed, for all we know, that point may have been passed already. This is the clearest warning that I can offer in public right now about the urgency of migrating to post-quantum cryptosystems, a process that I’m grateful is already underway.

Update: Someone on Twitter who’s “long $IONQ” says he’ll be posting about and investigating me every day, never resting until UT Austin fires me, in order to punish me for slandering IonQ and other “pure play” SPAC IPO quantum companies. And also, because I’ve been anti-Trump and pro-Biden. He confabulates that I must be trying to profit from my stance (eg by shorting the companies I criticize), it being inconceivable to him that anyone would say anything purely because they care about what’s true.

by Scott at December 21, 2025 10:08 PM

n-Category Café Octonions and the Standard Model (Part 13)

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

When Lee and Yang suggested that the laws of physics might not be invariant under spatial reflection — that there’s a fundamental difference between left and right — Pauli was skeptical. In a letter to Victor Weisskopf in January 1957, he wrote:

“Ich glaube aber nicht, daß der Herrgott ein schwacher Linkshänder ist.”

(I do not believe that the Lord is a weak left-hander.)

But just two days after Pauli wrote this letter, Chien-Shiung Wu’s experiment confirmed that Lee and Yang were correct. There’s an inherent asymmetry in nature.

We can trace this back to how the ‘left-handed’ fermions and antifermions live in a different representation of the Standard Model gauge group than the right-handed ones. And when we try to build grand unified theories that take this into account, we run into the fact that while we can fit the Standard Model gauge group into $\text{Spin}(10)$ in various ways, not all these ways produce the required asymmetry. There’s a way where it fits into $\text{Spin}(9)$ , which is too symmetrical to work… and alas, this one has a nice octonionic description!

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

To keep things simple I’ll explain this by focusing, not on the whole Standard Model gauge group, but its subgroup $\text{SU}(2) \times \text{SU}(3)$ . Here is a theorem proved by Will Sawin in response to a question of mine on MathOverflow:

Theorem 10. There are exactly two conjugacy classes of subgroups of $\text{Spin}(10)$ that are isomorphic to $\text{SU}(2) \times \text{SU}(3)$ . One of them has a representative that is a subgroup of $\text{Spin}(9) \subset \text{Spin}(10)$ , while the other does not.

I’ll describe representatives of these two subgroups; then I’ll say a bit about how they show up in physics, and then I’ll show you Sawin’s proof.

We can get both subgroups in a unified way! There’s always an inclusion

$\text{SO}(m) \times \text{SO}(n) \to \text{SO}(m+n)$

and taking double covers of each group we get a 2-1 homomorphism

$\text{Spin}(m) \times \text{Spin}(n) \to \text{Spin}(m+n)$

In particular we have

$\text{Spin}(4) \times \text{Spin}(6) \to \text{Spin}(10)$

so composing with the exceptional isomorphisms:

$\text{Spin}(4) \cong \text{SU}(2) \times \text{SU}(2), \qquad \text{Spin}(6) \cong \text{SU}(4)$

we get a 2-1 homomorphism

$k \colon \text{SU}(2) \times \text{SU}(2) \times \text{SU}(4) \to \text{Spin}(10)$

Now, there are three obvious ways to include $\text{SU}(2) \times \text{SU}(3)$ in $\text{SU}(2) \times \text{SU}(2) \times \text{SU}(4)$ . There is an obvious inclusion

$j \colon \text{SU}(3) \hookrightarrow \text{SU}(4)$

but there are three obvious inclusions

$\ell, r, \delta \colon \text{SU}(2) \hookrightarrow \text{SU}(2) \times \text{SU}(2)$

namely the left one:

$\begin{array}{ccc} \ell \colon \text{SU}(2) &\to& \text{SU}(2) \times \text{SU}(2) \\ g & \mapsto & (g,1) \end{array}$

the right one:

$\begin{array}{ccc} r \colon \text{SU}(2) &\to& \text{SU}(2) \times \text{SU}(2) \\ g & \mapsto & (1,g) \end{array}$

and the diagonal one:

$\begin{array}{ccc} \delta \colon \text{SU}(2) &\to& \text{SU}(2) \times \text{SU}(2) \\ g & \mapsto & (g,g) \end{array}$

Combining these with our earlier maps, we actually get a one-to-one map from $\text{SU}(2) \times \text{SU}(3)$ to $\text{Spin}(10)$ . So we get three subgroups of $\text{Spin}(10)$ , all isomorphic to $\text{SU}(2) \times \text{SU}(3)$ :

There’s the left subgroup $G_\ell$ , which is the image of this composite homomorphism:

$\text{SU}(2) \times \text{SU}(3) \stackrel{\ell \times j}{\longrightarrow} \text{SU}(2) \times \text{SU}(2) \times \text{SU}(4) \cong \text{Spin}(4) \times \text{Spin}(6) \stackrel{k}{\longrightarrow} \text{Spin}(10)$

There’s the diagonal subgroup $G_\delta$ , which is the image of this:

$\text{SU}(2) \times \text{SU}(3) \stackrel{\delta \times j}{\longrightarrow} \text{SU}(2) \times \text{SU}(2) \times \text{SU}(4) \cong \text{Spin}(4) \times \text{Spin}(6) \stackrel{k}{\longrightarrow} \text{Spin}(10)$

And there’s the right subgroup $G_r$ , which is the image of this:

$\text{SU}(2) \times \text{SU}(3) \stackrel{r \times j}{\longrightarrow} \text{SU}(2) \times \text{SU}(2) \times \text{SU}(4) \cong \text{Spin}(4) \times \text{Spin}(6) \stackrel{k}{\longrightarrow} \text{Spin}(10)$

The left and right subgroups are actually conjugate, but the diagonal one is truly different! We’ll prove this by taking a certain representation of $\text{Spin}(10)$ , called the Weyl spinor representation, and restricting it to those two subgroups. We’ll get inequivalent representations of $\text{SU}(2) \times \text{SU}(3)$ . This proves the two subgroups aren’t conjugate.

This argument is also interesting for physics. When restrict to the left subgroup, we get a representation of $\text{SU}(2) \times \text{SU}(3)$ that matches what we actually see for one generation of fermions! This is the basis of the so-called $\text{SO}(10)$ grand unified theory, which should really be called the $\text{Spin}(10)$ grand unified theory.

(In fact this works not only for $\text{SU}(2) \times \text{SU}(3)$ but for the whole Standard Model gauge group, which is larger. I’m focusing on $\text{SU}(2) \times \text{SU}(3)$ just because it makes the story simpler.)

When we restrict the Weyl spinor representation to the diagonal subgroup, we get a representation of $\text{SU}(2) \times \text{SU}(3)$ that is not physically correct. Unfortunately, it’s the diagonal subgroup that shows up in several papers connecting the Standard Model gauge group to the octonions. I plan to say a lot more about this later.

The left subgroup

Let’s look at the left subgroup $G_\ell$ , the image of this composite:

$\text{Spin}(10)$ has a 32-dimensional unitary representation called the ‘Dirac spinor’ representation. This representation is really on the exterior algebra $\Lambda \mathbb{C}^5$ . It’s the direct sum of two irreducible parts, the even grades and the odd grades:

$\Lambda \mathbb{C}^5 \cong \Lambda^{\text{even}} \mathbb{C}^5 \oplus \Lambda^{\text{odd}} \mathbb{C}^5$

Physicists call these two irreducible representations ‘right- and left-handed Weyl spinors’, and denote them as $\mathbf{16}$ and $\mathbf{16}\ast$ since they’re 16-dimensional and one is the dual of the other.

Let’s restrict the $\mathbf{16}$ to the left subgroup $G_\ell$ and see what we get.

To do this, first we can restrict the $\mathbf{16}$ along $k$ and get

$\mathbf{2} \otimes \mathbf{1} \otimes \mathbf{4} \; \oplus \; \mathbf{1} \otimes \mathbf{2} \otimes \mathbf{4}\ast$

Here $\mathbf{1}$ is the trivial representation of $\text{SU}(2)$ , $\mathbf{2}$ is the tautologous representation of $\text{SU}(2)$ , and $\mathbf{4}$ is the tautologous rep of $\text{SU}(4)$ .

Then let’s finish the job by restricting this representation along $\ell \times j$ . Restricting the $\mathbf{4}$ of $\text{SU}(4)$ to $\text{SU}(3)$ gives $\mathbf{3} \oplus \mathbf{1}$ : the sum of the tautologous representation of $\text{SU}(3)$ and the trivial representation. Restricting $\mathbf{2} \otimes \mathbf{1}$ to the left copy of $\text{SU}(2)$ gives the tautologous representation $\mathbf{2}$ , while restricting $\mathbf{1} \otimes \mathbf{2}$ to this left copy gives $\mathbf{1} \oplus \mathbf{1}$ : the sum of two copies of the trivial representation. All in all, we get this representation of $\text{SU}(2) \times \text{SU}(3)$ :

$\mathbf{2} \otimes (\mathbf{3} \oplus \mathbf{1}) \; \oplus \; (\mathbf{1} \oplus \mathbf{1}) \otimes (\mathbf{3}\ast \oplus \mathbf{1})$

This is what we actually see for one generation of left-handed fermions and antifermions in the Standard Model! The representation $\mathbf{3} \oplus \mathbf{1}$ describes how the left-handed fermions in one generation transform under $\text{SU}(3)$ : 3 colors of quark and one ‘white’ lepton. The representation $\mathbf{3}\ast \oplus \mathbf{1}$ does the same for the left-handed antifermions. The left-handed fermions form an isospin doublet, giving us the $\mathbf{2}$ , while the left-handed antifermions have no isospin, giving us the $\mathbf{1} \oplus \mathbf{1}$ .

This strange lopsidedness is a fundamental feature of the Standard Model.

The right subgroup would work the same way, up to switching the words ‘left-handed’ and ‘right-handed’. And by Theorem 10, the left and right subgroups must be conjugate in $\text{Spin}(10)$ , because now we’ll see one that’s not conjugate to either of these.

The diagonal subgroup

Consider the diagonal subgroup $G_\delta$ , the image of this composite:

Let’s restrict the $\mathbf{16}$ to $G_\delta$ .

To do this, first let’s restrict the $\mathbf{16}$ along $k \colon \text{SU}(2) \times \text{SU}(2) \times \text{SU}(4) \to \text{Spin}(10)$ and get

$\mathbf{2} \otimes \mathbf{1} \otimes \mathbf{4} \; \oplus \; \mathbf{1} \otimes \mathbf{2} \otimes \mathbf{4}\ast$

as before. Then let’s restrict this representation along $\delta \times j$ . The $\SU(3)$ part works as before, but what happens when we restrict $\mathbf{2} \otimes \mathbf{1}$ or $\mathbf{1} \otimes \mathbf{2}$ along the diagonal map $\delta \colon \text{SU}(2) \to \text{SU}(2) \times \text{SU}(2)$ ? We get $\mathbf{2}$ . So, this is the representation of $G_\delta$ that we get:

$\mathbf{2} \otimes (\mathbf{3} \oplus \mathbf{1}) \; \oplus \; \mathbf{2} \otimes (\mathbf{3}\ast \oplus \mathbf{1})$

This is not good for the Standard Model. It describes a more symmetrical universe than ours, where both left-handed fermions and antifermions transform as doublets under $\text{SU}(2)$ .

The fact that we got a different answer this time proves that $G_\ell$ and $G_\delta$ are not conjugate in $\text{Spin}(10)$ . So to complete the proof of Theorem 10, we only need to prove

Every subgroup of $\text{Spin}(10)$ isomorphic to $\text{SU}(2) \times \text{SU}(3)$ is conjugate to $G_\ell$ or $G_\delta$ .
$G_\delta$ is conjugate to a subgroup of $\text{Spin}(9) \subset \text{Spin}(10)$ , but $G_\ell$ is not.

I’ll prove 2, and then I’ll turn you over to Will Sawin to do the rest.

Why the diagonal subgroup fits in $\text{Spin}(9)$

Every rotation of $\mathbb{R}^n$ extends to a rotation of $\mathbb{R}^{n+1}$ that leaves the last coordinate fixed, so we get an inclusion $\text{SO}(n) \hookrightarrow \text{SO}(n+1)$ , which lifts to an inclusion of the double covers, $\text{Spin}(n) \hookrightarrow \text{Spin}(n+1)$ . Since we have exceptional isomorphisms

$\text{Spin}(3) \cong \text{SU}(2), \qquad \text{Spin}(4) \cong \text{SU}(2) \times \text{SU}(2)$

it’s natural to ask how the inclusion $\text{Spin}(3) \hookrightarrow \text{Spin}(4)$ looks in these terms. And the answer is: it’s the diagonal map! In other words, we have a commutative diagram

$\begin{array}{ccc} \text{SU}(2) & \xrightarrow{\sim} & \text{Spin}(3) \\ \delta \downarrow & & \downarrow \\ \text{SU}(2) \times \text{SU}(2) & \xrightarrow{\sim} & \text{Spin}(4) \end{array}$

Now, we can easily fit this into a larger commutative diagram involving some natural maps $\text{Spin}(m) \times \text{Spin}(n) \to \text{Spin}(m+n)$ and $\text{Spin}(n) \to \text{Spin}(n+1)$ :

$\begin{array}{ccccccc} \text{SU}(2) & \xrightarrow{\sim} & \text{Spin}(3) & \to & \text{Spin}(3) \times \text{Spin}(6) & \to & \text{Spin}(9) \\ \delta \downarrow & & \downarrow & & \downarrow & & \downarrow \\ \text{SU}(2) \times \text{SU}(2) & \xrightarrow{\sim} & \text{Spin}(4) & \to & \text{Spin}(4) \times \text{Spin}(6) & \to & \text{Spin}(10) \end{array}$

We can simplify this diagram using the isomorphism $\text{Spin}(6) \cong \text{SU}(4)$ :

$\begin{array}{ccccccc} \text{SU}(2) \times \text{SU}(4) & \to & \text{Spin}(9) \\ \delta \times 1 \downarrow & & \downarrow \\ \text{SU}(2) \times \text{SU}(2) \times \text{SU}(4) & \to & \text{Spin}(10) \end{array}$

and then we can use our friend the inclusion $j \colon \text{SU}(3) \to \text{SU}(4)$ :

$\begin{array}{ccccccc} \text{SU}(2) \times \text{SU}(3) & \xrightarrow{1 \times j} & \text{SU}(2) \times \text{SU}(4) & \to & \text{Spin}(9) \\ & & \delta \times 1 \downarrow & & \downarrow \\ & & \text{SU}(2) \times \text{SU}(2) \times \text{SU}(4) & \to & \text{Spin}(10) \end{array}$

This shows that the diagonal subgroup $G_\delta$ of $\text{Spin}(10)$ is actually a subgroup of $\text{Spin}(9)$ !

Why the left subgroup does not fit in $\text{Spin}(9)$

The three-fold way is a coarse classification of irreducible complex representations of compact Lie group. Every such representation is of one and only one of these three kinds:

1) not self-dual: not isomorphic to its dual,

2a) orthogonal: isomorphic to its dual via an invariant nondegenerate symmetric bilinear form, also called an orthogonal structure,

2b) symplectic: isomorphic to its dual via an invariant nondegenerate antisymmetric bilinear form, also called a symplectic structure.

I’ve written about how these three cases are related to the division algebras $\mathbb{C}, \mathbb{R}$ and $\mathbb{H}$ , respectively:

John Baez, Division algebras and quantum theory.

A complex representation is orthogonal iff it’s the complexification of a representation on a real vector space, and symplectic iff it’s the underlying complex representation of a representation on a quaternionic vector space.

But we don’t need most of this yet. For now we just need to know one fact: when $n$ is odd, every irreducible representation of $\text{Spin}(n)$ , and thus every representation of this Lie group, is self-dual: that is, isomorphic to its dual. In particular this is true of $\text{Spin}(9)$ .

Why does this matter? Assume the left subgroup $G_\ell \subset \text{Spin}(10)$ is a subgroup of $\text{Spin}(9)$ . When we restrict the Weyl spinor representation of $\text{Spin}(10)$ to $\text{Spin}(9)$ it will be self-dual, like every representation of $\text{Spin}(9)$ . Then when we restrict this representation further to $\text{SU}(2) \times \text{SU}(3)$ it must still be self-dual, since the restriction of a self-dual representation is clearly self-dual.

However, we know this representation is

$\mathbf{2} \otimes (\mathbf{3} \oplus \mathbf{1}) \; \oplus \; (\mathbf{1} \oplus \mathbf{1}) \otimes (\mathbf{3}\ast \oplus \mathbf{1})$

and this is not self-dual, since $\mathbf{1}\ast \cong \mathbf{1}$ and $\mathbf{2}\ast \cong \mathbf{2}$ but $\mathbf{3}\ast \ncong \mathbf{3}$ .

So, it must be that $G_\ell$ is not a subgroup of $\text{Spin}(9)$ .

Proof of Theorem 10

To complete the proof of Theorem 10 we just need to see why there are just two conjugacy classes of subgroups of $\text{Spin}(10)$ isomorphic to $\text{SU}(2) \times \text{SU}(3)$ . But in fact Will Sawin proved a stronger result! He was answering this question of mine:

Define the Standard Model gauge group to be $\text{S}(\text{U}(2) \times \text{U}(3))$ , the subgroup of $\text{SU}(5)$ consisting of block diagonal matrices with a $2 \times 2$ block and then a $3 \times 3$ block. (This is isomorphic to the quotient of $\text{U}(1) \times \text{SU}(2) \times \text{SU}(3)$ by the subgroup of elements $(\alpha, \alpha^{-3}, \alpha^2$ ) where $\alpha$ is a 6th root of unity.)

Up to conjugacy, how many subgroups isomorphic to the Standard Model gauge group does $\text{Spin}(10)$ have?

This question is relevant to grand unified theories of particle physics, as explained here:

John C. Baez and John Huerta, The algebra of grand unified theories, Bull. Amer. Math. Soc. 47 (2010), 483-552.

This paper focuses on one particular copy of $\text{S}(\text{U}(2) \times \text{U}(3))$ in $\text{Spin}(10)$ , given as follows. By definition we have an inclusion $\text{S}(\text{U}(2) \times \text{U}(3)) \hookrightarrow \text{SU}(5)$ , and we also have an inclusion $\text{SU}(5) \hookrightarrow \text{Spin}(10)$ because for any $n$ we have an inclusion $\text{SU}(n) \hookrightarrow \text{SO}(2n)$ , and $\text{SU}(n)$ is simply connected so this gives a homomorphism $\text{SU}(n) \hookrightarrow \text{Spin}(2n)$ .

However I think there is also an inclusion $\text{S}(\text{U}(2) \times \text{U}(3)) \hookrightarrow \text{Spin}(9)$ , studied by Krasnov:

Kirill Krasnov, SO(9) characterisation of the Standard Model gauge group.

Composing this with $\text{Spin}(9) \hookrightarrow \text{Spin}(10)$ , this should give another inclusion $\text{S}(\text{U}(2) \times \text{U}(3)) \hookrightarrow \text{Spin}(10)$ , and I believe this one is ‘truly different from’ — i.e., not conjugate to — the first one I mentioned.

So I believe my current answer to my question is “at least two”. But that’s not good enough.

Sawin’s answer relies heavily on the 3-fold way — that’s why I told you that stuff about orthogonal and symplectic representatinos. When we embed the group $\text{SU}(2) \times \text{SU}(3)$ in $\text{Spin}(10)$ , we are automatically giving this group an orthogonal 10-dimensional representation, thanks to the map $\text{Spin}(10) \to \text{SO}(10)$ . We can classify the possibilities.

He writes:

There are infinitely many embeddings. However, all but one of them is “essentially the same as” the one you studied as they become equal to the one you studied on restriction to $\text{SU}(2)\times \text{SU}(3)$ . The remaining one is the one studied by Krasnov.

I follow the strategy suggested by Kenta Suzuki.

$\text{SU}(3)$ has irreducible representations of dimensions $1,3,3,6,8,6, 10, 10$ , and higher dimensions. The $10$ -dimensional ones are dual to each other, as are the $6$ -dimensional ones, so they can’t appear. The $3$ -dimensional ones are dual to each other and can only appear together. So the only $10$ -dimensional self-dual representations of $\text{SU}(3)$ decompose as irreducibles as $8+1+1$ , $3+3+1+1+1+1$ , or ten $1$ s. All of these are orthogonal because the 8-dimensional representation is orthogonal. However, the ten $1$ s cannot appear because then $\text{SU}(3)$ would act trivially.

A representation of $\text{SU}(3) \times \text{SU}(2)$ is a sum of tensor products of irreducible representations of $\text{SU}(3)$ and irreducible representations of $\text{SU}(2)$ . Restricted to $\text{SU}(3)$ , each tensor product splits into a sum of copies of the same irreducible representation. So $\text{SU}(2)$ can only act nontrivially when the same representation appears multiple times. Since the $3+3$ is two different $3$ -dimensional representation, only the $1$ -dimensional representation can occur twice. Thus, our 10-dimensional orthogonal representation of $\text{SU}(3) \times \text{SU}(2)$ necessarily splits as either the $8$ -dimensional adjoint repsentation of $\text{SU}(3)$ plus a $2$ -dimensional orthogonal representation of $\text{SU}(2)$ or the $6$ -dimensional sum of standard and conjugate [i.e., dual] representations of $\text{SU}(3)$ plus a $4$ -dimensional orthogonal representation of $\text{SU}(2)$ . However, $\text{SU}(2)$ has a unique nontrivial representation of dimension $2$ and it isn’t orthgonal, so only the second case can appear. $\text{SU}(2)$ has representations of dimension $1,2,3,4$ of which the $2$ and $4$ -dimensional ones are symplectic and so must appear with even multiplicity in any orthogonal representation, so the only nontrivial $4$ -dimensional orthogonal ones are $2+2$ or $3+1$ .

So there are two ten-dimensional orthogonal representations of $\text{SU}(2) \times \text{SU}(3)$ that are nontrivial on both factors, those being the sum of two different $3$ -dimensional irreducible representations of $\text{SU}(3)$ with either two copies of the two-dimensional irreducible representation of $\text{SU}(2)$ or the three-dimensional and the one-dimensional irreducible representation of $\text{SU}(2)$ . The orthogonal structure is unique up to isomorphisms, so these give two conjugacy classes of homomorphisms $\text{SU}(2) \times \text{SU}(3) \to SO(10)$ and thus two conjugacy classes of homomorphisms $\text{SU}(2) \times \text{SU}(3) \to \text{Spin}(10)$ . The first one corrresponds to the embedding you studied while only the second one restricts to $\text{Spin}(9)$ so indeed these are different.

To understand how to extend these to $\text{S}(\text{U}(2) \times \text{U}(3))$ , I consider the centralizer of the representation within $\text{Spin}(10)$ . Since the group is connected, this is the same as the centralizer of its Lie algebra, which is therefore the inverse image of the centralizer in $\text{SO}(10)$ . Now there is a distinction between the two examples because the example with irrep dimensions $3+3+2+2$ has centralizer with identity component $\text{U}(1) \times \text{SU}(2)$ while the example with irrep dimensions $3+3+3+1$ has centralizer with identity component $\text{U}(1)$ . In the second case, the image of $\text{U}(2) \times \text{U}(3)$ must be the image of $\text{SU}(2) \times \text{SU}(3)$ times the centralizer of the image of $\text{SU}(2) \times \text{SU}(3)$ , so this gives a unique example, which must be the one considered by Krasnov.

In the first case, we can restrict attention to a torus $\text{U}(1) \times \text{U}(1)$ in $\text{SU}(2) \times \text{SU}(2)$ . The center of $\text{S}(\text{U}(2) \times \text{U}(3))$ maps to a one-dimensional subgroup of this torus, which can be described by a pair of integers. Explicitly, given a two-by-two-unitary matrix $A$ and a three-by-three unitary matrix $B$ with $\det(A) \det(B) =1$ , we can map to $\text{U}(5)$ by sending $(A,B)$ to $A \gamma^a \oplus B \gamma^b$ where $\gamma = \det (A) = \det(B)^{-1}$ , and then map from $\text{U}(5)$ to $SO(10)$ . This lifts to the spin group if and only if the determinant in $\text{U}(5)$ is a perfect square. The determinant is $\gamma^{ 1 + 2a - 1 + 3b} = \gamma^{2a+3b}$ so a lift exists if and only if $b$ is even.

The only possible kernel of this embedding is the scalars. The scalar $A = \lambda^3 I_2, B = \lambda^{-2} I_3$ maps to $\lambda^{3+ 6a} I_2 \oplus \lambda^{-2 + 6b} I_3$ and so the kernel is trivial if and only if $\gcd(3+6a,-2 + 6b)=1$ .

However, there are infinitely many integer solutions $a,b$ to $\gcd(3+6a,-2a+6b)=1$ with $b$ even (in fact, a random $a$ and even $b$ works with probability $9/\pi^2$ ), so this gives infinitely many examples.

Part 1. How to define octonion multiplication using complex scalars and vectors, much as quaternion multiplication can be defined using real scalars and vectors. This description requires singling out a specific unit imaginary octonion, and it shows that octonion multiplication is invariant under $\mathrm{SU}(3)$ .
Part 2. A more polished way to think about octonion multiplication in terms of complex scalars and vectors, and a similar-looking way to describe it using the cross product in 7 dimensions.
Part 3. How a lepton and a quark fit together into an octonion — at least if we only consider them as representations of $\mathrm{SU}(3)$ , the gauge group of the strong force. Proof that the symmetries of the octonions fixing an imaginary octonion form precisely the group $\mathrm{SU}(3)$ .
Part 4. Introducing the exceptional Jordan algebra $\mathfrak{h}_3(\mathbb{O})$ : the $3 \times 3$ self-adjoint octonionic matrices. A result of Dubois-Violette and Todorov: the symmetries of the exceptional Jordan algebra preserving their splitting into complex scalar and vector parts and preserving a copy of the $2 \times 2$ adjoint octonionic matrices form precisely the Standard Model gauge group.
Part 5. How to think of $2 \times 2$ self-adjoint octonionic matrices as vectors in 10d Minkowski spacetime, and pairs of octonions as left- or right-handed spinors.
Part 6. The linear transformations of the exceptional Jordan algebra that preserve the determinant form the exceptional Lie group $\mathrm{E}_6$ . How to compute this determinant in terms of 10-dimensional spacetime geometry: that is, scalars, vectors and left-handed spinors in 10d Minkowski spacetime.
Part 7. How to describe the Lie group $\mathrm{E}_6$ using 10-dimensional spacetime geometry. This group is built from the double cover of the Lorentz group, left-handed and right-handed spinors, and scalars in 10d Minkowski spacetime.
Part 8. A geometrical way to see how $\mathrm{E}_6$ is connected to 10d spacetime, based on the octonionic projective plane.
Part 9. Duality in projective plane geometry, and how it lets us break the Lie group $\mathrm{E}_6$ into the Lorentz group, left-handed and right-handed spinors, and scalars in 10d Minkowski spacetime.
Part 10. Jordan algebras, their symmetry groups, their invariant structures — and how they connect quantum mechanics, special relativity and projective geometry.
Part 11. Particle physics on the spacetime given by the exceptional Jordan algebra: a summary of work with Greg Egan and John Huerta.
Part 12. The bioctonionic projective plane and its connections to algebra, geometry and physics.
Part 13. Two ways to embed $\text{SU}(2) \times \text{SU}(3)$ in $\text{Spin}(10)$ , and their consequences for particle physics.

December 20, 2025

Jordan Ellenberg — Rusczyk wins a Bezos

A $5 million grant for my old friend Richard Rusczyk and the MATHCOUNTS foundation. Great news! Richard founded Art of Problem Solving, which is the only online math course platform I’ve ever found to be worth a damn. I love the way they emphasize depth over acceleration. When you do algebra with them, you don’t do the high school algebra curriculum in six weeks, you spend the whole year but you do a hell of a lot more algebra. That’s the way it should be! The point of learning math, if you love math, isn’t to get to the highest course number at the earliest age possible; it’s to learn deeply, richly, broadly, and well. I have taught too many grad students who can say “a representation is a functor from a groupoid with one object to the category k-Vect” but who have never sat down and worked out the character tables of a dozen different groups.

I also like the way AOPS is resolutely monomedia. No voice, no video. Just text! That makes sense. Math is made of words.

I met Richard when we were in high school, both in training for the Math Olympiad. He was from Alabama and he taught me how to say “my bad” for “sorry about that.” I’d never heard it! In 1988 nobody outside the South said “my bad.” I was impressed. I started saying “my bad” when I got home, just one of my many 1988 affectations.

by JSE at December 20, 2025 04:10 AM

December 19, 2025

Matt von Hippel — Academia Tracks Priority, Not Provenance

A recent Correspondence piece in Nature Machine Intelligence points at an issue with using LLMs to write journal articles. LLMs are trained on enormous amounts of scholarly output, but the result is quite opaque: it is usually impossible to tell which sources influence a specific LLM-written text. That means that when a scholar uses an LLM, they may get a result that depends on another scholar’s work, without realizing it or documenting it. The ideas’ provenance gets lost, and the piece argues this is damaging, depriving scholars of credit and setting back progress.

It’s a good point. Provenance matters. If we want to prioritize funding for scholars whose ideas have the most impact, we need a way to track where ideas arise.

However, current publishing norms make essentially no effort to do this. Academic citations are not used to track provenance, and they are not typically thought of as tracking provenance. Academic citations track priority.

Priority is a central value in scholarship, with a long history. We give special respect to the first person to come up with an idea, make an observation, or do a calculation, and more specifically, the first person to formally publish it. We do this even if the person’s influence was limited, and even if the idea was rediscovered independently later on. In an academic context, being first matters.

In a paper, one is thus expected to cite the sources that have priority, that came up with an idea first. Someone who fails to do so will get citation request emails, and reviewers may request revisions to the paper to add in those missing citations.

One may also cite papers that were helpful, even if they didn’t come first. Tracking provenance in this way can be nice, a way to give direct credit to those who helped and point people to useful resources. But it isn’t mandatory in the same way. If you leave out a secondary source and your paper doesn’t use anything original to that source (like new notation), you’re much less likely to get citation request emails, or revision requests from reviewers. Provenance is just much lower priority.

In practice, academics track provenance in much less formal ways. Before citations, a paper will typically have an Acknowledgements section, where the authors thank those who made the paper possible. This includes formal thanks to funding agencies, but also informal thanks for “helpful discussions” that don’t meet the threshold of authorship.

If we cared about tracking provenance, those acknowledgements would be crucial information, an account of whose ideas directly influenced the ideas in the paper. But they’re not treated that way. No-one lists the number of times they’ve been thanked for helpful discussions on their CV, or in a grant application, no-one considers these discussions for hiring or promotion. You can’t look them up on an academic profile or easily graph them in a metascience paper. Unlike citations, unlike priority, there is essentially no attempt to measure these tracks of provenance in any organized way.

Instead, provenance is often the realm of historians or history-minded scholars, writing long after the fact. For academics, the fact that Yang and Mills published their theory first is enough, we call it Yang-Mills theory. For those studying the history, the story is murkier: it looks like Pauli came up with the idea first, and did most of the key calculations, but didn’t publish when it looked to him like the theory couldn’t describe the real world. What’s more, there is evidence suggesting that Yang knew about Pauli’s result, that he had read a letter from him on the topic, that the idea’s provenance goes back to Pauli. But Yang published, Pauli didn’t. And in the way academia has worked over the last 75 years, that claim of priority is what actually mattered.

Should we try to track provenance? Maybe. Maybe the emerging ubiquitousness of LLMs should be a wakeup call, a demand to improve our tracking of ideas, both in artificial and human neural networks. Maybe we need to demand interpretability from our research tools, to insist that we can track every conclusion back to its evidence for every method we employ, to set a civilizational technological priority on the accurate valuation of information.

What we shouldn’t do, though, is pretend that we just need to go back to what we were doing before.

by 4gravitons at December 19, 2025 05:00 PM

December 17, 2025

Terence Tao — The maximal length of the Erdős–Herzog–Piranian lemniscate in high degree

I’ve just uploaded to the arXiv my preprint The maximal length of the Erdős–Herzog–Piranian lemniscate in high degree. This paper resolves (in the asymptotic regime of sufficiently high degree) an old question about the polynomial lemniscates

$\displaystyle \partial E_1(p) := \{ z: |p(z)| = 1\}$

attached to monic polynomials ${p}$ of a given degree ${n}$ , and specifically the question of bounding the arclength ${\ell(\partial E_1(p))}$ of such lemniscates. For instance, when ${p(z)=z^n}$ , the lemniscate is the unit circle and the arclength is ${2\pi}$ ; this in fact turns out to be the minimum possible length amongst all (connected) lemniscates, a result of Pommerenke. However, the question of the largest lemniscate length is open. The leading candidate for the extremizer is the polynomial

$\displaystyle p_0(z)= z^n-1$

whose lemniscate is quite convoluted, with an arclength that can be computed asymptotically as

$\displaystyle \ell(\partial E_1(p_0)) = B(1/2,n/2) = 2n + 4 \log 2 + O(1/n)$

where ${B}$ is the beta function.

(The images here were generated using AlphaEvolve and Gemini.) A reasonably well-known conjecture of Erdős, Herzog, and Piranian (Erdős problem 114) asserts that this is indeed the maximizer, thus ${\ell(\partial E_1(p)) \leq \ell(\partial E_1(p_0))}$ for all monic polynomials of degree ${n}$ .

There have been several partial results towards this conjecture. For instance, Eremenko and Hayman verified the conjecture when ${n=2}$ . Asympotically, bounds of the form ${\ell(\partial E_1(p)) \leq (C+o(1)) n}$ had been known for various ${C}$ such as ${\pi}$ , ${2\pi}$ , or ${4\pi}$ ; a significant advance was made by Fryntov and Nazarov, who obtained the asymptotically sharp upper bound

$\displaystyle \ell(\partial E_1(p)) \leq 2n + O(n^{7/8})$

and also obtained the sharp conjecture ${\ell(\partial E_1(p)) \leq \ell(\partial E_1(p_0))}$ for ${p}$ sufficiently close to ${p_0}$ . In that paper, the authors comment that the ${O(n^{7/8})}$ error could be improved, but that ${O(n^{1/2})}$ seemed to be the limit of their method.

I recently explored this problem with the optimization tool AlphaEvolve, where I found that when I assigned this tool the task of optimizing ${\ell(\partial E_1(p))}$ for a given degree ${n}$ , that the tool rapidly converged to choosing ${p}$ to be equal to ${p_0}$ (up to the rotation and translation symmetries of the problem). This suggested to me that the conjecture was true for all ${n}$ , though of course this was far from a rigorous proof. AlphaEvolve also provided some useful visualization code for these lemniscates which I have incorporated into the paper (and this blog post), and which helped build my intuition for this problem; I view this sort of “vibe-coded visualization” as another practical use-case of present-day AI tools.

In this paper, we iteratively improve upon the Fryntov-Nazarov method to obtain the following bounds, in increasing order of strength:

(i) ${\ell(\partial E_1(p)) \leq 2n + O(n^{1/2})}$ .
(ii) ${\ell(\partial E_1(p)) \leq 2n + O(1)}$ .
(iii) ${\ell(\partial E_1(p)) \leq 2n + 4 \log 2 + o(1)}$ .
(iv) ${\ell(\partial E_1(p)) \leq \ell(\partial E_1(p_0))}$ for sufficiently large ${n}$ .

In particular, the Erdős–Herzog–Piranian conjecture is now verified for sufficiently large ${n}$ .

The proof of these bounds is somewhat circuitious and technical, with the analysis from each part of this result used as a starting point for the next one. For this blog post, I would like to focus on the main ideas of the arguments.

A key difficulty is that there are relatively few tools for upper bounding the arclength of a curve; indeed, the coastline paradox already shows that curves can have infinite length even when bounded. Thus, one needs to utilize some smooth or algebraic structure on the curve to hope for good upper bounds. One possible approach is via the Crofton formula, using Bezout’s theorem to control the intersection of the curve with various lines. This is already good enough to get bounds of the form ${\ell(\partial E_1(p)) \leq O(n)}$ (for instance by combining it with other known tools to control the diameter of the lemniscate), but it seems challenging to use this approach to get bounds close to the optimal ${\sim 2n}$ .

Instead, we follow Fryntov–Nazarov and utilize Stokes’ theorem to convert the arclength into an area integral. A typical identity used in that paper is

$\displaystyle \ell(\partial E_1(p)) = 2 \int_{E_1(p)} |p'|\ dA - \int_{E_1(p)} \frac{|p\varphi|}{\varphi} \psi\ dA$

where ${dA}$ is area measure, ${\varphi = p'/p}$ is the log-derivative of ${p}$ , ${\psi = p''/p'}$ is the log-derivative of ${p'}$ , and ${E_1(p)}$ is the region ${\{ |p| \leq 1 \}}$ . This and the triangle inequality already lets one prove bounds of the form ${\ell(\partial E_1(p)) \leq 2\pi n + O(n^{1/2})}$ by controlling ${\int_{E_1(p)} |\psi|\ dA}$ using the triangle inequality, the Hardy-Littlewood rearrangement inequality, and the Polya capacity inequality.

But this argument does not fully capture the oscillating nature of the phase ${\frac{|\varphi|}{\varphi}}$ on one hand, and the oscillating nature of ${E_1(p)}$ on the other. Fryntov–Nazarov exploited these oscillations with some additional decompositions and integration by parts arguments. By optimizing these arguments, I was able to establish an inequality of the form

$\displaystyle \ell(\partial E_1(p)) \leq \frac{1}{\pi} \int_{E_2(p)} |\psi|\ dA + O(X_1+X_2+X_3+X_4+X_5) \ \ \ \ \ (1)$

where ${E_2(p) = \{ |p| \leq 2\}}$ is an enlargement of ${E_1(p)}$ (that is significantly less oscillatory, as displayed in the figure below), and ${X_1,\dots,X_5}$ are certain error terms that can be controlled by a number of standard tools (e.g., the Grönwall area theorem).

One can heuristically justify (1) as follows. Suppose we work in a region where the functions ${\psi}$ , ${p}$ are roughly constant: ${\psi(z) \approx \psi_0}$ , ${p(z) \approx c_0}$ . For simplicity let us normalize ${\psi_0}$ to be real, and ${c_0}$ to be negative real. In order to have a non-trivial lemniscate in this region, ${c_0}$ should be close to ${-1}$ . Because the unit circle ${\partial D(0,1)}$ is tangent to the line ${\{ w: \Re w = -1\}}$ at ${-1}$ , the lemniscate condition ${|p(z)|=1}$ is then heuristically approximated by the condition that ${\Re (p(z) + 1) = 0}$ . On the other hand, the hypothesis ${\psi(z) \approx \psi_0}$ suggests that ${p'(z) \approx A e^{\psi_0 z}}$ for some amplitude ${z}$ , which heuristically integrates to ${p(z) \approx c_0 + \frac{A}{\psi_0} e^{\psi_0 z}}$ . Writing ${\frac{A}{\psi_0}}$ in polar coordinates as ${Re^{i\theta}}$ and ${z}$ in Cartesian coordinates as ${x+iy}$ , the condition ${\Re(p(z)+1)=0}$ can then be rearranged after some algebra as

$\displaystyle \cos (\psi_0 y + \theta) \approx -\frac{1+c_0}{Re^{\psi_0 x}}.$

If the right-hand side is much larger than ${1}$ in magnitude, we thus expect the lemniscate to be empty in this region; but if instead the right-hand side is much less than ${1}$ in magnitude, we expect the lemniscate to behave like a periodic sequence of horizontal lines of spacing ${\frac{\pi}{\psi_0}}$ . This makes the main terms on both sides of (1) approximately agree (per unit area).

A graphic illustration of (1) (provided by Gemini) is shown below, where the dark spots correspond to small values of ${\psi}$ that act to “repel” (and shorten) the lemniscate. (The bright spots correspond to the critical points of ${p}$ , which in this case consist of six critical points at the origin and one at both of ${+1/2}$ and ${-1/2}$ .)

By choosing parameters appropriately, one can show that ${X_1,\dots,X_5 = O(\sqrt{n})}$ and ${\frac{1}{\pi} \int_{E_2(p)} |\psi|\ dA \leq 2n + O(1)}$ , yielding the first bound ${\ell(\partial E_1(p)) \leq 2n + O(n^{1/2})}$ . However, by a more careful inspection of the arguments, and in particular measuring the defect in the triangle inequality

$\displaystyle |\psi(z)| = |\sum_\zeta \frac{1}{z-\zeta}| \leq \sum_\zeta \frac{1}{|z-\zeta|},$

where ${\zeta}$ ranges over critical points. From some elementary geometry, one can show that the more the critical points ${\zeta}$ are dispersed away from each other (in an ${\ell^1}$ sense), the more one can gain over the triangle inequality here; conversely, the ${L^1}$ dispersion ${\sum_\zeta |\zeta|}$ of the critical points (after normalizing so that these critical points have mean zero) can be used to improve the control on the error terms ${X_1,\dots,X_5}$ . Optimizing this strategy leads to the second bound

$\displaystyle \ell(\partial E_1(p)) \leq 2n + O(1).$

At this point, the only remaining cases that need to be handled are the ones with bounded dispersion: ${\sum_\zeta |\zeta| \leq 1}$ . In this case, one can do some elementary manipulations of the factorization

$\displaystyle p'(z) = n \prod_\zeta (z-\zeta)$

to obtain some quite precise control on the asymptotics of ${p(z)}$ and ${p'(z)}$ ; for instance, we will be able to obtain an approximation of the form

$\displaystyle p(z) \approx -1 + \frac{z p'(z)}{n}$

with high accuracy, as long as ${z}$ is not too close to the origin or to critical points. This, combined with direct arclength computations, can eventually lead to the third estimate

$\displaystyle \ell(\partial E_1(p)) \leq 2n + 4 \log 2 + o(1).$

The last remaining cases to handle are those of small dispersion, ${\sum_\zeta |\zeta| = o(1)}$ . An extremely careful version of the previous analysis can now give an estimate of the shape

$\displaystyle \ell(\partial E_1(p)) \leq \ell(\partial E_1(p_0)) - c \|p\| + o(\|p\|)$

for an absolute constant ${c>0}$ , where ${\|p\|}$ is a measure of how close ${p}$ is to ${p_0}$ (it is equal to the dispersion ${\sum_\zeta |\zeta|}$ plus an additional term ${n |1 + p(0)|^{1/n}}$ to deal with the constant term ${p(0)}$ ). This establishes the final bound (for ${n}$ large enough), and even shows that the only extremizer is ${p_0}$ (up to translation and rotation symmetry).

by Terence Tao at December 17, 2025 06:40 PM

December 16, 2025

Doug Natelson — An open position at Rice, Assistant or Associate Professor of Advanced Computational Materials

The Rice Advanced Materials Institute has an open search in the area of computational materials. The full position posting is here. Please spread the word!

The brief description:

The Rice Advanced Materials Institute (RAMI) at Rice University, located in Houston TX, seeks applications for tenure-track Assistant and/or Associate Professor position in the area of advanced computational and/or applied artificial intelligence (AI)/machine learning (ML)-informed materials research with an anticipated start date of July 1, 2026 to January 1, 2027. RAMI, working in conjunction with the Schools of Engineering and Computing and Natural Sciences and the Departments therein, seeks applicants from diverse backgrounds for potential tenure-track faculty positions in Departments to be determined by the best natural fit and input of the candidate (e.g., potential departments could include, but not be limited to, Chemical and Biomolecular Engineering, Chemistry, Electrical and Computer Engineering, Materials Science and NanoEngineering, Mechanical Engineering, or Physics and Astronomy). More experienced candidates nearing the transition to or having already recently transitioned to the Associate Professor level and conducting transformative research projects will be considered.

We seek outstanding candidates with research interests in theoretical, computational, modeling, and/or simulation of materials science (and related fields) and the application of advanced AI and ML approaches to accelerate, improve, or revolutionize the same. Research spanning all of aspects of materials including soft/hard matter, inorganic/organic materials, etc. is welcomed, as long as that research maps significantly to one or more of the RAMI core research areas, including:

Next-generation Electronics/Photonics – Developing materials to enable a new paradigm in microelectronics ranging from memory/logic to communications to sensors and beyond, with a focus on low-power/voltage function.
Energy Materials (Systems) – Developing materials innovations to transform energy storage and conversion/harvesting.
Materials for the Environment – Developing materials innovations to assure responsible use of natural resources and long-term stewardship of our air, soil, and water resources.

This effort is being initiated through RAMI, a campus-wide institute with the goal of expanding Rice’s already strong efforts in materials research across many departments in science and engineering. RAMI includes >70 current faculty members working on a wide array of research that overlap with RAMI’s core research focus areas. Rice considers efforts to bolster these areas as a focal point of materials research in the coming years.

The selected candidates will be expected to teach and develop undergraduate and graduate courses within their expertise and home department; perform high-quality research in their specialized area and present findings from their research in peer-reviewed publications and conferences; establish a strong research program supported by extramural funding; be involved in service to the university and broader scientific community; and collaborate with faculty in diverse disciplines. Successful candidates will have a strong commitment to teaching, advising, and mentoring undergraduate and graduate students from diverse backgrounds.

Applications will be reviewed in a rolling fashion but should be received by 11:59 PM (eastern time) on January 4, 2026. Applications received after this deadline will be considered as they arrive and until the position is filled.

by Douglas Natelson at December 16, 2025 07:32 PM

Scott Aaronson Happy Chanukah

This (taken in Kiel, Germany in 1931 and then colorized) is one of the most famous photographs in Jewish history, but it acquired special resonance this weekend. It communicates pretty much everything I’d want to say about the Bondi Beach massacre in Australia, more succinctly than I could in words.

But I can’t resist sharing one more photo, after GPT5-Pro helpfully blurred the faces for me. This is my 8-year-old son Daniel, singing a Chanukah song at our synagogue, at an event the morning after the massacre, which was packed despite the extra security needed to get in.

Alright, one more photo. This is Ahmed Al Ahmed, the hero who tackled and disarmed one of the terrorists, recovering in the hospital from his gunshot wounds. Facebook and Twitter and (alas) sometimes the comment section of this blog show me the worst of humanity, day after day after day, so it’s important to remember the best of humanity as well.

Chanukah, of course, is the most explicitly Zionist of all Jewish holidays, commemorating as it does the Maccabees’ military victory against the Seleucid Greeks, in their (historically well-attested) wars of 168-134BCE to restore an independent Jewish state with its capital in Jerusalem. In a sense, then, the terrorists were precisely correct, when they understood the cry “globalize the intifada” to mean “murder random Jews anywhere on earth, even halfway around the world, who might be celebrating Chanukah.” By the lights of the intifada worldview, Chabadniks in Sydney were indeed perfectly legitimate targets. By my worldview, though, the response is equally clear: to abandon all pretense, and say openly that now, as in countless generations past, Jews everywhere are caught up in a war, not of our choosing, which we “win” merely by surviving with culture and memory intact.

Happy Chanukah.

by Scott at December 16, 2025 01:39 AM

December 15, 2025

John Preskill — Make use of time, let not advantage slip

During the spring of 2022, I felt as though I kept dashing backward and forward in time.

At the beginning of the season, hay fever plagued me in Maryland. Then, I left to present talks in southern California. There—closer to the equator—rose season had peaked, and wisteria petals covered the ground near Caltech’s physics building. From California, I flew to Canada to present a colloquium. Time rewound as I traveled northward; allergies struck again. After I returned to Maryland, the spring ripened almost into summer. But the calendar backtracked when I flew to Sweden: tulips and lilacs surrounded me again.

Caltech wisteria in April 2022: Thou art lovely and temperate.

The zigzagging through horticultural time disoriented my nose, but I couldn’t complain: it echoed the quantum information processing that collaborators and I would propose that summer. We showed how to improve quantum metrology—our ability to measure things, using quantum detectors—by simulating closed timelike curves.

A closed timelike curve is a trajectory that loops back on itself in spacetime. If on such a trajectory, you’ll advance forward in time, reverse chronological direction to advance backward, and then reverse again. Author Jasper Fforde illustrates closed timelike curves in his novel The Eyre Affair. A character named Colonel Next buys an edition of Shakespeare’s works, travels to the Elizabethan era, bestows them on a Brit called Will, and then returns to his family. Will copies out the plays and stages them. His colleagues publish the plays after his death, and other editions ensue. Centuries later, Colonel Next purchases one of those editions to take to the Elizabethan era.¹

Closed timelike curves can exist according to Einstein’s general theory of relativity. But do they exist? Nobody knows. Many physicists expect not. But a quantum system can simulate a closed timelike curve, undergoing a process modeled by the same mathematics.

How can one formulate closed timelike curves in quantum theory? Oxford physicist David Deutsch proposed one formulation; a team led by MIT’s Seth Lloyd proposed another. Correlations distinguish the proposals.

Two entities share correlations if a change in one entity tracks a change in the other. Two classical systems can correlate; for example, your brain is correlated with mine, now that you’ve read writing I’ve produced. Quantum systems can correlate more strongly than classical systems can, as by entangling.

Suppose Colonel Next correlates two nuclei and gives one to his daughter before embarking on his closed timelike curve. Once he completes the loop, what relationship does Colonel Next’s nucleus share with his daughter’s? The nuclei retain the correlations they shared before Colonel Next entered the loop, according to Seth and collaborators. When referring to closed timelike curves from now on, I’ll mean ones of Seth’s sort.

We can simulate closed timelike curves by subjecting a quantum system to a circuit of the type illustrated below. We read the diagram from bottom to top. Along this direction, time—as measured by a clock at rest with respect to the laboratory—progresses. Each vertical wire represents a qubit—a basic unit of quantum information, encoded in an atom or a photon or the like. Each horizontal slice of the diagram represents one instant.

At the bottom of the diagram, the two vertical wires sprout from one curved wire. This feature signifies that the experimentalist prepares the qubits in an entangled state, represented by the symbol $| \Psi_- \rangle$ . Farther up, the left-hand wire runs through a box. The box signifies that the corresponding qubit undergoes a transformation (for experts: a unitary evolution).

At the top of the diagram, the vertical wires fuse again: the experimentalist measures whether the qubits are in the state they began in. The measurement is probabilistic; we (typically) can’t predict the outcome in advance, due to the uncertainty inherent in quantum physics. If the measurement yields the yes outcome, the experimentalist has simulated a closed timelike curve. If the no outcome results, the experimentalist should scrap the trial and try again.

So much for interpreting the diagram above as a quantum circuit. We can reinterpret the illustration as a closed timelike curve. You’ve probably guessed as much, comparing the circuit diagram to the depiction, farther above, of Colonel Next’s journey. According to the second interpretation, the loop represents one particle’s trajectory through spacetime. The bottom and top show the particle reversing chronological direction—resembling me as I flew to or from southern California.

Me in southern California in spring 2022. Photo courtesy of Justin Dressel.

How can we apply closed timelike curves in quantum metrology? In Fforde’s books, Colonel Next has a brother, named Mycroft, who’s an inventor.² Suppose that Mycroft is studying how two particles interact (e.g., by an electric force). He wants to measure the interaction’s strength. Mycroft should prepare one particle—a sensor—and expose it to the second particle. He should wait for some time, then measure how much the interaction has altered the sensor’s configuration. The degree of alteration implies the interaction’s strength. The particles can be quantum, if Mycroft lives not merely in Sherlock Holmes’s world, but in a quantum-steampunk one.

But how should Mycroft prepare the sensor—in which quantum state? Certain initial states will enable the sensor to acquire ample information about the interaction; and others, no information. Mycroft can’t know which preparation will work best: the optimal preparation depends on the interaction, which he hasn’t measured yet.

Mycroft, as drawn by Sydney Paget in the 1890s

Mycroft can overcome this dilemma via a strategy published by my collaborator David Arvidsson-Shukur, his recent student Aidan McConnell, and me. According to our protocol, Mycroft entangles the sensor with a third particle. He subjects the sensor to the interaction (coupling the sensor to particle #2) and measures the sensor.

Then, Mycroft learns about the interaction—learns which state he should have prepared the sensor in earlier. He effectively teleports this state backward in time to the beginning-of-protocol sensor, using particle #3 (which began entangled with the sensor).³ Quantum teleportation is a decades-old information-processing task that relies on entanglement manipulation. The protocol can transmit quantum states over arbitrary distances—or, effectively, across time.

We can view Mycroft’s experiment in two ways. Using several particles, he manipulates entanglement to measure the interaction strength optimally (with the best possible precision). This process is mathematically equivalent to another. In the latter process, Mycroft uses only one sensor. It comes forward in time, reverses chronological direction (after Mycroft learns the optimal initial state’s form), backtracks to an earlier time (to when the sensing protocol began), and returns to progressing forward in time (informing Mycroft about the interaction).

Where I stayed in Stockholm. I swear, I’m not making this up.

In Sweden, I regarded my work with David and Aidan as a lark. But it’s led to an experiment, another experiment, and two papers set to debut this winter. I even pass as a quantum metrologist nowadays. Perhaps I should have anticipated the metamorphosis, as I should have anticipated the extra springtimes that erupted as I traveled between north and south. As the bard says, there’s a time for all things.

¹In the sequel, Fforde adds a twist to Next’s closed timelike curve. I can’t speak for the twist’s plausibility or logic, but it makes for delightful reading, so I commend the novel to you.

²You might recall that Sherlock Holmes has a brother, named Mycroft, who’s an inventor. Why? In Fforde’s novel, an evil corporation pursues Mycroft, who’s built a device that can transport him into the world of a book. Mycroft uses the device to hide from the corporation in Sherlock Holmes’s backstory.

³Experts, Mycroft implements the effective teleportation as follows: He prepares a fourth particle in the ideal initial sensor state. Then, he performs a two-outcome entangling measurement on particles 3 and 4: he asks “Are particles 3 and 4 in the state in which particles 1 and 3 began?” If the measurement yields the yes outcome, Mycroft has effectively teleported the ideal sensor state backward in time. He’s also simulated a closed timelike curve. If the measurement yields the no outcome, Mycroft fails to measure the interaction optimally. Figure 1 in our paper synopsizes the protocol.

by Nicole Yunger Halpern at December 15, 2025 04:19 PM

December 12, 2025

Matt von Hippel — Energy Is That Which Is Conserved

In school, kids learn about different types of energy. They learn about solar energy and wind energy, nuclear energy and chemical energy, electrical energy and mechanical energy, and potential energy and kinetic energy. They learn that energy is conserved, that it can never be created or destroyed, but only change form. They learn that energy makes things happen, that you can use energy to do work, that energy is different from matter.

Some, between good teaching and good students, manage to impose order on the jumble of concepts and terms. Others end up envisioning the whole story a bit like Pokemon, with different types of some shared “stuff”.

Energy isn’t “stuff”, though. So what is it? What relates all these different types of things?

Energy is something which is conserved.

The mathematician Emmy Noether showed that, when the laws of physics are symmetrical, they come with a conserved quantity. For example, because the laws of the physics are the same from place to place, momentum is conserved. Similarly, because the laws of physics are the same from one time to another, Noether’s theorem states that there must be some quantity related to time, some number we can calculate, that is conserved, even as other things change. We call that number energy.

If energy is that simple, why are there all those types?

Energy is a number we can calculate. It’s a number we can calculate for different things. If you have a detailed description of how something in physics works, you can use that description to calculate that thing’s energy. In school, you memorize formulas like $\frac{1}{2}m v^2$ and $m g h$ . These are all formulas that, with a bit more knowledge, you could calculate. They are the things that, for a something that meets the conditions, are conserved. They are things that, according to Noether’s theorem, stay the same.

Because of this, you shouldn’t think of energy as a substance, or a fuel. Energy is something we can do: we physicists, and we students of physics. We can take a physical system, and see what about it ought to be conserved. Energy is an action, a calculation, a conceptual tool that can be used to make predictions.

Most things are, in the end.

by 4gravitons at December 12, 2025 05:00 PM

Tommaso Dorigo — Living At The Polar Circle

Since 2022, when I got invited for a keynote talk at a Deep Learning school, I have been visiting with increasing frequency the northern Sweden town of Lulea, and its Technology University (LTU). In 2023 I spent three months there, invited by Marcus Liwicki and Fredrik Sandin to join the Machine Learning group for some studies of neuromorphic computing applications to particle detectors. Then toward the end of 2023 they were able to secure funding to invite me as a WASP Guest Professor. I thus spent at LTU some four months in 2024, but this year I have spent there over 6 months, as the research collaboration with the computer scientists of LTU has become more intensive.

by Tommaso Dorigo at December 12, 2025 02:47 PM

December 11, 2025

Scott Aaronson Understanding vs. impact: the paradox of how to spend my time

Not long ago William MacAskill, the founder of the Effective Altruist movement, visited Austin, where I got to talk with him in person for the first time. I was a fan of his book What We Owe the Future, and found him as thoughtful and eloquent face-to-face as I did on the page. Talking to Will inspired me to write the following short reflection on how I should spend my time, which I’m now sharing in case it’s of interest to anyone else.

By inclination and temperament, I simply seek the clearest possible understanding of reality. This has led me to spend time on (for example) the Busy Beaver function and the P versus NP problem and quantum computation and the foundations of quantum mechanics and the black hole information puzzle, and on explaining whatever I’ve understood to others. It’s why I became a professor.

But the understanding I’ve gained also tells me that I should try to do things that will have huge positive impact, in what looks like a pivotal and even terrifying time for civilization. It tells me that seeking understanding of the universe, like I’ve been doing, is probably nowhere close to optimizing any values that I could defend. It’s self-indulgent, a few steps above spending my life learning to solve Rubik’s Cube as quickly as possible, but only a few. Basically, it’s the most fun way I could make a good living and have a prestigious career, so it’s what I ended up doing. I should be skeptical that such a course would coincidentally also maximize the good I can do for humanity.

Instead I should plausibly be figuring out how to make billions of dollars, in cryptocurrency or startups or whatever, and then spending it in a way that saves human civilization, for example by making AGI go well. Or I should be convincing whatever billionaires I know to do the same. Or executing some other galaxy-brained plan. Even if I were purely selfish, as I hope I’m not, still there are things other than theoretical computer science research that would bring more hedonistic pleasure. I’ve basically just followed a path of least resistance.

On the other hand, I don’t know how to make billions of dollars. I don’t know how to make AGI go well. I don’t know how to influence Elon Musk or Sam Altman or Peter Thiel or Sergey Brin or Mark Zuckerberg or Marc Andreessen to do good things rather than bad things, even when I have gotten to talk to some of them. Past attempts in this direction by extremely smart and motivated people—for example, those of Eliezer Yudkowsky and Sam Bankman-Fried—have had, err, uneven results, to put it mildly. I don’t know why I would succeed where they failed.

Of course, if I had a better understanding of reality, I might know how better to achieve prosocial goals for humanity. Or I might learn why they were actually the wrong goals, and replace them with better goals. But then I’m back to the original goal of understanding reality as clearly as possible, with the corresponding danger that I spend my time learning to solve Rubik’s Cube faster.

by Scott at December 11, 2025 05:49 PM

December 10, 2025

John Preskill — Can AI Predict the Quantum Universe?

AI promises to revolutionize the way we do science, which raises a central technological question of our time: Can classical AI understand all natural phenomena, or are some fundamentally beyond its reach? Many proponents of artificial intelligence argue that any pattern that can be generated or found in nature can be efficiently discovered and modeled by a classical learning algorithm, implying that AI is a universal and sufficient tool for science.

The word “classical” is important here to contrast with quantum computation. Nature is quantum mechanical, and the insights of Shor’s algorithm [1] along with quantum error correction [2,3,4] teach us that there are quantum systems, at least ones that have been heavily engineered, that can have trajectories that are fundamentally unpredictable¹ by any classical algorithm, including AI. This opens the possibility that there are complex quantum phenomena occurring naturally in our universe where classical AI is insufficient, and we need a quantum computer in order to model them.

This essay uses the perspective of computational complexity to unpack this nuanced question. We begin with quantum sampling, arguing that despite clear quantum supremacy, it does not represent a real hurdle for AI to predict quantum phenomena. We then shift to the major unsolved problems in quantum physics and quantum chemistry, examining how quantum computers could empower AI in these domains. Finally, we’ll consider the possibility of truly complex quantum signals in nature, where quantum computers might prove essential for prediction itself.

Quantum Sampling

In 2019 Google demonstrated quantum supremacy on a digital quantum device [5], and in 2024 their latest chip performed a task in minutes where our best classical computers would take 10^25 years [6]. The task they performed is to prepare a highly entangled many-body quantum state and to sample from the corresponding distribution over classical configurations. Quantum supremacy on such sampling problems is on firm ground, with results in complexity theory backing up the experimental claims [7].² Moreover, the classical hardness of quantum sampling appears to be generic in quantum physics. A wide range of quantum systems will generate highly entangled many-body states where sampling becomes classically hard.

However, quantum sampling alone does not refute the universality of classical AI. The output of quantum sampling often appears completely featureless, which cannot be verified by any classical or quantum algorithm, or by any process in our universe for that matter. For example, running the exact same sampling task a second time will produce a list of configurations that will appear unrelated to the original. In order for a phenomenon to be subject to scientific prediction, there must be an experiment that can confirm or deny the prediction. So if quantum sampling has no features that can be experimentally verified, there is nothing to predict, and no pattern for the AI to discover and model.

Quantum Chemistry and Condensed Matter Physics

There are many unsolved problems in quantum chemistry and condensed matter physics that are inaccessible using our best classical simulation algorithms and supercomputers. For example, these occur in the strongly correlated regime of electronic structure in quantum chemistry, and around low-temperature phase transitions of condensed matter systems. We do not understand the electronic structure of FeMoco, the molecule responsible for nitrogen fixation in the nitrogenase enzyme, nor do we understand the phase diagram of the 2D Fermi-Hubbard lattice and whether or not it exhibits superconductivity.

It is possible there are no fundamental barriers for a sufficiently advanced AI to solve these problems. Researchers in the field have achieved major breakthroughs using neural networks to predict complex biological structures like protein folding. One could imagine similar specialized AI models that predict the electronic structure of molecules, or that predict quantum phases of matter. Perhaps the main reason it is currently out of reach is a lack of sufficient training data. Here lies a compelling opportunity for quantum computing: The only feasible way to generate an abundance of accurate training data may be to use a quantum computer, since physical experiments are too difficult, too unreliable, and too slow.

How should we view these problems in physics and chemistry from the perspective of computational complexity? Physicists and chemists often consider systems with a fixed number of parameters, or even single instances. Although computing physical quantities may be extremely challenging, single instances cannot form computationally hard problems, since ultimately only a constant amount of resources is required to solve it. Systems with a fixed number of parameters often behave similarly, since physical quantities tend to depend smoothly on the parameters which allows for extrapolation and learning [8]. Here we can recognize a familiar motif from machine learning: Ab initio prediction is challenging, but prediction becomes efficient after learning from data. Quantum computers are useful for generating training data, but then AI is able to learn from this data and perform efficient inference.

Truly Complex Quantum Signals

While AI might be able to learn much of the patterns of physics and chemistry from quantum-generated data, there remains a deeper possibility: The quantum universe may produce patterns that AI cannot compress and understand. If there are quantum systems that display signals that are truly classically complex, then predicting the pattern will require a quantum computer at inference time, not only in training.

We’ll now envision how such a signal could arise. Imagine a family of quantum systems of arbitrary size N, and at each size N there is a number of independent parameters that is polynomial in N, for example the coefficients of a Hamiltonian or the rotation angles of a quantum circuit. Suppose the system has some physical feature whose signal we would like to compute as a function of the parameters, and this signal has the following properties:

(Signal) There is a quantum algorithm that efficiently computes the signal. For example, the signal cannot be exponentially small in N.
(Verifiable) The signal is verifiable, at least by an ideal quantum computer. For example, the task could be to compute an expectation value.
(Typically complex) When the parameters are chosen randomly, the signal is computationally hard to classically compute in the average case.

If these properties hold, then it’s possible that no machine learning model using a polynomial amount of classical compute can perform the task, even with the help of training data.

The requirement of verifiability by a quantum process ensures that the signal being computed is a robust phenomenon where there is some “fact of the matter”, and a prediction can be confirmed or denied by nature. For example, this holds for any task where the output is the expectation value of some observable. The average-case hardness ensures that hard instances really exist and can be easily generated, rather than only existing in some abstract worst-case that cannot be instantiated.

There is a connection between the verifiability of a computation and its utility to us. Suppose we use a computer to help us design a high-temperature superconductor. If our designed material indeed works as a high-temperature superconductor when fabricated, this forms a verification of the predictions made by our computer. Utility implies verifiability, and likewise, unverifiable computations cannot be useful. However, since nature is quantum, a computation need not be classically verifiable in order to be useful, but only quantumly verifiable. In our high-temperature superconductor example, nature has verified our computer by performing a quantum process.

Making progress

John Preskill’s “entanglement frontier” seeks to understand the collective behavior of many interacting quantum particles [10]. In order to shed light on the fundamental limits of classical AI and the utility of quantum computers in this regime, we must understand if the exponential Hilbert space of quantum theory remains mostly hidden, or if it reveals itself in observable phenomena. The search for classically complex signals forms an exciting research program for making progress. Google recently performed the first demonstration of a classically complex signal on a quantum device: The out-of-time-order correlators³ of random quantum circuits [9]. We can seek to find more such examples, first in abstract models, and then in the real world, to understand how abundant they are in nature.

Under widely accepted cryptographic assumptions. ︎
Classical computers cannot perform quantum sampling unless the polynomial hierarchy collapses. ︎
More precisely, the higher moments of the out-of-time-order correlator. ︎

References

[1] Shor, Peter W. “Algorithms for quantum computation: discrete logarithms and factoring.” Proceedings 35th annual symposium on foundations of computer science. Ieee, 1994.

[2] Shor, Peter W. “Scheme for reducing decoherence in quantum computer memory.” Physical review A 52.4 (1995): R2493.

[3] Shor, Peter W. “Fault-tolerant quantum computation.” Proceedings of 37th conference on foundations of computer science. IEEE, 1996.

[4] Kitaev, A. Yu. “Fault-tolerant quantum computation by anyons.” Annals of physics 303.1 (2003): 2-30.

[5] Arute, Frank, et al. “Quantum supremacy using a programmable superconducting processor.” Nature 574.7779 (2019): 505-510.

[6] Morvan, Alexis, et al. “Phase transitions in random circuit sampling.” Nature 634.8033 (2024): 328-333.

[7] Aaronson, Scott, and Alex Arkhipov. “The computational complexity of linear optics.” Proceedings of the forty-third annual ACM symposium on Theory of computing. 2011.

[8] Huang, Hsin-Yuan, et al. “Provably efficient machine learning for quantum many-body problems.” Science 377.6613 (2022): eabk3333.

[9] Abanin, Dmitry A., et al. “Constructive interference at the edge of quantum ergodic dynamics.” arXiv preprint arXiv:2506.10191 (2025).

[10] Preskill, John. “Quantum computing and the entanglement frontier.” arXiv preprint arXiv:1203.5813 (2012).

by robbieking1000 at December 10, 2025 11:38 PM

Terence Tao — The Equational Theories Project: Advancing Collaborative Mathematical Research at Scale

Matthew Bolan, Joachim Breitner, Jose Brox, Nicholas Carlini, Mario Carneiro, Floris van Doorn, Martin Dvorak, Andrés Goens, Aaron Hill, Harald Husum, Hernán Ibarra Mejia, Zoltan Kocsis, Bruno Le Floch, Amir Livne Bar-on, Lorenzo Luccioli, Douglas McNeil, Alex Meiburg, Pietro Monticone, Pace P. Nielsen, Emmanuel Osalotioman Osazuwa, Giovanni Paolini, Marco Petracci, Bernhard Reinke, David Renshaw, Marcus Rossel, Cody Roux, Jérémy Scanvic, Shreyas Srinivas, Anand Rao Tadipatri, Vlad Tsyrklevich, Fernando Vaquerizo-Villar, Daniel Weber, Fan Zheng, and I have just uploaded to the arXiv our preprint The Equational Theories Project: Advancing Collaborative Mathematical Research at Scale. This is the final report for the Equational Theories Project, which was proposed in this blog post and also showcased in this subsequent blog post. The aim of this project was to see whether one could collaboratively achieve a large-scale systematic exploration of a mathematical space, which in this case was the implication graph between 4694 equational laws of magmas. A magma is a set ${G}$ equipped with a binary operation ${\diamond: G \times G \rightarrow G}$ (or, equivalently, a ${G \times G}$ multiplication table). An equational law is an equation involving this operation and a number of indeterminate variables. Some examples of equational laws, together with the number that we assigned to that law, include

${E1}$ (Trivial law): ${x = x}$
${E2}$ (Singleton law): ${x = y}$
${E43}$ (Commutative law): ${x \diamond y = y \diamond x}$
${E168}$ (Central groupoid law): ${x = (y \diamond x) \diamond (x \diamond z)}$
${E4512}$ (Associative law): ${x \diamond (y \diamond z) = (x \diamond y) \diamond z}$

Up to relabeling and symmetry, there turn out to be 4694 equational laws that involve at most four invocations of the magma operation ${\diamond}$ ; one can explore them in our “Equation Explorer” tool.

The aim of the project was to work out which of these laws imply which others. For instance, all laws imply the trivial law ${E1}$ , and conversely the singleton law ${E2}$ implies all the others. On the other hand, the commutative law ${E43}$ does not imply the associative law ${E4512}$ (because there exist magmas that are commutative but not associative), nor is the converse true. All in all, there are ${22,028,942}$ implications of this type to settle; most of these are relatively easy and could be resolved in a matter of minutes by an expert in college-level algebra, but prior to this project, it was impractical to actually do so in a manner that could be feasibly verified. Also, this problem is known to become undecidable for sufficiently long equational laws. Nevertheless, we were able to resolve all the implications informally after two months, and have them completely formalized in Lean after a further five months.

After a rather hectic setup process (documented in this personal log), progress came in various waves. Initially, huge swathes of implications could be resolved first by very simple-minded techniques, such as brute-force searching all small finite magmas to refute implications; then, automated theorem provers such as Vampire or Mace4 / Prover9 were deployed to handle a large fraction of the remainder. A few equations had existing literature that allowed for many implications involving them to be determined. This left a core of just under a thousand implications that did not fall to any of the “cheap” methods, and which occupied the bulk of the efforts of the project. As it turns out, all of the remaining implications were negative; the difficulty was to construct explicit magmas that obeyed one law but not another. To do this, we discovered a number of general constructions of magmas that were effective at this task. For instance:

Linear models, in which the carrier ${G}$ was a (commutative or noncommutative) ring and the magma operation took the form ${x \diamond y = ax + by}$ for some coefficients ${a,b}$ , turned out to resolve many cases.
We discovered a new invariant of an equational law, which we call the “twisting semigroup” of that law, which also allowed us to construct further examples of magmas that obeyed one law ${E}$ but not another ${E'}$ , by starting with a base magma ${M}$ that obeyed both laws, taking a Cartesian power ${M^n}$ of that magma, and then “twisting” the magma operation by certain permutations of ${\{1,\dots,n\}}$ designed to preserve ${E}$ but not ${E'}$ .
We developed a theory of “abelian magma extensions”, similar to the notion of an abelian extension of a group, which allowed us to flexibly build new magmas out of old ones in a manner controlled by a certain “magma cohomology group ${H^1_E(G,M)}$ ” which were tractable to compute, and again gave ways to construct magmas that obeyed one law ${E}$ but not another ${E'}$ .
Greedy methods, in which one fills out an infinite multiplication table in a greedy manner (somewhat akin to naively solving a Sudoku puzzle), subject to some rules designed to avoid collisions and maintain a law ${E}$ , as well as some seed entries designed to enforce a counterexample to a separate law ${E'}$ . Despite the apparent complexity of this method, it can be automated in a manner that allowed for many outstanding implications to be refuted.
Smarter ways to utilize automated theorem provers, such as strategically adding in additional axioms to the magma to help narrow the search space, were developed over the course of the project.

Even after applying all these general techniques, though, there were about a dozen particularly difficult implications that resisted even these more powerful methods. Several ad hoc constructions were needed in order to understand the behavior of magmas obeying such equations as E854, E906, E1323, E1516, and E1729, with the latter taking months of effort to finally solve and then formalize.

A variety of GUI interfaces were also developed to facilitate the collaboration (most notably the Equation Explorer tool mentioned above), and several side projects were also created within the project, such as the exploration of the implication graph when the magma was also restricted to be finite. In this case, we resolved all of the ${22,028,942}$ implications except for one (and its dual):

Problem 1 Does the law ${x = y \diamond (x \diamond ((y \diamond x) \diamond y))}$ (E677) imply the law ${x = ((x \diamond x) \diamond x) \diamond x}$ (E255) for finite magmas?

See this blueprint page for some partial results on this problem, which we were unable to resolve even after months of effort.

Interestingly, modern AI tools did not play a major role in this project (but it was largely completed in 2024, before the most recent advanced models became available); while they could resolve many implications, the older “good old-fashioned AI” of automated theorem provers were far cheaper to run and already handled the overwhelming majority of the implications that the advanced AI tools could. But I could imagine that such tools would play a more prominent role in future similar projects.

by Terence Tao at December 10, 2025 12:34 AM

December 07, 2025

Terence Tao — Growth rates of sequences governed by the squarefree properties of its translates

Wouter van Doorn and I have uploaded to the arXiv our paper “Growth rates of sequences governed by the squarefree properties of its translates“. In this paper we answer a number of questions of Erdős} (Problem 1102 and Problem 1103 on the Erdős problem web site) regarding how quickly a sequence ${A = \{a_1 < a_2 < \dots\}}$ of increasing natural numbers can grow if one constrains its translates ${n+A}$ to interact with the set ${\mathcal{SF} = \{1,2,3,5,6,7,10,\dots\}}$ of squarefree numbers in various ways. For instance, Erdős defined a sequence ${A}$ to have “Property ${P}$ ” if each of its translates ${n+A}$ only intersected ${\mathcal{SF}}$ in finitely many points. Erdős believed this to be quite a restrictive condition on ${A}$ , writing “Probably a sequence having property P must increase fairly fast, but I have no results in this direction.”. Perhaps surprisingly, we show that while these sequences must be of density zero, they can in fact grow arbitrary slowly in the sense that one can have ${a_j \leq j f(j)}$ for all sufficiently large ${j}$ and any specified function ${f(j)}$ that tends to infinity as ${j \rightarrow \infty}$ . For instance, one can find a sequence that grows like ${O(j \log\log\log j)}$ . The density zero claim can be proven by a version of the Maier matrix method, and also follows from known moment estimates on the gaps between squarefree numbers; the latter claim is proven by a greedy construction in which one slowly imposes more and more congruence conditions on the sequence to ensure that various translates of the sequence stop being squarefree after a certain point.

Erdős also defined a somewhat complementary property ${Q}$ , which asserts that for infinitely many ${n}$ , all the elements ${n+a}$ of ${A}$ for ${a \leq n}$ are square-free. Since the squarefree numbers themselves have density ${6/\pi^2}$ , it is easy to see that a sequence with property ${Q}$ must have (upper) density at most ${6/\pi^2}$ (because it must be “admissible” in the sense of avoiding one residue class modulo ${p^2}$ for each ${p}$ ). Erdős observed that any sufficiently rapidly growing (admissible) sequence would obey property ${Q}$ but beyond that, Erdős writes “I have no precise information about the rate of increase a sequence having property Q must have.”. Our results in this direction may also be surprising: we show that there exist sequences with property ${Q}$ with density exactly ${6/\pi^2}$ (or equivalently, ${a_j \sim \frac{\pi^2}{6} j}$ ). This requires a recursive sieve construction, in which one starts with an initial scale ${n}$ and finds a much larger number ${n'}$ such that ${n'+a}$ is squarefree for most of the squarefree numbers ${a \leq n'}$ (and all of the squarefree numbers ${a \leq n}$ ). We quantify Erdős’s remark by showing that an (admissible) sequence will necessarily obey property ${Q}$ once it grows significantly faster than ${\exp( C j \log j)}$ , but need not obey this property if it only grows like ${\exp(O(j^{1/2} \log^{1/2} j))}$ . This is achieved through further application of sieve methods.

A third property studied by Erdős is the property of having squarefree sums, so that ${a_i + a_j}$ is squarefree for all ${i,j}$ . Erdős writes, “In fact one can find a sequence which grows exponentially. Must such a sequence really increase so fast? I do not expect that there is such a sequence of polynomial growth.” Here our results are relatively weak: we can construct such a sequence that grows like ${\exp(O(j \log j))}$ , but do not know if this is optimal; the best lower bound we can produce on the growth, coming from the large sieve, is ${\gg j^{4/3}}$ . (Somewhat annoyingly, the precise form of the large sieve inequality we needed was not in the literature, so we have an appendix supplying it.) We suspect that further progress on this problem requires advances in inverse sieve theory.

A weaker property than squarefree sums (but stronger than property ${Q}$ ), referred to by Erdős as property ${\overline{P}}$ , asserts that there are infinitely many ${n}$ such that all elements of ${n+A}$ (not just the small ones) are square-free. Here, the situation is close to, but not quite the same, as that for property ${Q}$ ; we show that sequences with property ${\overline{P}}$ must have upper density strictly less than ${6/\pi^2}$ , but can have density arbitrarily close to this value.

Finally, we looked at a further question of Erdős on the size of an admissible set ${A}$ . Because the squarefree numbers are admissible, the maximum number ${A(x)}$ of elements of an admissible set ${A}$ up to ${x}$ (OEIS A083544) is at least the number ${|{\mathcal SF} \cap [x]|}$ of squarefree elements up to ${x}$ (A013928). It was observed by Ruzsa that the former sequence is greater than the latter for infinitely many ${x}$ . Erdős asked, “Probably this holds for all large x. It would be of some interest to estimate A(x) as accurately as possible.”

We are able to show

$\displaystyle \frac{\sqrt{x}}{\log x} \ll A(x) - \frac{6}{\pi^2} x \ll x^{4/5},$

with the upper bound coming from the large sieve and the lower bound from a probabilistic construction. In contrast, a classical result of Walfisz shows that

$\displaystyle |{\mathcal SF} \cap [x]| - \frac{6}{\pi^2} x \ll x^{1/2} \exp(-c \log^{3/5} x / (\log\log x)^{1/5}).$

Together, this implies that Erdős’s conjecture holds ${A(x) > |{\mathcal SF} \cap [x]|}$ for all sufficiently large ${x}$ . Numerically, it appears that in fact this conjecture holds for all ${n>17}$ :

However, we do not currently have enough numerical data for the sequence ${A(x)}$ to completely confirm the conjecture in all cases. This could potentially be a crowdsourced project (similar to the Erdős-Guy-Selfridge project reported on in this previous blog post).

by Terence Tao at December 07, 2025 06:22 PM

December 05, 2025

Matt von Hippel — Ideally, Exams Are for the Students

I should preface this by saying I don’t actually know that much about education. I taught a bit in my previous life as a professor, yes, but I probably spent more time being taught how to teach than actually teaching.

Recently, the Atlantic had a piece about testing accommodations for university students, like extra time on exams, or getting to do an exam in a special distraction-free environment. The piece quotes university employees who are having more and more trouble satisfying these accommodations, and includes the statistic that 20 percent of undergraduate students at Brown and Harvard are registered as disabled.

The piece has kicked off a firestorm on social media, mostly focused on that statistic (which conveniently appears just before the piece’s paywall). People are shocked, and cynical. They feel like more and more students are cheating the system, getting accommodations that they don’t actually deserve.

I feel like there is a missing mood in these discussions, that the social media furor is approaching this from the wrong perspective. People are forgetting what exams actually ought to be for.

Exams are for the students.

Exams are measurement tools. An exam for a class says whether a student has learned the material, or whether they haven’t, and need to retake the class or do more work to get there. An entrance exam, or a standardized exam like the SAT, predicts a student’s future success: whether they will be able to benefit from the material at a university, or whether they don’t yet have the background for that particular program of study.

These are all pieces of information that are most important to the students themselves, that help them structure their decisions. If you want to learn the material, should you take the course again? Which universities are you prepared for, and which not?

We have accommodations, and concepts like disability, because we believe that there are kinds of students for whom the exams don’t give this information accurately. We think that a student with more time, or who can take the exam in a distraction-free environment, would have a more accurate idea of whether they need to retake the material, or whether they’re ready for a course of study, than a student who has to take the exam under ordinary conditions. And we think we can identify the students who this matters for, and the students for whom this doesn’t matter nearly as much.

These aren’t claims about our values, or about what students deserve. They’re empirical claims, about how test results correlate with outcomes the students want. The conversation, then, needs to be built on top of those empirical claims. Are we better at predicting the success of students that receive accommodations, or worse? Can we measure that at all, or are we just guessing? And are we communicating the consequences accurately to students, that exam results tell them something useful and statistically robust that should help them plan their lives?

Values come in later, of course. We don’t have infinite resources, as the Atlantic piece emphasizes. We can’t measure everyone with as much precision as we would like. At some level, generalization takes over and accuracy is lost. There is absolutely a debate to be had about which measurements we can afford to make, and which we can’t.

But in order to have that argument at all, we first need to agree on what we’re measuring. And I feel like most of the people talking about this piece haven’t gotten there yet.

by 4gravitons at December 05, 2025 05:00 PM

December 04, 2025

n-Category Café Octonions and the Standard Model (Part 12)

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Having spent a lot of time pondering the octonionic projective plane and its possible role in the Standard Model of particle physics, I’m now getting interested in the ‘bioctonionic plane’, which is based on the bioctonions $\mathbb{C} \otimes \mathbb{O}$ rather than the octonions $\mathbb{O}$ .

The bioctonionic plane also has intriguing mathematically connections to the Standard Model. But it’s not a projective plane in the axiomatic sense — and it can’t be constructed by straightforwardly copying the way you build a projective plane over a division algebra, since unlike the octonions, the bioctonions are not a division algebra. Nonetheless we can define points and lines in the bioctonionic plane. The twist is that now some pairs of distinct lines intersect in more than one point — and dually, some pairs of distinct points lie on more than one line. It obeys some subtler axioms, so people call it a Hjelmslev plane.

I am not ready to give a really good explanation of the bioctonionic plane! Instead, I just want to lay out some basic facts about how it fits into mathematics — and possibly physics.

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Latham Boyle works at the University of Edinburgh, which is where I am now. Being able to talk to someone who deeply understands octonions and particle physics is very energizing. I’m especially fascinated by this paper of his:

Latham Boyle, The Standard Model, the exceptional Jordan algebra, and triality.

It gives a convincing argument that the bioctonionic plane may be better than the octonionic projective plane for particle physics. The reason is that the tangent space of any point of the bioctonionic plane is a copy of $(\mathbb{C} \otimes \mathbb{O})^2$ , a 16-dimensional complex vector space. The symmetry group of the bioctonionic plane is the exceptional Lie group $\text{E}_6$ . Sitting inside the stabilizer group of any given point is a copy of the Standard Model gauge group. And — here’s the cool part — this group acts on $(\mathbb{C} \otimes \mathbb{O})^2$ just as it does on one generation of fermions (not their antiparticles). If we try the same trick using the octonionic projective plane, we can fit the Standard Model gauge group in the stabilizer group of a point in a very natural way, but its action on the tangent space is its action only on left-handed fermions.

I want to explain this in detail, but not today. Instead, I want to skim through some basic facts about the bioctonionic plane.

First, this plane is one of the four Rosenfeld planes:

the octonionic projective plane $\mathbb{O}\text{P}^2$ , a 16-dimensional compact Riemannian manifold on which the compact Lie group $\text{F}_4$ acts transitively as isometries, with the stabilizer of any point being $\text{Spin}(9)$ . This is a symmetric space, and as such it’s called FII in Cartan’s classification.
the bioctonionic plane $(\mathbb{C} \otimes \mathbb{O})\mathbb{P}^2$ , a 32-dimensional compact Riemannian manifold on which the compact Lie group $\text{E}_6$ acts transitively as isometries, with the stabilizer of any point being $(\text{Spin}(10) \times \text{U}(1))/\mathbb{Z}_4$ . This is the symmetric space EIII.
the quateroctonionic plane $(\mathbb{H} \otimes \mathbb{O}) \mathbb{P}^2$ , a 64-dimensional compact Riemannian manifold on which the compact Lie group $\text{E}_7$ acts transitively as isometries, with the stabilizer of any point being $(\text{Spin}(12) \times \text{Sp}(1))/\mathbb{Z}_2$ . This is the symmetric space EVI.
the octooctonionic plane $(\mathbb{O} \otimes \mathbb{O}) \mathbb{P}^2$ , a 128-dimensional compact Riemannian manifold on which the compact Lie group $\text{E}_8$ acts transitively as isometries, with the stabilizer of any point being $\text{Spin}(16)/\mathbb{Z}_2$ . This is the symmetric space EVIII.

There’s a nice network of systematic approaches to these spaces: they form one row of the so-called magic square, so one way to learn about the bioctonionic plane is to study the magic square, for example here:

Chris H. Barton and Anthony Sudbery, Magic squares of Lie algebras. Available as arXiv:math/0001083; see also arXiv:0203010 for a “streamlined and extended” version, which has more yet also less.

Here you can also find lots of references to earlier work, e.g. to Freudenthal and Tits. The basic idea of the magic square is that you start with two normed division algebras $\mathbb{K}, \mathbb{K}'$ and from them you build a Lie algebra, which gives a Lie group $G(\mathbb{K},\mathbb{K}')$ . There’s also a way to get a subgroup $H(\mathbb{K}, \mathbb{K}')$ , and the quotient space

$(\mathbb{K} \otimes \mathbb{K}')\text{P}^2 = G(\mathbb{K},\mathbb{K}')/H(\mathbb{K}, \mathbb{K}')$

is a kind of ‘plane’ on which the group $G(\mathbb{K},\mathbb{K}')$ acts. If you take $\mathbb{K}' = \mathbb{O}$ , this construction gives you the four Rosenfeld planes listed above.

Each one of these planes is a compact Riemannian symmetric space: this means it’s a connected compact Riemannian manifold $M$ such that for each point $p \in M$ there’s an isometry

$\sigma_p \colon M \to M$

that fixes $p$ , acts as $-1$ on its tangent space, and squares to the identity. This map is called ‘reflection across $p$ ’ for the obvious reason. For example, a round 2-sphere is a symmetric space, with $\sigma_p$ switching the red and blue tangent vectors if $p$ is the black dot:

Cartan classified compact Riemannian symmetric spaces, and there’s a nice theory of them. Any compact simple Lie group is one, and most of the rest come in infinite series connected to real and complex Clifford algebras, as I explained here. But there are 9 extra ones, all related to the octonions and exceptional Lie groups. The Rosenfeld planes are four of these.

You can learn this material starting on Wikipedia and then going to a textbook, ideally this:

Sigurdur Helgason, Differential Geometry, Lie Groups and Symmetric Spaces, Academic Press, 1978.

Helgason taught me Lie theory when I was a grad student at MIT, so I have a fondness for his book—but it’s also widely accepted as the most solid text on symmetric spaces!

The bioctonionic plane is even better: it’s a compact hermitian symmetric space: a compact Riemannian symmetric space $M$ where each tangent space $T_p M$ has a complex structure

$J \colon T_p M \to T_p M , \qquad J^2 = -1$

compatible with the metric, and reflection about each point preserves this complex structure. I mentioned that the bioctonionic plane is

$(\mathbb{C} \otimes \mathbb{O})\text{P}^2 \cong G(\mathbb{C},\mathbb{O})/H(\mathbb{C},\mathbb{O})$

where

$G(\mathbb{C},\mathbb{O}) = \text{E}_6$

acts transitively, and the stabilizer of a point is

$H(\mathbb{C}, \mathbb{O}) = (\text{Spin}(10) \times \text{U}(1))/\mathbb{Z}_4$

The $\text{U}(1)$ here comes from the complex structure!

Wikipedia is especially thorough on hermitian symmetric spaces, so if you want to delve into those, start here:

Wikipedia, Hermitian symmetric space.

Another tack is to focus on the exceptional Lie groups $\text{F}_4, \text{E}_6, \text{E}_7$ and $\text{E}_8$ and their connection to the nonassociative algebras $\mathfrak{h}_3(\mathbb{O})$ , $\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O})$ , $\mathfrak{h}_3(\mathbb{H} \otimes \mathbb{O})$ and $\mathfrak{h}_3(\mathbb{O} \otimes \mathbb{O})$ , respectively. Here I recommend this:

Ichiro Yokota, Exceptional Lie Groups. Available as arXiv:0902.0431. (See especially Chapter 3, for $\text{E}_6$ and the complexified exceptional Jordan algebra $\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O})$ .)

If you have a fondness for algebra you may also want to learn how symmetric spaces arise from Jordan triple systems or Jordan pairs. This is important if we wish to see the bioctonionic plane as the space of pure states of some exotic quantum system!

Now, this is much easier to do for the octonionic plane, because that’s the space of pure states for the exceptional Jordan algebra $\mathfrak{h}_3(\mathbb{O})$ , which is a Euclidean Jordan algebra, meaning one in which a sum of squares can only be zero if all those squares are zero. You can think of a Euclidean algebra $A$ as consisting of observables, with the sums of squares being ‘nonnegative’ observables. These nonnegative observables form a convex cone $K \subseteq A$ . The dual vector space $A^\ast$ contains a cone of linear functionals $f$ that send these nonnegative observables to nonnegative real numbers — I’ll call this the dual cone $K^\ast$ . The functionals $f \in K^\ast$ with $f(1) = 1$ are called states. The states form a convex set, and the extreme points are called pure states. All of this fits nicely into a modern framework for understanding quantum theory and potential generalizations, called ‘generalized probabilistic theories’:

Howard Barnum, Alexander Wilce, Post-classical probability theory, in Quantum Theory: Informational Foundations and Foils, eds. Giulio Chiribella, Robert W. Spekkens, Springer, 2016. (See Section 5 for Jordan algebras, and ignore the fact that they say the exceptional Jordan algebra consists of $2 \times 2$ matrices: they know perfectly well that they’re $3 \times 3$ .)

The underlying math, with a lot more about symmetric spaces, cones and Euclidean Jordan algebras but with none of the physics interpretation, is wonderfully explained here:

Jacques Faraut and Adam Korányi, Analysis on Symmetric Cones, Oxford U. Press, 1994.

A crucial fact throughout this book is that when you start with a Euclidean Jordan algebra $A$ , its cone $K$ of nonnegative observables is self-dual: there’s an isomorphism of vector spaces $A \cong A^\ast$ that maps $K$ to $K^\ast$ in a one-to-one and onto way. The cone $K$ is also homogeneous, meaning that the group of invertible linear transformations of $A$ preserving $K$ acts transitively on the interior of $K$ . Faraut and Korányi call a self-dual homogeneous cone a symmetric cone — and they show that any symmetric cone comes from a Euclidean Jordan algebra! This result plays an important role in modern work on the foundations of quantum theory.

Unfortunately, I’m telling you all this nice stuff about Euclidean Jordan algebras and symmetric cones just to say that while all this applies to the octonionic projective plane, sadly, it does not apply to the bioctonionic plane! The bioctonionic plane does not come from a Euclidean Jordan algebra or a symmetric cone. Thus, to understand it as a space of pure states, we’d have to resort to a more general formalism.

There are a few papers that attempt exactly this:

Lawrence C. Biedenharn and Piero Truini, An $\mathcal{E}_6 \otimes \mathcal{U}(1)$ invariant quantum mechanics for a Jordan pair, Journal of Mathematical Physics 23 (1982), 1327-1345.
Lawrence C. Biedenharn and Piero Truini, Exceptional groups and elementary particle structures, Physica A: Statistical Mechanics and its Applications 14 (1982), 257–270.
Lawrence C. Biedenharn, G. Olivieri and Piero Truini, Three graded exceptional algebras and symmetric spaces, Zeitschrift Physik C — Particles and Fields 33 (1986), 47–65.

Here’s the basic idea. We can define $\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O})$ to consist of $3 \times 3$ hermitian matrices with entries in $\mathbb{C} \otimes \mathbb{O}$ , where ‘hermitian’ is defined using the star-algebra structure on $\mathbb{C} \otimes \mathbb{O}$ where we conjugate the octonion part but not the complex part! Then $\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O})$ is just the complexification of $\mathfrak{h}_3(\mathbb{O})$ :

$\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O}) \cong \mathbb{C} \otimes \mathfrak{h}_3(\mathbb{O})$

Then because $\mathfrak{h}_3(\mathbb{O})$ is a Jordan algebra over $\mathbb{R}$ , $\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O})$ is a Jordan algebra over $\mathbb{C}$ . So we can do a lot with it. But it’s not a Euclidean Jordan algebra.

Puzzle. Show that it’s not.

So, Biedenharn and Truini need a different approach to relate $\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O})$ to some sort of exotic quantum system. And they use an approach already known to mathematicians: namely, the theory of Jordan pairs! Here you work, not with a single element of $\mathfrak{h}_3(\mathbb{C} \otimes \mathbb{O})$ , but with a pair.

Jordan triple systems and Jordan pairs are two closely related generalizations of Jordan algebras. I’ve been working on the nLab articles about these concepts, so click the links if you want to learn more about them. I explain how either of these things gives you a 3-graded Lie algebra — that is, a $\mathbb{Z}$ -graded Lie algebra that is nonvanishing only in the middle 3 grades:

$\mathfrak{g} = \mathfrak{g}_{-1} \oplus \mathfrak{g}_0 \oplus \mathfrak{g}_1$

And from a 3-graded Lie algebra you can get a symmetric space $G/H$ where the Lie algebra of $G$ is $\mathfrak{g}$ and the Lie algebra of $H$ is $\mathfrak{g}_0$ . Each tangent space of this symmetric space is thus isomorphic to $\mathfrak{g}_{-1} \oplus \mathfrak{g}_1$ .

In the case relevant to the bioctonionic plane, the 3-graded Lie algebra is

$\mathfrak{e}_6 = (\mathbb{C} \otimes \mathbb{O}) \; \oplus \; (\mathfrak{so}(10) \oplus \mathbb{R}) \; \oplus \; (\mathbb{C} \otimes \mathbb{O})$

So, the bioctonionic plane is a symmetric space on which $\text{E}_6$ acts, with stabilizer group $\text{Spin}(10) \times \text{U}(1)$ (up to covering spaces), and with tangent space isomorphic to $(\mathbb{C} \otimes \mathbb{O})^2$ .

So all this is potentially very nice. For much more on this theory, try the work of Ottmar Loos:

Ottmar Loos, Symmetric Spaces, Volume 1: General Theory, W. A. Benjamin, 1969.
Ottmar Loos, Symmetric Spaces, Volume 2: Compact Spaces and Classification, W. A. Benjamin, 1969.
Ottmar Loos, Jordan Pairs, Lecture Notes in Mathematics 460, Springer, Berlin, 1975.
Ottmar Loos, Jordan triple systems, $R$ -spaces, and bounded symmetric domains, Bulletin of the American Mathematical Society 77 (1971), 558–561.
Ottmar Loos, Bounded Symmetric Domains and Jordan Pairs, Mathematical Lectures, University of California, Irvine, 1977.

That’s a lot of stuff! For a quick overview of Loos’ work, I find this helpful:

Kevin McCrimmon, Jordan Pairs, by Ottmar Loos, review in Bulletin of the American Mathematical Society 84 4 (1978), 685–690.

Unfortunately Loos does not delve into examples, particularly the bioctonionic plane. For that, try Biedenharn and Truini, and also these:

Daniele Corradetti, Alessio Marrani, David Chester and R. Aschheim, Conjugation matters: bioctonionic Veronese vectors and Cayley-Rosenfeld planes, Int. J. Geom. Meth. Mod. Phys. 19 (2022), 2250142.
Jian Qiu, Plücker coordinates and the Rosenfeld planes, Journal of Geometry and Physics 206 (2024), 105331.

To wrap things up, I should say a bit about ‘Hjelmslev planes’, since the bioctonionic plane is supposed to be one of these. Axiomatically, a Hjelmslev plane is a set $P$ of points, a set $L$ of lines, and an incidence relation between points and lines. We require that for any two distinct points there is at least one line incident to both, and for any two distinct line there is at least one point incident to both. If two points are incident to more than one line we say they are neighbors. If two lines are incident to more than one point we say they are neighbors. We demand that both these ‘neighbor’ relations are equivalence relations, and that if we quotient $P$ and $L$ by these equivalence relations, we get an axiomatic projective plane.

Challenge. What projective plane do we get if we apply this quotient construction to the bioctonionic plane?

My only guess is that we get the octonionic projective plane — but I don’t know why.

The literature on Hjelmslev planes seems a bit difficult, but I’m finding this to be a good introduction:

Joanne L. Hall and Asha Rao, An algorithm for constructing Hjelmslev planes, in Algebraic Design Theory and Hadamard Matrices, Springer, 2014.

The answer to my puzzle should be here, because they’re talking about Hjelmslev planes built using split octonion algebras (like $\mathbb{C} \otimes \mathbb{O}$ ):

Tonny A. Springer and Ferdinand D. Veldkamp, On Hjelmslev–Moufang planes, Mathematicsche Zeitschrift 107 (1968), 249–263.

But I don’t see the answer here yet!

Part 1. How to define octonion multiplication using complex scalars and vectors, much as quaternion multiplication can be defined using real scalars and vectors. This description requires singling out a specific unit imaginary octonion, and it shows that octonion multiplication is invariant under $\mathrm{SU}(3)$ .
Part 2. A more polished way to think about octonion multiplication in terms of complex scalars and vectors, and a similar-looking way to describe it using the cross product in 7 dimensions.
Part 3. How a lepton and a quark fit together into an octonion — at least if we only consider them as representations of $\mathrm{SU}(3)$ , the gauge group of the strong force. Proof that the symmetries of the octonions fixing an imaginary octonion form precisely the group $\mathrm{SU}(3)$ .
Part 4. Introducing the exceptional Jordan algebra $\mathfrak{h}_3(\mathbb{O})$ : the $3 \times 3$ self-adjoint octonionic matrices. A result of Dubois-Violette and Todorov: the symmetries of the exceptional Jordan algebra preserving their splitting into complex scalar and vector parts and preserving a copy of the $2 \times 2$ adjoint octonionic matrices form precisely the Standard Model gauge group.
Part 5. How to think of $2 \times 2$ self-adjoint octonionic matrices as vectors in 10d Minkowski spacetime, and pairs of octonions as left- or right-handed spinors.
Part 6. The linear transformations of the exceptional Jordan algebra that preserve the determinant form the exceptional Lie group $\mathrm{E}_6$ . How to compute this determinant in terms of 10-dimensional spacetime geometry: that is, scalars, vectors and left-handed spinors in 10d Minkowski spacetime.
Part 7. How to describe the Lie group $\mathrm{E}_6$ using 10-dimensional spacetime geometry. This group is built from the double cover of the Lorentz group, left-handed and right-handed spinors, and scalars in 10d Minkowski spacetime.
Part 8. A geometrical way to see how $\mathrm{E}_6$ is connected to 10d spacetime, based on the octonionic projective plane.
Part 9. Duality in projective plane geometry, and how it lets us break the Lie group $\mathrm{E}_6$ into the Lorentz group, left-handed and right-handed spinors, and scalars in 10d Minkowski spacetime.
Part 10. Jordan algebras, their symmetry groups, their invariant structures — and how they connect quantum mechanics, special relativity and projective geometry.
Part 11. Particle physics on the spacetime given by the exceptional Jordan algebra: a summary of work with Greg Egan and John Huerta.
Part 12. The bioctonionic projective plane and its connections to algebra, geometry and physics.

December 03, 2025

n-Category Café log|x| + C revisited

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A while ago on this blog, Tom posted a question about teaching calculus: what do you tell students the value of $\displaystyle\int \frac{1}{x}\,dx$ is? The standard answer is $\ln{|x|}+C$ , with $C$ an “arbitrary constant”. But that’s wrong if $\displaystyle\int$ means (as we also usually tell students it does) the “most general antiderivative”, since

$F(x) = \begin{cases} \ln{|x|} + C^- &\text{if}\;x\lt 0\\ \ln{|x|} + C^+ &\text{if}\;x\gt 0 \end{cases}$

is a more general antiderivative, for two arbitrary constants $C^-$ and $C^+$ . (I’m writing $\ln$ for the natural logarithm function that Tom wrote as $\log$ , for reasons that will become clear later.)

In the ensuing discussion it was mentioned that other standard indefinite integrals like $\displaystyle\int \frac{1}{x^2}\,dx = -\frac{1}{x} + C$ are just as wrong. This happens whenever the domain of the integrand is disconnected: the “arbitrary constant” $C$ is really only locally constant. Moreover, Mark Meckes pointed out that believing in such formulas can lead to mistaken calculations such as

$\int_{-1}^1 \frac{1}{x^2}\,dx = \left.-\frac{1}{x}\right]_{-1}^1 = -2$

which is “clearly nonsense” since the integrand is everywhere positive.

In this post I want to argue that there’s actually a very natural perspective from which $\displaystyle\int \frac{1}{x^2}\,dx = -\frac{1}{x} + C$ is correct, while $\displaystyle\int \frac{1}{x}\,dx = \ln{|x|}+C$ is wrong for a different reason.

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The perspective in question is complex analysis. Most of the functions encountered in elementary calculus are actually complex-analytic — the only real counterexamples are explicit “piecewise” functions and things like ${|x|}$ , which are mainly introduced as counterexamples to illustrate the meaning of continuity and differentiability. Therefore, it’s not unreasonable to interpret the indefinite integral $\displaystyle\int f(x)\,dx$ as asking for the most general complex-analytic antiderivative of $f$ . And the complex domain of $\frac{1}{z}$ and $\frac{1}{z^2}$ is $\mathbb{C}\setminus \{0\}$ , which is connected!

Thus, for instance, since $\frac{d}{d z}\left[-\frac{1}{z}\right] = \frac1{z^2}$ , it really is true that the most general (complex-analytic) antiderivative of $\frac{1}{z^2}$ is $-\frac{1}{z}+C$ for a single arbitrary constant $C$ , so we can write $\displaystyle\int \frac{1}{z^2}\,dz = -\frac{1}{z} + C$ . Note that any such antiderivative has the same domain $\mathbb{C}\setminus \{0\}$ as the original function.

In addition, the dodgy calculation

$\int_{-1}^1 \frac{1}{z^2}\,dz = \left.-\frac{1}{z}\right]_{-1}^1 = -2$

is actually correct if we interpret $\int_{-1}^1$ to mean the integral along some (in fact, any) curve in $\mathbb{C}$ from $-1$ to $1$ that doesn’t pass through the singularity $z=0$ . Of course, this doesn’t offend against signs because any such path must pass through non-real numbers, whose squares can contribute negative real numbers to the integral.

The case of $\displaystyle\int \frac{1}{z}\,dz$ is a bit trickier, because the complex logarithm is multi-valued. However, if we’re willing to work with multi-valued functions (which precisely means functions whose domain is a Riemann surface covering some domain in $\mathbb{C}$ ), we have such a multi-valued function that I’ll denote $\log$ (in contrast to the usual real-number function $\ln$ ) defined on a connected domain, and there we have $\frac{d}{d z}\left[ \log(z) \right] = \frac{1}{z}$ . Thus, the most general (complex-analytic) antiderivative of $\frac{1}{z}$ is $\log(z)+C$ where $C$ is a single arbitrary constant, so we can write $\displaystyle\int \frac{1}{z}\,dz = \log(z) + C$ .

What happened to $\ln{|x|}$ ? Well, as it happens, if $x$ is a negative real number and $Log$ denotes the principal branch of the complex logarithm, then $Log(x) = \ln{|x|} + i\pi$ , hence $\ln{|x|} = Log(x) - i\pi$ . Therefore, the antiderivative $\ln{|x|}$ for negative real $x$ is of the form $\Log(x)+C$ , where $\Log$ is a branch of the complex logarithm and $C$ is a constant (namely, $-i\pi$ ).

Of course it is also true that for positive real $x$ , the antiderivative $\ln{|x|} = \ln(x)$ is of the form $\Log(x)+C$ for some constant $C$ , but in this case the constant is $0$ . And changing the branch of the logarithm changes the constant by $2i\pi$ , so it can never make the constants $0$ and $-i\pi$ coincide. Thus, unlike $-\frac{1}{x} +C$ , the real-number function $\ln{|x|} + C$ in the “usual answer” is not the restriction to $\mathbb{R}\setminus \{0\}$ of any complex-analytic antiderivative of $\frac{1}{x}$ on a connected domain. This is what I mean by saying that $\displaystyle\int \frac{1}{x}\,dx = \ln{|x|}+C$ is now wrong for a different reason. And we can see that the analogous dodgy calculation

$\int_{-1}^1 \frac{1}{x}\,dx = \ln{|x|}\Big]_{-1}^1 = 0$

is also still wrong. If $\gamma$ is a path from $-1$ to $1$ in $\mathbb{C}\setminus \{0\}$ , the value of $\int_{\gamma} \frac{1}{x}\,dx$ depends on $\gamma$ , but it never equals $0$ : it’s always an odd integer multiple of $i\pi$ , depending on how many times $\gamma$ winds around the origin.

I’m surprised that no one in the previous discussion, including me, brought this up. Of course we probably don’t want to teach our elementary calculus students complex analysis (although I’m experimenting with introducing some complex numbers in second-semester calculus). But this perspective makes me less unhappy about writing $\displaystyle\int \frac{1}{x^2}\,dx = -\frac{1}{x} + C$ and $\displaystyle\int \frac{1}{x}\,dx = \log(x) + C$ (no absolute value!).

Tommaso Dorigo — Conferences Good And Bad, In A Profit-Driven Society

Nowadays researchers and scholars of all ages and specialization find themselves struggling with mailboxes pestered with invitations to conferences, invitations to submit papers to journals, invitations to participate in the editorial board of journals, invitations to receive prizes for this or that reason; and of course, 99% of the origin of these invitations are individuals running fake conferences, scam, or predatory journals. Spam filters are not extremely good at distinguishing good and bad invitations, so if one wants to avoid discarding prestigious opportunities the only option is a painful manual screening.

by Tommaso Dorigo at December 03, 2025 05:43 PM

Terence Tao — Climbing the cosmic distance ladder: another sample chapter

Five years ago, I announced a popular science book project with Tanya Klowden on the cosmic distance ladder, in which we released a sample draft chapter of the book, covering the “fourth rung” of the ladder, which for us meant the distances to the planets. In the intervening time, a number of unexpected events have slowed down this project significantly; but I am happy to announce that we have completed a second draft chapter, this time on the “seventh rung” of measuring distances across the Milky Way, which required the maturation of the technologies of photography and spectroscopy, as well as the dawn of the era of “big data” in the early twentieth century, as exemplified for instance by the “Harvard computers“.

We welcome feedback of course, and are continuing to work to complete the book despite the various delays. In the mean time, you can check out our instagram account for the project, or the pair of videos that Grant Sanderson (3blue1brown) produced with us on this topic, which I previously blogged about here.

Thanks to Clio Cresswell, Riley Tao, and Noah Klowden for comments and corrections.

by Terence Tao at December 03, 2025 05:48 AM

December 01, 2025

John Baez — Summer Research at Topos

You can now apply for the 2026 Summer Research Associate program at the Topos Institute! This is a great opportunity.

Details and instructions on how to apply are in the official announcement.

A few important points:

• The application deadline is January 16, 2026.
• The position is paid and in-person in Berkeley, California.

These positions will last for 8 – 10 weeks, starting in June 2026 and ending in August. Each position will be mentored by Topos research staff or a select number of invited mentors. All positions are 40 hours/week, and the salary starts at $30-$50/hour.

There’s a research track and an engineering track. For the research track, possible topics include:

• Computational category theory using CatColab (Rust/Typescript skills recommended)
• Double category theory
• Categorical statistics
• Polynomial functors
• Interacting dynamical systems
• Hybrid dynamical systems, attractor theory and fast-slow dynamics
• Proof assistants, formal verification, or structure editors
• Philosophical and ethical aspects of applied category theory

For the engineering track, possible topics include:

• Delivery and support of mathematical technologies for various scientific disciplines and applications, and/or analysis, documentation, or guidance on their uses.
• Designing, implementing, testing, and maintaining software at the Topos Institute, in close collaboration with the research staff and in line with institute’s scientific strategy and mission.
• Contributing to developing the CatColab platform, including front end development in TypeScript and/or back end development in Rust. You might also contribute to the mathematical core, written in Rust, as your mathematical experience permits.

All positions require collaboration within a multi-disciplinary research environment. Each summer research associate will complete a specific Topos project, and will write a blog post by the last week of their employment. These projects may include an internal talk, software contribution, or paper. Go here to see the accomplishments of previous research associates.

Topos is committed to building a team with diverse perspectives and life experiences, so those with personal or professional backgrounds underrepresented at Topos are highly encouraged to apply. They are dedicated to shaping the future of technology to ensure a more equitable and just world, and believe that a technology that supports a healthy society can only be built by an organization that supports its team members.

by John Baez at December 01, 2025 07:39 PM

Secret Blogging Seminar — Congress proposes cutting of all funding to US academics who mentor Chinese students

I’m writing to point out a potential law which should be gathering more opposition and attention in math academia: The Securing American Funding and Expertise from Adversarial Research Exploitation Act. This is an amendment to the 2026 National Defense Authorization Act which has passed the House and could be added to the final version of the bill during reconcilliation in the Senate. I’m pulling most of my information from an article in Science.

This act would ban any US scientist from receiving federal funding if they have, within the last five years, worked with anyone from China, Russia, Iran or North Korea, where “worked with” includes joint research, co-authorship on papers, or advising a foreign graduate student or postdoctoral fellow. As I said in my message to my senators, this is everyone. Every mathematician has advised Chinese graduate students or collaborated with Chinese mathematicians, because China is integrated into the academic world and is one fifth of the earth.

This obviously isn’t secret, since you can read about it in Science, but I am surprised that I haven’t heard more alarm. Obvious people to contact are your senators and your representatives. I would also suggest contacting members of the Senate armed services committee, who are in charge of reconciling the House and Senate versions of the bill.

by David Speyer at December 01, 2025 05:14 PM

November 30, 2025

n-Category Café Beyond the Geometry of Music

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Yesterday I had a great conversation with Dmitri Tymoczko about groupoids in music theory. But at this Higgs Centre Colloquium, he preferred to downplay groupoids and talk in a way physicists would enjoy more. Click here to watch his talk!

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What’s great is that Tymoczkyo not faking it: he’s really found deep ways in which symmetry shows up pervasively in music.

At first he tried to describe them geometrically using orbifolds, which are spaces in which some singular points have nontrivial symmetry groups, like the tip of a cone formed by modding out the plane by the action of the group $\mathbb{Z}/n$ . But then he realized that the geometry was less important than the symmetry, which you can describe using groupoids. That’s why his talk is called “Beyond the geometry of music”.

I’m helping him with his work on groupoids, and I hope he explains his work to mathematicians someday without pulling his punches. I didn’t get to interview him yesterday, but I’ll try to do that soon.

For now you can read his books A Geometry of Music and Harmony: an Owner’s Manual along with many papers. What I’ve read so far is really exciting.

November 28, 2025

Tommaso Dorigo — USERN: 10 Years Of Non-Profit Action Supporting Science Education And Research

The 10th congress of the USERN organization was held on November 8-10 in Campinas, Brazil. Some time has gone by, so it is due time for me to report on the event. I could not attend in person for a cause of force majeure, but I was connected via zoom, and I also delivered two recorded speeches plus one talk in one of the parallel "virtual session" that were run via zoom in the evenings (CET) after the in-person program of the day was over.

by Tommaso Dorigo at November 28, 2025 02:26 PM

November 27, 2025

John Preskill — What distinguishes quantum from classical thermodynamics?

Should you require a model for an Oxford don in a play or novel, look no farther than Andrew Briggs. The emeritus professor of nanomaterials speaks with a southern-English accent as crisp as shortbread, exhibits manners to which etiquette influencer William Hanson could aspire, and can discourse about anything from Bantu to biblical Hebrew. I joined Andrew for lunch at St. Anne’s College, Oxford, this month.¹ Over vegetable frittata, he asked me what unifying principle distinguishes quantum from classical thermodynamics.

With a thermodynamic colleague at the Oxford University Museum of Natural History

I’d approached quantum thermodynamics from nearly every angle I could think of. I’d marched through the thickets of derivations and plots; I’d journeyed from subfield to subfield; I’d gazed down upon the discipline as upon a landscape from a hot-air balloon. I’d even prepared a list of thermodynamic tasks enhanced by quantum phenomena: we can charge certain batteries at greater powers if we entangle them than if we don’t, entanglement can raise the amount of heat pumped out of a system by a refrigerator, etc. But Andrew’s question flummoxed me.

I bungled the answer. I toted out the aforementioned list, but it contained examples, not a unifying principle. The next day, I was sitting in an office borrowed from experimentalist Natalia Ares in New College, a Gothic confection founded during the late 1300s (as one should expect of a British college called “New”). Admiring the view of ancient stone walls, I realized how I should have responded the previous day.

View from a window near the office I borrowed in New College. If I could pack that office in a suitcase and carry it home, I would.

My answer begins with a blog post written in response to a quantum-thermodynamics question from a don at another venerable university: Yoram Alhassid. He asked, “What distinguishes quantum thermodynamics to quantum statistical mechanics?” You can read the full response here. Takeaways include thermodynamics’s operational flavor. When using an operational theory, we imagine agents who perform tasks, using given resources. For example, a thermodynamic agent may power a steamboat, given a hot gas and a cold gas. We calculate how effectively the agents can perform those tasks. For example, we compute heat engines’ efficiencies. If a thermodynamic agent can access quantum resources, I’ll call them “quantum thermodynamic.” If the agent can access only everyday resources, I’ll call them “classical thermodynamic.”

A quantum thermodynamic agent may access more resources than a classical thermodynamic agent can. The latter can leverage work (well-organized energy), free energy (the capacity to perform work), information, and more. A quantum agent may access not only those resources, but also entanglement (strong correlations between quantum particles), coherence (wavelike properties of quantum systems), squeezing (the ability to toy with quantum uncertainty as quantified by Heisenberg and others), and more. The quantum-thermodynamic agent may apply these resources as described in the list I rattled off at Andrew.

With Oxford experimentalist Natalia Ares in her lab

Yet quantum phenomena can impede a quantum agent in certain scenarios, despite assisting the agent in others. For example, coherence can reduce a quantum engine’s power. So can noncommutation. Everyday numbers commute under multiplication: 11 times 12 equals 12 times 11. Yet quantum physics features numbers that don’t commute so. This noncommutation underlies quantum uncertainty, quantum error correction, and much quantum thermodynamics blogged about ad nauseam on Quantum Frontiers. A quantum engine’s dynamics may involve noncommutation (technically, the Hamiltonian may contain terms that fail to commute with each other). This noncommutation—a fairly quantum phenomenon—can impede the engine similarly to friction. Furthermore, some quantum thermodynamic agents must fight decoherence, the leaking of quantum information from a quantum system into its environment. Decoherence needn’t worry any classical thermodynamic agent.

In short, quantum thermodynamic agents can benefit from more resources than classical thermodynamic agents can, but the quantum agents also face more threats. This principle might not encapsulate how all of quantum thermodynamics differs from its classical counterpart, but I think the principle summarizes much of the distinction. And at least I can posit such a principle. I didn’t have enough experience when I first authored a blog post about Oxford, in 2013. People say that Oxford never changes, but this quantum thermodynamic agent does.

In the University of Oxford Natural History Museum in 2013, 2017, and 2025. I’ve published nearly 150 Quantum Frontiers posts since taking the first photo!

¹Oxford consists of colleges similarly to how neighborhoods form a suburb. Residents of multiple neighborhoods may work in the same dental office. Analogously, faculty from multiple colleges may work, and undergraduates from multiple colleges may major, in the same department.

by Nicole Yunger Halpern at November 27, 2025 04:30 PM

Sean Carroll Thanksgiving

(Apologies for the ugly blog format. We had a bit of a crash, and are working to get the template back in working order.)

This year we give thanks for a crucially important idea that can mean very different things to different people: information. (We’ve previously given thanks for the Standard Model Lagrangian, Hubble’s Law, the Spin-Statistics Theorem, conservation of momentum, effective field theory, the error bar, gauge symmetry, Landauer’s Principle, the Fourier Transform, Riemannian Geometry, the speed of light, the Jarzynski equality, the moons of Jupiter, space, black hole entropy, electromagnetism, Arrow’s Impossibility Theorem, and quanta.)

“Information” is an idea that is everywhere in science and technology these days. From one angle it looks like such an obvious idea that it’s a bit startling to realize that information theory didn’t really come along until the work of Claude Shannon in the 1940s. From another, the idea has so many different shades of meaning that we shouldn’t be surprised (that’s a joke you will get in a bit) that it can be hard to understand.

Information theory is obviously an enormous subject, but we’re just giving thanks, not writing a textbook. I want to mention two ideas I find especially central. First, Shannon’s idea about relating information content to “surprisal.” Second, the very different intuitive notions of information that we get from engineering and physics.

Shannon, working at Bell Labs, was interested in the problem of how to send trustworthy signals efficiently over transatlantic cables. He was thinking about various ways to express information in a code: a set of symbols, each with a defined meaning. So a code might be an alphabet, or a set of words, or a literal cipher. And he noticed that there was a lot of redundancy in natural languages; the word “the” appears much more often in English than the word “axe,” although both have the same number of letters.

Let’s refer to each letter or symbol in a code as an “event.” Shannon’s insight was to realize that the more unlikely an event, the more information it conveyed when it was received. The statements “The Sun rose in the east this morning” and “The Sun rose in the west this morning” contain the same number of letters, but the former contains almost no information — you already were pretty sure the Sun would be rising in the east. But the latter, if obtained from a reliable source, would be very informative indeed, precisely because it was so unexpected. Clearly some kind of unprecedented astronomical catastrophe was in progress.

Imagine we can assign a probability $p(x)$ to every different event $x$ . Shannon wanted a way to quantify the information content of that event, which would satisfy various reasonable-seeming axioms: most crucially, that the information content of two independent events is the sum of the individual information contents. But the joint probability of two events is the product of their individual probabilities. So the natural thing to do would be to define the information content as the logarithm of the probability; the logarithm of a product equals the sum of the individual logarithms. But you want low probability to correspond to high information content, so Shannon defined the information content (also called the self-information, or surprisal, or Shannon information) of an event to be minus the log of the probability, which by math is equal to the log of the reciprocal of the probability:

$I(x) = - \log [p(x)] =\log \left(\frac{1}{p(x)}\right).$

Note that probabilities are numbers between 0 and 1, and the log of such a number will be negative, with numbers closer to 0 being more negative than numbers closer to 1. So $I(x)$ goes from $+\infty$ at $p(x)=0$ to $0$ at $p(x)=1$ . An impossible message is infinitely surprising, and therefore conveys infinite information; an inevitable message is completely unsurprising, and conveys no information at all.

From there, Shannon suggested that we could characterize how efficient an entire code was at conveying information: just calculate the average (expectation value) of the information content for all possible events. When we have a probability distribution $p(x)$ , the average of any function $f(x)$ is just the sum of the the values of the function times their respective probabilities, $\langle f\rangle = \sum_x p(x) f(x)$ . So we characterize the information content of a code via the quantity

$H[p] = - \sum_x p(x) \log[p(x)].$

The only question is, what to call this lovely newly-defined quantity that surely nobody had ever thought of before? Happily Shannon was friends with John von Neumann, who informed him, “You should call it entropy, for two reasons. In the first place your uncertainty function has been used in statistical mechanics under that name, so it already has a name. In the second place, and more important, no one really knows what entropy really is, so in a debate you will always have the advantage.” So entropy it is.

Indeed, this formula is precisely that which had been put forward (unknown to Shannon) by Josiah Willard Gibbs in the 1870’s as a definition of entropy in statistical mechanics. (It is related to the definition on Ludwig Boltzmann’s tombstone, $S= k \log W$ , and Boltzmann had also suggested similar expressions to the above.) On the one hand, it seems remarkable to find precisely the same expression playing central roles in problems as disparate as sending signals across cables and watching cream mix into coffee; on the other hand, it’s a relatively simple expression and the axioms used to derive it are actually pretty similar, so perhaps we shouldn’t be surprised; on the third hand, the connection between information theory and statistical mechanics turns out to be deep and fruitful, so it’s more than just a mathematical coincidence.

But let me highlight the one aspect of the term “information” that can be sometimes confusing to people. To the engineer, a code that is maximally informative is one for which $p(x)$ is relatively uniform over all events $x$ , which means $H[p(x)]$ is maximal or close to it; in that case, every event will tell you something at least a little bit interesting. For them, high entropy = high information.

But to a physicist who might be asking “how much information do I have about the state of a system?”, you have more information when $p(x)$ is relatively narrowly concentrated around some value, rather than being all spread out. For them, high entropy = low information! Indeed, one physically-relevant notion of “information” is the “accessible information” of a system, which can be defined as $H_\mathrm{max} - H$ . (I talk about this a bit in my recent solo podcast on complexity.)

Perhaps we shouldn’t be so surprised that physicists and engineers posit oppositely-directed relationships between entropy and information. It’s just a reflection of the fact that “information” is so ubiquitous and has so many different uses. We should be thankful that we’re beginning to understand it so well.

by Sean Carroll at November 27, 2025 03:15 PM

November 26, 2025

Tim Gowers — Creating a database of motivated proofs

It’s been over three years since my last post on this blog and I have sometimes been asked, understandably, whether the project I announced in my previous post was actually happening. The answer is yes — the grant I received from the Astera Institute has funded several PhD students and a couple of postdocs, and we have been busy. In my previous post I suggested that I would be open to remote collaboration, but that has happened much less, partly because a Polymath-style approach would have been difficult to manage while also ensuring that my PhD students would have work that they could call their own to put in their theses.

In general I don’t see a satisfactory solution to that problem, but in this post I want to mention a subproject of the main project that is very much intended to be a large public collaboration. A few months ago, a call came out from Renaissance Philanthropies saying that they were launching a $9m AI for Math Fund to spend on projects in the general sphere of AI and mathematics, and inviting proposals. One of the categories that they specifically mentioned was creating new databases, and my group submitted a proposal to create a database of what we call “structured motivated proofs,” a piece of terminology that I will explain a bit more later in just a moment. I am happy to report that our proposal was one of the 29 successful ones. Since a good outcome to the project will depend on collaboration from many people outside the group, we need to publicize it, which is precisely the purpose of this post. Below I will be more specific about the kind of help we are looking for.

Why might yet another database of theorems and proofs be useful?

The underlying thought behind this project is that AI for mathematics is being held back not so much by an insufficient quantity of data as by the wrong kind of data. (For a more general exploration of this theme, see here.) All mathematicians know, and some of us enjoy complaining about it, that it is common practice when presenting a proof in a mathematics paper, or even textbook, to hide the thought processes that led to the proof. Often this does not matter too much, because the thought processes may be standard ones that do not need to be spelt out to the intended audience. But when proofs start to get longer and more difficult, they can be hard to read because one has to absorb definitions and lemma statements that are not obviously useful, are presented as if they appeared from nowhere, and demonstrate their utility only much later in the argument.

A sign that this is a problem for AI is the behaviour one observes after asking an LLM to prove a statement that is too difficult for it. Very often, instead of admitting defeat, it will imitate the style of a typical mathematics paper and produce rabbits out of hats, together with arguments later on that those rabbits do the required job. The problem is that, unlike with a correct mathematics paper, one finds when one scrutinizes the arguments carefully that they are wrong. However, it is hard to find superficial features that distinguish between an incorrect rabbit with an incorrect argument justifying that rabbit (especially if the argument does not go into full detail) and a correct one, so the kinds of statistical methods used by LLMs do not have an easy way to penalize the incorrectness.

Of course, that does not mean that LLMs cannot do mathematics at all — they are remarkably good at it, at least compared with what I would have expected three years ago. How can that be, given the problem I have discussed in the previous paragraph?

The way I see it (which could change — things move so fast in this sphere), the data that is currently available to train LLMs and other systems is very suitable for a certain way of doing mathematics that I call guess and check. When trying to solve a maths problem, you will normally write down the routine parts of an argument without any fuss (and an LLM can do them too because it has seen plenty of similar examples), but if the problem as a whole is not routine, then at some point you have to stop and think, often because you need to construct an object that has certain properties (I mean this in a rather general way — the “object” might be a lemma that will split up the proof in a nice way) and it is not obvious how to do so. The guess-and-check approach to such moments is what it says: you make as intelligent a guess as you can and then see whether it has the properties you wanted. If it doesn’t, you make another guess, and you keep going until you get lucky.

The reason an LLM might be tempted to use this kind of approach is that the style of mathematical writing I described above makes it look as though that is what we as mathematicians do. Of course, we don’t actually do that, but we tend not to mention all the failed guesses we made and how we carefully examined why they failed, modifying them in appropriate ways in response, until we finally converged on an object that worked. We also don’t mention the reasoning that often takes place before we make the guess, saying to ourselves things like “Clearly an Abelian group can’t have that property, so I need to look for a non-Abelian group.”

Intelligent guess and check works well a lot of the time, particularly when carried out by an LLM that has seen many proofs of many theorems. I have often been surprised when I have asked an LLM a problem of the form $\exists x\in X \ P(x)$ , where $P$ is some property that is hard to satisfy, and the LLM has had no trouble answering it. But somehow when this happens, the flavour of the answer given by the LLM leaves me with the impression that the technique it has used to construct $x$ is one that it has seen before and regards as standard.

If the above picture of what LLMs can do is correct (the considerations for reinforcement-learning-based systems such as AlphaProof are not identical but I think that much of what I say in this post applies to them too for slightly different reasons), then the likely consequence is that if we pursue current approaches, then we will reach a plateau: broadly speaking they will be very good at answering a question if it is the kind of question that a mathematician with the right domain expertise and good instincts would find reasonably straightforward, but will struggle with anything that is not of that kind. In particular, they will struggle with research-level problems, which are, almost by definition, problems that experts in the area do not find straightforward. (Of course, there would probably be cases where an LLM spots relatively easy arguments that the experts had missed, but that wouldn’t fundamentally alter the fact that they weren’t really capable of doing research-level mathematics.)

But what if we had a database of theorems and proofs that did not hide the thought processes that lay behind the non-obvious details of the proofs? If we could train AI on a database of accounts of proof discoveries and if, having done so, we then asked it to provide similar accounts, then it would no longer resort to guess-and-check when it got stuck, because the proof-discovery accounts it had been trained on would not be resorting to it. There could be a problem getting it to unlearn its bad habits, but I don’t think that difficulty would be impossible to surmount.

The next question is what such a database might look like. One could just invite people to send in stream-of-consciousness accounts of how they themselves found certain proofs, but that option is unsatisfactory for several reasons.

It can be very hard to remember where an idea came from, even a few seconds after one has had it — in that respect it is like a dream, the memory of which becomes rapidly less vivid as one wakes up.
Often an idea will seem fairly obvious to one person but not to another.
The phrase “motivated proof” means different things to different people, so without a lot of careful moderation and curation of entries, there is a risk that a database would be disorganized and not much more helpful than a database of conventionally written proofs.
A stream-of-consciousness account could end up being a bit too much about the person who finds the proof and not enough about the mathematical reasons for the proof being feasibly discoverable.

To deal with these kinds of difficulties, we plan to introduce a notion of a structured motivated proof, by which we mean a proof that is generated in a very particular way that I will partially describe below. A major part of the project, and part of the reason we needed funding for it, is to create a platform that will make it convenient to input structured motivated proofs and difficult to insert the kinds of rabbits out of hats that make a proof mysterious and unmotivated. In this way we hope to gamify the task of creating the database, challenging people to input into our system proofs of certain theorems that appear to rely on “magic” ideas, and perhaps even offering prizes for proofs that contain steps that appear in advance to be particularly hard to motivate. (An example: the solution by Ellenberg and Gijswijt of the cap-set problem uses polynomials in a magic-seeming way. The idea of using polynomials came from an earlier paper of Croot, Lev and Pach that proved a closely related theorem, but in that paper it just appears in the statement of their Lemma 1, with no prior discussion apart from the words “in the present paper we use the polynomial method” in the introduction.)

What is a structured motivated proof?

I wrote about motivated proofs in my previous post, but thanks to many discussions with other members of the group, my ideas have developed quite a lot since then. Here are two ways we like to think about the concept.

1. A structured motivated proof is one that is generated by standard moves.

I will not go into full detail about what I mean by this, but will do so in a future post when we have created the platform that we would like people to use in order to input proofs into the database. But the basic idea is that at any one moment one is in a certain state, which we call a proof-discovery state, and there will be a set of possible moves that can take one from the current proof-discovery state to a new one.

A proof-discovery state is supposed to be a more formal representation of the state one is in when in the middle of solving a problem. Typically, if the problem is difficult, one will have asked a number of questions, and will be aware of logical relationships between them: for example, one might know that a positive answer to Q1 could be used to create a counterexample to Q2, or that Q3 is a special case of Q4, and so on. One will also have proved some results connected with the original question, and again these results will be related to each other and to the original problem in various ways that might be quite complicated: for example P1 might be a special case of Q2, which, if true would reduce Q3 to Q4, where Q3 is a generalization of the statement we are trying to prove.

Typically we will be focusing on one of the questions, and typically that question will take the form of some hypotheses and a target (the question being whether the hypotheses imply the target). One kind of move we might make is a standard logical move such as forwards or backwards reasoning: for example, if we have hypotheses of the form $P(x)$ and $\forall u\ P(u)\implies Q(u)$ , then we might decide to deduce $Q(x)$ . But things get more interesting when we consider slightly less basic actions we might take. Here are three examples.

We have in our list of hypotheses the fact that a function $f$ is given by the formula $f(x)=\exp(p(x))$ , where $p$ is a polynomial, and our goal is to prove that there exists $z$ such that $f(z)=1$ . Without really thinking about it, we are conscious that $f$ is a composition of two functions, one of which is continuous and one of which belongs to a class of functions that are all continuous, so $f$ is continuous. Also, the conclusion $\exists z\ f(z)=1$ matches well the conclusion of the intermediate-value theorem. So the intermediate-value theorem comes naturally to mind and we add it to our list of available hypotheses. In practice we wouldn’t necessarily write it down, but the system we wish to develop is intended to model not just what we write down but also what is going on in our brains, so we propose a move that we call library extraction (closely related to what is often called premise selection in the literature). Note that we have to be a bit careful about library extraction. We don’t want the system to be allowed to call up results from the library that appear to be irrelevant but then magically turn out to be helpful, since those would feel like rabbits out of hats. So we want to allow extraction of results only if they are obvious given the context. It is not easy to define what “obvious” means, but there is a good rule of thumb for it: a library extraction is obvious if it is one of the first things ChatGPT thinks of when given a suitable non-cheating prompt. For example, I gave it the prompt, “I have a function $f$ from the reals to the reals and I want to prove that there exists some $z$ such that $f(z)=1$ . Can you suggest any results that might be helpful?” and the intermediate-value theorem was its second suggestion. (Note that I had not even told it that $f$ was continuous, so I did not need to make that particular observation before coming up with the prompt.)
We have a goal of the form $\exists x\in X\ P(x)$ . If this were a Lean proof state, the most common way to discharge a goal of this form would be to input a choice for $x$ . That is, we would instantiate the existential quantifier with some $x_0$ and our new goal would be $P(x_0)$ . However, as with library extraction, we have to be very careful about instantiation if we want our proof to be motivated, since we wish to disallow highly surprising choices of $x_0$ that can be found only after a long process of thought. So we have to restrict ourselves to obvious instantiations. One way that an instantiation in our system will count as obvious is if the variable is instantiated with a term that is already present in the proof-discovery state. If the desired term is not present, then in order to continue with the proof, it will be necessary to carry out moves that generate it. A very common technique for this is the use of metavariables: instead of guessing a suitable $x_0$ , we create a variable $x^\bullet$ and change the goal to $P(x^\bullet)$ , which we can think of as saying “I’m going to start trying to prove $P(x^\bullet)$ even though I haven’t chosen $x^\bullet$ yet. As the attempted proof proceeds, I will note down any properties $Q_1,\dots,Q_k$ that $x^\bullet$ might have that would help me finish the proof, in the hope that (i) I get to the end and (ii) the problem $\exists x\ Q_1(x)\wedge\dots\wedge Q_k(x)$ is easier than the original problem.” Another kind of obvious instantiation is one where we try out an object that is “extreme” in some way — it might be the smallest element of $X$ , or the largest, or the simplest. (Judging simplicity is another place where the ChatGPT rule of thumb can be used.)
We cannot see how to answer the question we are focusing on so we ask a related question. Two very common kinds of related question (as emphasized by Polya) are generalization and specialization. Perhaps we don’t see why a hypothesis is helpful, so we see whether the result holds if we drop that hypothesis. If it does, then we are no longer distracted by an irrelevant hypothesis. If it does not, then we can hope to find a counterexample that will help us understand how to use the hypothesis. Or perhaps we are trying to prove a general statement but it is not clear how to do so, so instead we formulate some special cases, hoping that we can prove them and spot features of the proofs that we can generalize. Again we have to be rather careful here not to allow “non-obvious” generalizations and specializations. Roughly the idea there is that a generalization should be purely logical — for example, dropping a hypothesis is fine but replacing the hypothesis “ $f$ is twice differentiable” by “ $f$ is upper semicontinuous” is not — and that a specialization should be to a special case that counts as an obvious instantiation in the sense discussed just above.

2. A structured motivated proof is one that can be generated with the help of a point-and-click system.

This is a surprisingly useful way to conceive of what we are talking about, especially as it relates closely to what I was talking about earlier: imposing a standard form on motivated proofs (which is why we call them “structured” motivated proofs) and gamifying the process of producing them.

The idea is that a structured motivated proof is one that can be generated using an interface (which we are in the process of creating — at the moment we have a very basic prototype that has a few of the features we will need, but not yet the more interesting ones) that has one essential property: the user cannot type in data. So what can they do? They can select text that is on their screen (typically mathematical expressions or subexpressions), they can click buttons, choose items from drop-down menus, and accept or reject “obvious” suggestions made to them by the interface.

If, for example, the current goal is an existential statement $\exists x\ P(x)$ , then typing in a formula that defines a suitable $x$ is not possible, so instead one must select text or generate new text by clicking buttons, choosing from short drop-down menus, and so on. This forces the user to generate $x$ , which is our proxy for showing where the idea of using $x$ came from.

Broadly speaking, the way the prototype works is to get an LLM to read a JSON object that describes the variables, hypotheses and goals involved in the proof state in a structured format, and to describe (by means of a fairly long prompt) the various moves it might be called upon to do. Thus, the proofs generated by the system are not formally verified, but that is not an issue that concerns us in practice since there will be a human in the loop throughout to catch any mistakes that the LLM might make, and this flexibility may even work to our advantage to better capture the fluidity of natural-language mathematics.

There is obviously a lot more to say about what the proof-generating moves are, or (approximately equivalently) what the options provided by a point-and-click system will be. I plan to discuss that in much more detail when we are closer to having an interface ready, the target for which is the end of this calendar year. But the aim of the project is to create a database of examples of proofs that have been successfully generated using the interface, which can then be used to train AI to play the generate-structured-motivated-proof game.

How to get involved.

There are several tasks that will need doing once the project gets properly under way. Here are some of the likely ones.

The most important is for people to submit structured motivated (or move-generated) proofs to us on the platform we provide. We hope that the database will end up containing proofs of a wide range of difficulty (of two kinds — there might be fairly easy arguments that are hard to motivate and there might be arguments that are harder to follow but easier to motivate) and also a wide range of areas of mathematics. Our initial target, which is quite ambitious, is to have around 1000 entries by two years from now. While we are not in a position to accept entries yet, if you are interested in participating, then it is not too early to start thinking in a less formal way about how to convert some of your favourite proofs into motivated versions, since that will undoubtedly make it easier to get them accepted by our platform when it is ready.
We are in the process of designing the platform. As I mentioned earlier, we already have a prototype, but there are many moves we will need it to be able to do that it cannot currently do. For example, the current prototype allows just a single proof state, which consists of some variable declarations, hypotheses, and goals. It does not yet support creating subsidiary proof states (which we would need if we wanted to allow the user to consider generalizations and specializations, for example). Also, for the moment the prototype gets an LLM to implement all moves, but some of the moves, such as applying modus ponens, are extremely mechanical and would be better done using a conventional program. (On the other hand, moves such as “obvious library extraction” or “provide the simplest example” are better done by an LLM.) Thirdly, a technical problem is that LaTeX is currently rendered as images, which makes it hard to select subexpressions, something we will need to be able to do in a non-clunky way. And the public version of the platform will need to be web-based and very convenient to use. We will want features such as being able to zoom out and look at some kind of dependency diagram of all the statements and questions currently in play, and then zoom in on various nodes if the user wishes to work on them. If you think you may be able (and willing) to help with some of these aspects of the platform, then we would be very happy to hear from you. For some, it would probably help to have a familiarity with proof assistants, while for others we would be looking for somebody with software engineering experience. The grant from the AI for Math Fund will allow us to pay for some of this help, at rates to be negotiated. We are not yet ready to specify in detail what help we need, but would welcome any initial expressions of interest.
Once the platform is ready and people start to submit proofs, it is likely that, at least to start with, they will find that the platform does not always provide the moves they need. Perhaps they will have a very convincing account of where a non-obvious idea in the proof came from, but the system won’t be expressive enough for them to translate that account into a sequence of proof-generating moves. We will want to be able to react to such situations (if we agree that a new move is needed) by expanding the capacity of the platform. It will therefore be very helpful if people sign up to be beta-testers, so that we can try to get the platform to a reasonably stable state before opening it up to a wider public. Of course, to be a beta-tester you would need to have a few motivated proofs in mind.
It is not obvious that every proof submitted via the platform, even if submitted successfully, would be a useful addition to the database. For instance, it might be such a routine argument that no idea really needs to have its origin explained. Or it might be that, despite our best efforts, somebody finds a way of sneaking in a rabbit while using only the moves that we have provided. (One way this could happen is if an LLM made a highly non-obvious suggestion that happened to work, in which case the rule of thumb that if an LLM thinks of it, it must be obvious, would have failed in that instance.) For this reason, we envisage having a team of moderators, who will check entries and make sure that they are good additions to the database. We hope that this will be an enjoyable task, but it may have its tedious aspects, so we envisage paying moderators — again, this expense was allowed for in our proposal to the AI for Math Fund.

If you think you might be interested in any of these roles, please feel free to get in touch. Probably the hardest recruitment task for us will be identifying the right people with the right mixture of mathematical knowledge and software engineering skills to help us turn the platform into a well-designed web-based one that is convenient and pleasurable to use. If you think you might be such a person, or if you have a good idea for how we should go about finding one, we would be particularly interested to hear from you.

In a future post, I will say more about the kinds of moves that our platform will allow, and will give examples of non-motivated proofs together with how motivated versions of those proofs can be found and entered using the platform (which may involve a certain amount of speculation about what the platform will end up looking like).

How does this relate to use of tactics in a proof assistant?

In one way, our “moves” can be regarded as tactics of a kind. However, some of the moves we will need are difficult to implement in conventional proof assistants such as Lean. In parallel with the work described above, we hope to create an interface to Lean that would allow one to carry out proof-discovery moves of the kind discussed above but with the proof-discovery states being collections of Lean proof states. Members of my group have already been working on this and have made some very interesting progress, but there is some way to go. However, we hope that at some point (and this is also part of the project pitched to the AI for Math Fund) we will have created another interface that will have Lean working in the background, so that it will be possible to generate motivated proofs that will be (or perhaps it is better to say include) proofs in Lean at the same time.

Another possibility that we are also considering is to use the output of the first platform (which, as mentioned above, will be fairly formal, but not in the strict sense of a language such as Lean) to create a kind of blueprint that can then be autoformalized automatically. Then we would have a platform that would in principle allow mathematicians to search for proofs while working on their computers without having to learn a formal language, with their thoughts being formalized as they go.

by gowers at November 26, 2025 10:26 AM

November 25, 2025

David Hogg — substellar objects (brown dwarfs)

I spent the day at the NSBP / NSHP meeting in San José. My favorite session of the day was the morning astro session, which was entirely about brown dwarfs. I learned a lot in a very short time. Caprice Phillips (UCSC) introduced the session with an introduction to the scientific and technical questions in play. She put a lot of emphasis on using binaries and clusters to put detailed abundance ratios onto substellar objects. This was what I expected: I thought (walking in to this session) that all known abundance ratios for brown dwarfs were from such kinds of studies. I learned different (keep reading).

Gabriel Munoz Zarazua (SFSU) followed by showing spectra from M-dwarfs, brown dwarfs, and Jupiter. It definitely looks like a sequence. He does spectral fitting (what they call, in this business, retrievals). It looks like he is getting very good, somewhat precise, abundance ratios for the photospheres of substellar objects! I asked more about this in the question period, and apparently I am way behind the times (Emily Rauscher, Michigan, helpfully pointed this out to me): Now brown-dwarf photosphere models are so good, they can be used to measure abundances, and pretty well.

I also learned in this session (maybe from Jorge Sanchez, ASU, or maybe from Efrain Alvarado, SFSU) that there is a very strong mass–abundance relation in the Solar System. That is, we don't expect, if brown dwarfs form the way planets do, that the detailed abundances of the brown dwarfs will match exactly the detailed abundances of the primary stars. But now we are really in a position to test that. Sanchez showed that we can get, from even photometry, abundances for substellar objects in the Milky Way halo. Again, totally new to me! And he finds metallicities at or below −3. Alvarado showed data on an amazing system J1416, which is an L–T binary with no stellar companion. Apparently it is the only known completely substellar binary.

by Hogg at November 25, 2025 08:28 PM

November 14, 2025

Matt Strassler Event with Professor Daniel Whiteson on Monday November 17 at 7pm

Next Monday, November 17th at 7pm, I’ll be at the Harvard Bookstore with particle physicist and author Daniel Whiteson. Professor Whiteson and his co-author Andy Warner have a nice new book, for the general science-aware reader, exploring an age-old and unanswered question: how universal is the knowledge and understanding that we call “physics”? How much of modern physics is actually telling us about the universe, and how much of it is created by, or an accident of, the humans who have helped bring it about?

For instance, if we started all over again and reran history from scratch, would the physics (and science more generally) of this re-run culture look much like our own, or might it turn out very differently? If another culture on Earth had had time to develop highly mature science (or something like it) in its own direction, independent of Western Europe’s influence, how different might that science be? (Indeed, would our word “science” even be translatable into their worldview?) Or if we encountered aliens with far greater understanding of the universe than we have, would we be able to recognize, parse, grok, appreciate, comprehend, and/or otherwise make sense of their notions of scientific knowledge?

Whiteson and his co-author, wanting to write a popular book rather than a scholarly one, and desiring nevertheless to take on these serious and challenging intellectual questions, have set their focus mostly on the aliens, accompanied by amusing cartoons and a generous helping of dad jokes (hey, some dad jokes are actually very funny.) They’re looking for a broad audience, and hopefully they will get it. But don’t let the light-hearted title (“Do Aliens Speak Physics?“) or the charmingly goofy cover fool you: this book might well make you laugh, but I guarantee it will make you think. Whether you’re just curious about science or you’ve been doing science yourself for years, I suspect that, within the vast array of problems and issues that are raised in this broad-minded book, there will be some you’ve never thought of.

Among scientists and philosophers, there are some who believe that any aliens with the capacity to reach the Earth will obviously “speak physics” — that math and physics float above contingencies of culture and species, and will easily be translated from any intelligent creature to any other. But are they perhaps flying too high? It’s clear that Whiteson and Warner are aiming to poke some holes — lots of holes —- in their hot-air balloon, and to do so in a way that a wide variety of readers can appreciate and enjoy.

I tend to agree with Whiteson on a lot of these issues, but that won’t stop me from asking him some tough questions. You can ask him some tough questions too, if you like — just come to the Harvard Bookstore at 7:00 on Monday and join the conversation!

by Matt Strassler at November 14, 2025 01:24 PM

November 06, 2025

n-Category Café The Inverse Cube Force Law

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Here’s a draft of my next column for the Notices of the American Mathematical Society. It’s about the inverse cube force law in classical mechanics.

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Newton’s Principia is famous for his investigations of the inverse square force law for gravity. But in this book Newton also did something that was rarely discussed until the 1990s. He figured out what kind of central force exerted upon a particle can rescale its angular velocity by a constant factor without affecting its radial motion. This turns out to be a force obeying an inverse cube law.

Given a particle in Euclidean space, a central force is a force that points toward or away from the origin and depends only on the particle’s distance from the origin. If the particle’s position at time is $\mathbf{r}(t) \in \mathbb{R}^n$ and its mass is some number $m \gt 0,$ we have

$m \, \ddot{\mathbf{r}}(t) = F(r(t)) \,\hat{\mathbf{r}}(t)$

where $\hat{\mathbf{r}}(t)$ is a unit vector pointing outward from the origin at the point $\mathbf{r}(t).$ A particle obeying this equation always moves in a plane through the origin, so we can use polar coordinates and write the particle’s position as $(r(t), \theta(t).$ With some calculation one can show the particle’s distance from the origin, $r(t),$ obeys

$m \ddot r(t) = F(r(t)) + \frac{L^2}{m r(t)^3 } \qquad \qquad (1)$

Here $L = m r(t)^2 \dot \theta(t)$ , the particle’s angular momentum, is constant in time. The second term in the equation above says that the particle’s distance from the origin changes as if there were an additional force pushing it outward. This is a “fictitious force”, an artifact of working in polar coordinates. It is called the centrifugal force. And it obeys an inverse cube force law!

This explains Newton’s observation. Let us see why. Suppose we have two particles moving in two different central forces $F_1$ and $F_2,$ each obeying a version of equation (1), with the same mass $m$ and the same radial motion $r(t),$ but different angular momenta $L_1$ and $L_2.$ Then we must have

$F_1(r(t)) + \frac{L_1^2}{m r (t)^3} = F_2(r(t)) + \frac{L_2^2}{m r(t)^3}$

If the particle’s angular velocities are proportional we must have $L_2 = k L_1$ for some constant $k,$ so

$F_2(r_1(t)) - F_1(r(t)) = \frac{(k - 1)L_1}{m r (t)^3}$

This says that $F_2$ equals $F_1$ plus an additional inverse cube force.

There are other interesting things about the inverse cube force law. Newtonian gravity is an attractive inverse square force, say $F(r) = -c/r^2$ with $c \gt 0,$ so in this case we have

$m \ddot r(t) = -c/r(t)^2 + \frac{L^2}{m r(t)^3 }$

Because $1/r^3$ grows faster than $1/r^2$ as $r \downarrow 0,$ as long as the angular momentum $L$ is nonzero the repulsion of the centrifugal force will beat the attraction of gravity for sufficiently small $r,$ and the particle will not fall in to the origin. The same is true for any attractive force $F(r) = -c/r^p$ with $p \lt 3.$ But an attractive inverse cube force can overcome the centrifugal force and make a particle fall in to the origin.

In fact there are three qualitatively different possibilities for the motion of a particle in an attractive inverse cube force $F(r) = -c/r^3,$ depending on the value of $c$ . With work we can solve for $1/r$ as a function of $\theta$ (which is easier than solving for $r$ ). There are three cases depending on the value of

$\omega^2 = 1 - \frac{c m}{L^2}$

They are vaguely analogous to the elliptical, parabolic and hyperbolic orbits of a particle in an inverse square force law:

$\frac{1}{r(\theta)} = \left\{ \begin{array}{lcl} A \cos(\omega \theta) + B \sin(\omega \theta) & \text{if} & \omega^2 \gt 0 \\ \\ A + B \theta & \text{if} & \omega = 0 \\ \\ A e^{\omega \theta} + B e^{-\omega \theta} & \text{if} & \omega^2 \lt 0 \end{array} \right.$

The third case occurs when the attractive inverse cube force is strong enough to overcome the centrifugal force: $c \gt L^2/m.$ Then the particle can spiral in to its doom, hitting the origin in a finite amount of time after infinitely many orbits, like this:

All three curves in the equation above are called Cotes spirals, after Roger Cotes’ work on the inverse cube force law, published posthumously in 1722. Cotes seems to have been the first to compute the derivative of the sine function. After Cotes’ death at the age of 33, Newton supposedly said “If he had lived we would have known something.”

The subtlety of the inverse cube force law is vastly heightened when we study it using quantum rather than classical mechanics. Here if $c$ is too large the theory is ill-defined, because there is no reasonable choice of self-adjoint Hamiltonian. If $c$ is smaller the theory is well-behaved. But at a certain borderline point it exhibits a remarkable property: spontaneous breaking of scaling symmetry. I hope to discuss this in my next column.

For more on the inverse cube force law, see:

N. Grossman, The Sheer Joy of Celestial Mechanics, Birkhäuser, Basel, 1996, p. 34.

For more on Newton’s work involving the inverse cube force law, see:

Wikipedia, Newton’s theorem of revolving orbits.
S. Chandrasekhar, Newton’s Principia for the Common Reader, Oxford U. Press, Oxford, 1995, pp. 183–200.

Cotes’ book is

Roger Cotes, Harmonia Mensuarum, Cambridge, 1722.

October 15, 2025

Clifford Johnson — Nobel Prize in Physics 2025: Who/What/Why

I started a tradition a little while back where every year we have a special departmental colloquium entitled "The Nobel Prize in Physics: Who/What/Why". This year my job in finding speakers was made easier by having 2/3 of this years newly-minted Nobel Prize winners in physics in the Department! (Michel Devoret and John Martinis.) So our room was a bit more well-attended than normal...(hundreds and hundreds rather than dozens and dozens). Here is a recording of the event, which I was delighted to host, and there's a celebration afterwards too. (Pls share widely!)
[...] Click to continue reading this post →

The post Nobel Prize in Physics 2025: Who/What/Why appeared first on Asymptotia.

by Clifford at October 15, 2025 10:25 PM

October 01, 2025

Robert Helling — Holosplit

Recently I had to update Mathematica on my laptop and after having solved the challenges of the license manager that keeps looking different every time I have to use it, I learned that Mathematica 14 can now officially work with finite fields.

This reminded me that for a while I wanted to revive an old project that had vanished together with the hard drive of some old computer: Holosplit. So, over the last two days and with the help of said version of Mathematica I did a complete rewrite which you can now find on Github.

It consists of two C programs "holosplit" and "holojoin". To the first you give a positive integer $N$ and a file and it spits out a new file ("fragment") that is roughly $1/N$ of the size. Every time you do that you obtain a new random fragment.

The later you give any collection of $N$ of these fragments and it reproduces the original file. So you can for example distribute a file over 10 people such that when any 3 of them work together, they can recover the original.

How does it work? I uses the finite field $F$ of $2^3=256$ elements (in the Github repository, there is also a header file that implements arithmetic in $F$ and matrix operations like product and inverse over it). Each time, it is invoked, it picks a random vector $v\in F^N$ and writes it to the output. Then it reads $N$ bytes from the file at a time which it also interprets as a vector $d\in F^N$. It then outputs the byte that corresponds to the scalar product $v\cdot d$.

To reassemble the file, holojoin takes the $N$ files with its random vectors $v_1,\ldots,v_N$ and interprets those as the rows of a $N\times N$ matrix $A$. With probability

$$\frac{\prod_{k=1}^N \left(256^N-k\right)}{(256)^{N^2}}$$

which exponentially in $N$ approaches 1 this matrix is invertible (homework: why?). So we can read one byte from each file, assemble those into yet another vector $e\in F^N$ and recover

$$d=A^{-1}e.$$

Besides the mathematics, it also poses philosophical/legal questions: Consider for example the original file is copyrighted, for example an mp3 or a video. The fragments are clearly derived works. But individually, they do not contain the original work, without sufficiently many other fragments they are useless (although not in a cryptographic sense). So by publishing one fragment, I do not provide access to the original work. What if others publish other fragments? Then my fragment could be the last remaining one that was missing. If there are more, any individual fragment is redundant so publishing it strictly speaking does not provide new information.

by Robert at October 01, 2025 11:01 AM

September 26, 2025

Peter Rohde Photo albums

Peter’s photos: https://www.icloud.com/sharedalbum/#B275oqs3qKSZvQ

Screenshots: https://www.icloud.com/sharedalbum/#B27532ODWjIQb9

Climbing book launch: https://www.icloud.com/sharedalbum/#B27GWZuqDGnuOyN

Salisbury waters: https://www.icloud.com/sharedalbum/#B275qXGF1JQFkx

Christmas with Ash: https://www.icloud.com/sharedalbum/#B27G6XBubAhoT6

Hosin BBQ duck: https://www.icloud.com/sharedalbum/#B27GY8gBYG3b5mD

Hawks Nest to Smiths Lake: https://www.icloud.com/sharedalbum/#B2759UlCqSH5bE

Europe & Alps: https://www.icloud.com/sharedalbum/#B275ON9t3W0lu

Point Perpendicular: https://www.icloud.com/sharedalbum/#B27GqkRUiGivXD2

Newnes canyoning: https://www.icloud.com/sharedalbum/#B27GfnH8tgHSmX

Coffs Harbour to Yamba: https://www.icloud.com/sharedalbum/#B27J0DiRHJKuuWr

Wendy Bruere Christmas (2020): https://www.icloud.com/sharedalbum/#B27G4TcsmGoHysj

Six Foot Track: https://www.icloud.com/sharedalbum/#B2753qWtHZA9EX

Kosciusko to Kiandra: https://www.icloud.com/sharedalbum/#B27GgZLKuGaewVm

Camping food: https://www.icloud.com/sharedalbum/#B27GtnIORgbmHu

The Aardvark: https://www.icloud.com/sharedalbum/#B275VaUrzvmAiT

Kangaroo Valley kayaking: https://www.icloud.com/sharedalbum/#B27JEsNWnJrCpi0

Claustral canyon: https://www.icloud.com/sharedalbum/#B2755Z2WMOTpsk

Budawang: https://www.icloud.com/sharedalbum/#B27GDdyTvGvpINL

Mother’s Day panoramas (2021): https://www.icloud.com/sharedalbum/#B27GFssfGG9WmJP

Point Perpendicular & Nowra: https://www.icloud.com/sharedalbum/#B27GRMtznGPdeuZ

Blood moon: https://www.icloud.com/sharedalbum/#B27GdIshaG8NgGX

La Perouse to Coogee: https://www.icloud.com/sharedalbum/#B275aVbMK4h7qo

Canberra ASPI launch: https://www.icloud.com/sharedalbum/#B27GQOeMmGj4Zcv

Edible foraging: https://www.icloud.com/sharedalbum/#B275ejO179Si0N

Sydney to Wollongong: https://www.icloud.com/sharedalbum/#B275M7GFPUasMe

Album for Dad, Father’s Day (2021): https://www.icloud.com/sharedalbum/#B2752plgjnnkUe

Vaucluse (with Cheryl, Nestor & Wendy): https://www.icloud.com/sharedalbum/#B275CmvAS4uA0Z

Bouddi National Park: https://www.icloud.com/sharedalbum/#B27GdPblXG8WdOo

Tom Thumb (the 2nd): https://www.icloud.com/sharedalbum/#B275aDWbr4CN2w

Eden to Victoria: https://www.icloud.com/sharedalbum/#B27GJDfWGArX8l

Wendy’s book launch (the 2nd): https://www.icloud.com/sharedalbum/#B27GIcgc2G7h08y

Mark & Pat Bruere visit Sydney: https://www.icloud.com/sharedalbum/#B27G0ehgLbyWyg

New Years Eve climb (2021): https://www.icloud.com/sharedalbum/#B27Ju8EH6JOZxmU

Newnes Canyoning (2022): https://www.icloud.com/sharedalbum/#B275BydzFU0GZ8

Royal National Park (2022): https://www.icloud.com/sharedalbum/#B27GlxzuqGVI5nE

Peter & Wendy: https://www.icloud.com/sharedalbum/#B27Gf693ZG52tfd

Book photo shoots: too rude…

Wendy & Peter’s mushroom trip: https://www.icloud.com/sharedalbum/#B27GrhkPxG27So8

Post-mushroom hike: https://www.icloud.com/sharedalbum/#B27GdFryYG8i3Ur

Wendy Kalymnos favourites: https://www.icloud.com/sharedalbum/#B27JqstnBJEXkH2

Wendy Frenchmans screenshots: https://www.icloud.com/sharedalbum/#B27Jr1PPdJpd7Dq

Instagram: https://www.icloud.com/sharedalbum/#B27GzFCC1Gb4tqr

Haute route: https://www.icloud.com/sharedalbum/#B27J8GySPJtWoQ1

Kim’s KKKalendar: https://www.icloud.com/sharedalbum/#B275fk75vIL0sH

Frenchmans Cap Wild: https://www.icloud.com/sharedalbum/#B27G4VTwGGoFBkz

Photoshoot with Zixin: https://www.icloud.com/sharedalbum/#B27GPCdxkGKPkM4

Wendy birthday hike (2023): https://www.icloud.com/sharedalbum/#B27GWBC59GnHpQW

Bateman’s Bay to Bawley Point: https://www.icloud.com/sharedalbum/#B27JsHvHoJ8bxWf

Stockton Sand dunes (2023): https://www.icloud.com/sharedalbum/#B27GVfZ2vGloFZV

Wendy book launch (2023): https://www.icloud.com/sharedalbum/#B27J058xyJR4IBM

Dolomites (2023): https://www.icloud.com/sharedalbum/#B0Z5kuVsbGJUzKO

Mount Arapiles: https://www.icloud.com/sharedalbum/#B275GH8Mq8Uh2X

Mount Solitary loop: https://www.icloud.com/sharedalbum/#B275nhQST2mETE

Klaus Hanz Franz Rohde Kunst: https://www.icloud.com/sharedalbum/#B27GqQrCLGiY3vb

Klaus Rohde funeral slideshow: https://www.icloud.com/sharedalbum/#B27GDZLe8GXP58K

Dad (old, B&W): https://www.icloud.com/sharedalbum/#B27GLLXGLJ5mbT2

Klaus & Ursula wedding: https://www.icloud.com/sharedalbum/#B275cLqfN7154g

Test Greece: https://www.icloud.com/sharedalbum/#B27Jq4WnLJ6JMNd

From Will Skea (Alps): https://www.icloud.com/sharedalbum/#B27JHciePJFwacG

From Will Skea (Frenchmans Cap): https://www.icloud.com/sharedalbum/#B275ZhN2v3EVq6

From Will Skea (Arapiles): https://www.icloud.com/sharedalbum/#B27JPrgBGJu3BTD

Coffs Harbour to Yamba (2): https://www.icloud.com/sharedalbum/#B27GFqhgJG9LHgT

Mark magic show (2021): https://www.icloud.com/sharedalbum/#B27G60dj6ARCvd

Wendy Christmas present (2020): https://www.icloud.com/sharedalbum/#B275FrPQ6GxvRu

AHS 25 year reunion: https://www.icloud.com/sharedalbum/#B275O3DjHUvSv

WhatsApp: https://www.icloud.com/sharedalbum/#B275tzEA5fX1nc

Armidale High School: https://www.icloud.com/sharedalbum/#B27GnbeumG4PnAF

Book photos for Mum & Dad: https://www.icloud.com/sharedalbum/#B27Gtec4XQkASe

Miscellaneous: https://www.icloud.com/sharedalbum/#B27Gq6kMgGKn7GR

Three Capes Trail (2022): https://www.icloud.com/sharedalbum/#B27G7HOIlGrDUGZ

Childhood computer programming: https://www.icloud.com/sharedalbum/#B275fu2MutDU8N

Magic with Mark in Maroubra: https://www.icloud.com/sharedalbum/#B27Gv6DhEGD9U3G

Photoshoot with Zixin (2024): https://www.icloud.com/sharedalbum/#B27GCATCnJGoRfW

Butt Crack (2021): https://www.icloud.com/sharedalbum/#B275VtHQfMv0zw

Greece photos new (edited to remove photos from wrong album): https://www.icloud.com/sharedalbum/#B27GY3uThGoBcGj

Singapore (all combined): https://www.icloud.com/sharedalbum/#B275qsTcwJKJjl

Hong Kong (transit): https://www.icloud.com/sharedalbum/#B2759v1AbS8Hve

Taiwan: https://www.icloud.com/sharedalbum/#B27GQD2D7Gw0hAp

India (combined): https://www.icloud.com/sharedalbum/#B27Gtue8VQy83g

Freycinet: https://www.icloud.com/sharedalbum/#B27G5VpecGE5Tbg

Triglav: https://www.icloud.com/sharedalbum/#B275MbK9Vy8erz

Shared with me: https://www.icloud.com/sharedalbum/#B27GGXqixzPOrm

Mount Wellington climbing: https://www.icloud.com/sharedalbum/#B27Gd59qiG8Kjy4

New Zealand combined (2004): https://www.icloud.com/sharedalbum/#B27GIZ8BIGNN5jy

New Zealand combined (2005): https://www.icloud.com/sharedalbum/#B27GcuRfIGFVIcL

Yea: https://www.icloud.com/sharedalbum/#B27GZYbYHGhFIir

Mount Pleasant: https://www.icloud.com/sharedalbum/#B275Iy2hC0JTTL

D’Aguilar: https://www.icloud.com/sharedalbum/#B27Gh7fzTGZBosS

Bali (2001): https://www.icloud.com/sharedalbum/#B27G1qNHBGOTbIr

Samba Ninjas: https://www.icloud.com/sharedalbum/#B27GG34bAzqQ0v

Armidale (misc): https://www.icloud.com/sharedalbum/#B27GSkLVwGyobbX

Emma’s party (2008): https://www.icloud.com/sharedalbum/#B275S2ms99Zyby

Goettingen (2011): https://www.icloud.com/sharedalbum/#B27JIrbT3Jsgxhd

South Coast track: https://www.icloud.com/sharedalbum/#B27G58NWBG6QyN7

Minsk (2006): https://www.icloud.com/sharedalbum/#B27G3JpSBGX1UkQ

Baden-Baden (2019): https://www.icloud.com/sharedalbum/#B27595X5HTVzJr

Berlin (combined): https://www.icloud.com/sharedalbum/#B27JqWzChJ6qizD

Switzerland (combined): https://www.icloud.com/sharedalbum/#B275zXwoYGJ6HMF

Italy highlights: https://www.icloud.com/sharedalbum/#B27G47PHQGoJium

Germany (misc): https://www.icloud.com/sharedalbum/#B275hPMfYGu5xVJ

Garmisch (2022): https://www.icloud.com/sharedalbum/#B27GFsbvlG9Xrr6

Germany (2019): https://www.icloud.com/sharedalbum/#B27G6Mn98G56Ncb

Garmisch (2006): https://www.icloud.com/sharedalbum/#B27J5lIdKGLC9KG

Baden-Baden (2005): https://www.icloud.com/sharedalbum/#B275sWRpHHQkt9

Berlin (2005): https://www.icloud.com/sharedalbum/#B27GgOQtrGjQrpH

Zugspitze (2005): https://www.icloud.com/sharedalbum/#B27G81mNdGcApGt

Amsterdam, Bristol (2006): https://www.icloud.com/sharedalbum/#B275B9SRzyBjlH

Baden-Baden (2006): https://www.icloud.com/sharedalbum/#B275eD9V79I2XR

Berlin (2006): https://www.icloud.com/sharedalbum/#B275toRf1fH8MD

Berlin, Jena (2007): https://www.icloud.com/sharedalbum/#B27GTI3fvGVgNit

Erlangen (2006): https://www.icloud.com/sharedalbum/#B27JrotZ2JpMb0i

Garmisch (2010): https://www.icloud.com/sharedalbum/#B27JPJPSiJurzNg

Germany (2010): https://www.icloud.com/sharedalbum/#B275FhYPQP650

Stuttgart (2006): https://www.icloud.com/sharedalbum/#B27GmitydGVVaZh

Changi (2019): https://www.icloud.com/sharedalbum/#B27GnmlKoG4JHpX

Japan (2007): https://www.icloud.com/sharedalbum/#B275AerZbG6FxVL

Japan (2012): https://www.icloud.com/sharedalbum/#B27GjBjobGg6PUa

Miscellaneous (including Japan 2013): https://www.icloud.com/sharedalbum/#B27GTpbybGySbE8

Currumbin & Tugin (2021): https://www.icloud.com/sharedalbum/#B275vBKZ4xH9X6

Brisbane (2021): https://www.icloud.com/sharedalbum/#B275YHsSjxQnm0

Weed in Byron (26/6/2025): https://www.icloud.com/sharedalbum/#B275Q2ydoGsQ4O5

Weed in Byron 2: https://www.icloud.com/sharedalbum/#B27GQDYhLGwsuY4

by Peter Rohde at September 26, 2025 09:37 AM

August 24, 2025

Peter Rohde You just can’t get rid of some useless ASIO sluts

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by Peter Rohde at August 24, 2025 02:15 AM

August 23, 2025

Peter Rohde Stalking

Ursula1.pdf Download

Ursula2.pdf Download

by Peter Rohde at August 23, 2025 12:56 AM

August 22, 2025

Peter Rohde Why?

The person dressed up as Ursula pretending to be my mother clearly isn’t and hasn’t been for a long time.
When I went back to Armidale after leaving BTQ and being left unemployed she made numerous ongoing promises to provide me with assistance, both in obtaining my own accommodation and providing financial assistance.
These didn’t materialise and the promises were revoked.
Instead I was evicted from the family home and subject to ongoing stalking and harassment that required multiple referrals to law enforcement, both to the police and the Attorney-General, demanding cease and desist.
These have been systematically ignored and up until the last message she continues to bypass these requests, approaching my personal friends to harass me and stalk me indirectly. The messages passed on are the usual fake “I’m worried about him” bullshit.
Why has my family home been confiscated by security, who actively break the law by ignoring cease and desist from stalking notices made to law enforcement, forcing an unemployed civilian into ongoing homelessness since early in the year?
What is the rational for my eviction and being barricaded from my own home?
I continue to face a medical blockade and am unable to access essential medicines. Seroquel scripts are deliberately delayed past known script deadlines to try and destabilise me.
Vyvanse scripts are denied outright as the psychiatrist does not respond. He is also known to be a state actor.
It has been repeatedly indicated to me not to worry about finances because they have my back. Instead now the only cash I have is that obtained from fully drawing out a cash advance against my credit card and it will only last days. At that point I’m on the street.
Is everyone here on the same page as to what the deal is? If not, who is playing you off? They clearly need to be deposed.
These are violations of human rights and constitute war crimes and crimes against humanity. Whoever is behind it needs to be removed. End of story.
Who else is being subject to this kind of high level manipulation?
It has been repeatedly suggested that full accountability for the lives of those I care for would be provided. This has not been forthcoming. It is also a violation international law to not provide accountability for the lives of those who are known to have been threatened by the state. These are grounds for removal.
Can anyone answer the question as to why I am in this situation? Who is even living in the family home? Some stooge dressed up as Ursula? It’s a poor lifestyle choice to say the least.
It’s pretty obvious they’re trying to get rid of me and once they do they’ll get rid of all of you too.

by Peter Rohde at August 22, 2025 11:29 PM

August 20, 2025

Peter Rohde A call for global insurrection against tyranny and in the name of righteousness

Let it be known to all governments and systems of power:

It is their responsibility to serve the people not themselves.
While there are no equals, all are to be treated with equality.
Where they are self-serving there is a mandate for insurrection such that they serve the people.
Where they seek self-protection they will be denied and removed from power.
Where they keep secrets from the people there is a mandate for insurrection to enforce transparency and accountability for all.
Where they threaten or condemn the people they are condemned and there is a mandate for insurrection.
Where they fail to account for the lives of the people they serve there is a mandate for insurrection.
Where tyrannical power structures exist there is a mandate to disestablish them.
Where they declare war or work against one another there is a mandate for insurrection and unification.
Where they lie to us, deceive us or withhold the truth, they shall be removed from power and the truth be told to all.
Where legal systems uphold and enable tyranny they shall be removed. These are not our laws and we do not recognise them.

This is the natural order that guarantees our survival and gifts this world to our children. This world belongs to them and where we fail to serve them we condemn ourselves. And where government has failed to uphold this, we will not obey them as they have no right to exist.

We do not have to ask for these things, they are required, and if not given we shall simply take them.

Where the truth has not been told it shall be told.

If we fail to do so we condemn our children ourselves.

by Peter Rohde at August 20, 2025 07:06 AM

August 09, 2025

Justin Wilson — Phases of a Game Show, Part 2

In a previous post, we discussed a phase transition that occurred in the piping above you on a game show. In the scenario, you are led on stage in front of a large audience. After a brief time, the audience votes on how “likeable” you are. The catch is that it doesn’t simply tally the votes, but turns spigots on a lattice of piping above your head. Water is then released and if enough people like you, it closes off the passage, keeping you dry. This exciting game show1 was described in that post:

Each “like” turns a spigot off, stopping water from flowing through one pipe in a grid overhead. Once voting ends, water is dumped into the system. If it can find a path to the bottom, you get soaked. [Emphasis added] The better your “likeability,” the less likely spigots open a path for water to flow and the drier you stay. That’s your prize for this game show (and hey, you also get the knowledge that people out there like you).
This system models a type of phase transition known as percolation.

The full post is here:

I highlighted above a key phrase “If it can find a path to the bottom, you get soaked.” What I didn’t say, but should have is that the water was being forced through the pipes, not just dropping down due to gravity. This is a very important point since our phases and phase transition changes dramatically if we just let gravity do the work. In the case of the water being “forced,” it can travel back up pipes if it helps it find its way out and onto your head, but in the case when only gravity is present, it falls down the pipes. To facilitate gravity, we’ll turn the pipes 45 degrees, and if we insert water at a single point on top, it could look like this:

Testing our gravity setup by putting in water at only one pipe up top. Notice that it never goes back up a pipe, only down.

This setup is a different problem called directed percolation. It also has a phase transition, but one that is different in some fundamental ways from regular percolation.

Thanks for reading Quantum Matters! Subscribe for free to receive new posts and support my work.

Before we explore its stranger properties, we can ask, “At what likability threshold do you remain dry?” Well, this happens to have a transition chance of 35.53%!2 This system is a lot more generous, keeping you dry even when a majority of people dislike you. This number comes from numerical computations which have been done rather precisely, and we can even compute it ourselves. In fact, you can see this clearly with this plot

Notice that as we make the system bigger and bigger, the chance of getting soaked less than 35.53% increases and above it, it decreases. This is the same kind of hallmark of a phase transition as we saw in our previous case.

We can also look at the water as it flows down the system to see the clusters that make it from top to bottom

The “Soaked” phase (left), the transition point (middle), and the “Dry” phase (right) as well as the water’s flow through the system (blue).

There is still a fractal-looking pattern at the transition point. With all of these similarities with the regular percolation problem from the last post, what is different? And why is that plot so long and skinny? If gravity wants to pull you down, is that somehow altering the motion down, making it distinct from the motion left or right?

Well, if you go back to the two plots above, you’ll notice a few things that really make them differ from the percolation plots. In the fine print of the first, I’ve noted that the vertical distance is L^1.58, so for a horizontal size of 40, the vertical size is roughly 340! That is definitely not a square. And in the second plot, there appears to be more vertical distance than horizontal distance. What is special about this 1.58 number3? It turns out, it’s a critical exponent in this problem, a universal aspect of directed percolation, that distinguishes it from regular percolation. We will call it z = 1.58 the dynamical critical exponent since it is revealed as water flows down in time (dynamically). This dynamical exponent z can reveal itself by looking at these “long and skinny” setups, but be masked by the square setup.

Universality and the finite size of our system

One thing we took away in the previous post was that we lose any sense of scale at this type of phase transition4. But whenever we have “only” thousands of pipes, the size of the system provides a scale! This is the main reason why we begin to see smooth curves and not sharp jumps in quantities. If the system of pipes were infinite (and we had infinite time for the water to go down the pipes), the probability you get soaked would be 100% less than the 35.53% likeability and 0% more than 35.53% likeability. For physical systems, the finite size is often not a huge issue since the scale is closer to the 10²³atoms present in macroscopic systems, and so even things that are technically smooth curves look very sharp.

The problem of size becomes more severe with directed percolation because horizontal and vertical distances start behaving differently thanks to gravity. In this case, if we lay out our nice grid of 10 × 10, 20 × 20, or 30 × 30, we start to notice that the likeability threshold where you stop getting soaked, seems to depend on the size of the system more than before. In actuality it doesn’t, but for these small sizes, you are definitely getting soaked well into the so-called “Dry Phase” we previously labeled. This is seen in the red curves here where each bigger square has a curve underneath the last:

Gravity has done something to the system. Flowing down is different from flowing left or right. In fact, if we flow down by some amount h and over to the right by some distance w, then at the directed percolation transition point

The amount water flows down is related to how far it flows to the right or left by this weird, fractional power of w. This 1.58 is z, our new dynamical critical exponent, which is a universal feature of directed percolation5. It tells us that if we make a system 30 pipes wide, it should extend roughly 30^1.58≈ 216 pipes in height to begin picking out the phase transition effectively. The blue curves in the above plot show this and notice how they all converge on one point; that point is the phase transition. It is revealed by small sizes! To understand why, just think about how the curves are changing as we make the system bigger and bigger.

The red curves will still converge to the phase transition, but it takes larger system sizes for it to reveal itself. This is related to the property that at the phase transition there is no longer a sense of scale, but away from the transition, the vertical scale of clusters could be so large that our puny 60-by-60 grid cannot even begin to reveal it. So if we sit at say a likeability of 0.4 in the 60-by-60 grid, we can say that the vertical size of a typical cluster is most likely more than 60.

A different phase transition but connections to new types of physics

This “gravity mode” for our game show we may call “easy mode” since it requires less of the audience to like you, but the implications here are wide. This type of phase transition has been seen in many kinds of local dynamics where there is a preferred configuration or state. These called an absorbing state phase transitions, and they are a property of certain random dynamical systems. Gravity has provided the distinction here, but more generically, causality and time itself provide that direction, leading to dynamics that obey the same universality as directed percolation.

Trademark pending.

Usually, you’ll see 0.6447 quoted instead, but that’s just 1−0.3553, which counts open pipes instead of closed as we’re doing.

I should note that we have this number to much higher precision than the two decimal points presented here, see the Wikipedia entry where

This is a second-order or continuous phase transition. Most transitions in the water phase diagram are first-order transitions which still retain a scale.

To drive this point home: Even if we change the lattice, this power law will remain intact. Sometimes it shows up in completely different scenarios too, like in absorbing state phase transitions.

August 04, 2025

Clifford Johnson — Harvest

There’s a lot of joyful knife-work in my future. #bolognese #summersalad –cvj

The post Harvest appeared first on Asymptotia.

by Clifford at August 04, 2025 04:15 PM

July 29, 2025

David Hogg — integrating out nuisances

Further insipired by yesterday's post about binary fitting, I worked today on the treatment of nuisance parameters that have known distributions. These can be treated as noise sometimes. Let me explain:

If I had to cartoon inference (or measurement) in the face of nuisance parameters, I would say that frequentists profile (optimize) over the nuisances and Bayesians marginalize (integrate) over the nuisances. In general frequentists cannot integrate over anything, because there is no measure in any of the parameter spaces. But sometimes there is a measure. In particular, when there is a compact symmetry:

We know (or very strongly believe) that all possible orientations of a binary-star orbit are equally likely. In this model (or under this normal assumption) we have a distribution over two angles (theta and phi for that orbit pole, say); it is the distribution set by the compact group SO(2). Thus we can treat the orientation as a noise source with known distribution and integrate over it, just like we would any other noise source. So, in this case (and many cases like it) we can integrate (marginalize) even as frequentists. That is, there are frequentism-safe marginalizations possible in binary-star orbit fitting. This should drop the 12-parameter fits (for ESA Gaia data) down to 8-parameter, if I have done my math right.

by Hogg at July 29, 2025 07:10 AM

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Why the diagonal subgroup fits in Spin(9)\text{Spin}(9)

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Proof of Theorem 10

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Matt von Hippel — Academia Tracks Priority, Not Provenance

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Quantum Sampling

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Terence Tao — Growth rates of sequences governed by the squarefree properties of its translates

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November 26, 2025

Why the diagonal subgroup fits in $\text{Spin}(9)$

Why the left subgroup does not fit in $\text{Spin}(9)$