I had a chat about journalism recently, and I had a realization about just how weird science journalism, in particular, is.

Journalists aren’t supposed to be cheerleaders. Journalism and PR have very different goals (which is why I keep those sides of my work separate). A journalist is supposed to be uncompromising, to write the truth even if it paints the source in a bad light.

Norms are built around this. Serious journalistic outlets usually don’t let sources see pieces before they’re published. The source doesn’t have the final say in how they’re portrayed: the journalist reserves the right to surprise them if justified. Investigative journalists can be superstars, digging up damning secrets about the powerful.

When a journalist starts a project, the piece might turn out positive, or negative. A politician might be the best path forward, or a disingenuous grifter. A business might be a great investment opportunity, or a total scam. A popular piece of art might be a triumph, or a disappointment.

And a scientific result?

It might be a fraud, of course. Scientific fraud does exist, and is a real problem. But it’s not common, really. Pick a random scientific paper, filter by papers you might consider reporting on in the first place, and you’re very unlikely to find a fraudulent result. Science journalists occasionally report on spectacularly audacious scientific frauds, or frauds in papers that have already made the headlines. But you don’t expect fraud in the average paper you cover.

It might be scientifically misguided: flawed statistics, a gap in a proof, a misuse of concepts. Journalists aren’t usually equipped to ferret out these issues, though. Instead, this is handled in principle by peer review, and in practice by the scientific community outside of the peer review process.

Instead, for a scientific result, the most common negative judgement isn’t that it’s a lie, or a mistake. It’s that it’s boring.

And certainly, a good science journalist can judge a paper as boring. But there is a key difference between doing that, and judging a politician as crooked or a popular work of art as mediocre. You can write an article about the lying candidate for governor, or the letdown Tarantino movie. But if a scientific result is boring, and nobody else has covered it…then it isn’t newsworthy.

In science, people don’t usually publish their failures, their negative results, their ho-hum obvious conclusions. That fills the literature with only the successes, a phenomenon called publication bias. It also means, though, that scientists try to make their results sound more successful, more important and interesting, than they actually are. Some of the folks fighting the replication crisis have coined a term for this: they call it importance hacking.

The same incentives apply to journalists, especially freelancers. Starting out, it was far from clear that I could make enough to live on. I felt like I had to make every lead count, to find a newsworthy angle on every story idea I could find, because who knew when I would find another one? Over time, I learned to balance that pull better. Now that I’m making most of my income from consulting instead, the pressure has eased almost entirely: there are things I’m tempted to importance-hack for the sake of friends, but nothing that I need to importance-hack to stay in the black.

Doing journalism on the side may be good for me personally at the moment, but it’s not really a model. Much like we need career scientists, even if their work is sometimes boring, we need career journalists, even if they’re sometimes pressured to overhype.

So if we don’t want to incentivize science journalists to be science cheerleaders, what can we do instead?

In science, one way to address publication bias is with pre-registered studies. A scientist sets out what they plan to test, and a journal agrees to publish the result, no matter what it is. You could imagine something like this for science journalism. I once proposed a recurring column where every month I would cover a random paper from arXiv.org, explaining what it meant to accomplish. I get why the idea was turned down, but I still think about it.

In journalism, the arts offer the closest parallel with a different approach. There are many negative reviews of books, movies, and music, and most of them merely accuse the art of being boring, not evil. These exist because they focus on popular works that people pay attention to anyway, so that any negative coverage has someone to convince. You could imagine applying this model to science, though it could be a bit silly. I’m envisioning a journalist who writes an article every time Witten publishes, rating some papers impressive and others disappointing, the same way a music journalist might cover every Taylor Swift album.

Neither of these models are really satisfactory. You could imagine an even more adversarial model, where journalists run around accusing random scientists of wasting the government’s money, but that seems dramatically worse.

So I’m not sure. Science is weird, and hard to accurately value: if we knew how much something mattered already, it would be engineering, not science. Journalism is weird: it’s public-facing research, where the public facing is the whole point. Their combination? Even weirder.

It's been a busy time that has cut into my blogging, but I wanted to point out some links from the past couple of weeks.

• 
  Physics Today has a cover article this past issue about what is colloquially known as static electricity, but what is more technically described as triboelectricity, the transfer of charge between materials by rubbing.  I just wrote about this six months ago, and the detailed mechanisms remain poorly understood.  Large surface charge densities (like \(10^{12}\) electronic charges per square cm) can be created this way on insulators, leading to potential differences large enough to jump a spark from your finger to the door handle.  This can also lead to static electric fields near surfaces that are not small and can reveal local variations in material properties.
  
• That leads right into this paper (which I learned about from here) about the extreme shapes of the heads of a family of insects called treehoppers.  These little crawlies have head and body shapes that often have cuspy, pointy bits that stick out - spines, horns, etc.  As we learn early on about electrostatics, elongated and pointy shapes tend to lead to large local electric fields and field gradients.  The argument of this paper is that the spiky body and cranial morphology can help these insects better sense electric field distributions, and this makes it easier for them to find their way and avoid predators. 
• This manuscript on the arXiv this week is a particularly nice, pedagogical review article (formatted for Rev Mod Phys) about quantum geometry and Berry curvature in condensed matter systems.  I haven't had the chance to read it through, but I think this will end up being very impactful and a true resource for students to learn about these topics.
• Another very pretty recent preprint is this one, which examines the electronic phase diagram of twisted bilayers of WSe2, with a relative twist angle of 4.6°.  Much attention has been paid to the idea that moiré lattices can be in a regime seemingly well described by a Hubbard-like model, with an on-site Coulomb repulsion energy \(U\) and an electronic bandwidth \(W\).  This paper shows an exceptionally clean example of this, where disorder seems to be very weak, electron temperatures are quite cold, and phase diagrams are revealed that look remarkably like the phenomena seen in the cuprate superconductors (superconducting "domes" as a function of charge density adjacent to antiferromagnetic insulating states, and with "strange metal" linear-in-\(T\) resistance in the normal state near the superconducting charge density).  Results like this make me more optimistic about overcoming some of the major challenges in using twisted van der Waals materials as simulators of hard-to-solve hamilitonians.

I just learned that the origin of this word is “that which is predicated,” which is to say, more or less, any condition that can be described or specified, whether good, bad, or neutral. Not much different in this respect from the word “situation,” that which is situated. In other words: the present English meaning of “predicament” — “a difficult problem” — must be some kind of fossilization of a now-forgotten euphemistic phrase akin to the current “We have a situation.”

Scott Aaronson’s Brief Foreword:

Harvey Lederman is a distinguished analytic philosopher who moved from Princeton to UT Austin a few years ago. Since his arrival, he’s become one of my best friends among the UT professoriate. He’s my favorite kind of philosopher, the kind who sees scientists as partners in discovering the truth, and also has a great sense of humor. He and I are both involved in UT’s new AI and Human Objectives Initiative (AHOI), which is supported by Open Philanthropy.

The other day, Harvey emailed me an eloquent meditation he wrote on what will be the meaning of life if AI doesn’t kill us all, but “merely” does everything we do better than we do it. While the question is of course now extremely familiar to me, Harvey’s erudition—bringing to bear everything from speculative fiction to the history of polar exploration—somehow brought the stakes home for me in a new way.

Harvey mentioned that he’d sent his essay to major magazines but hadn’t had success. So I said, why not a Shtetl-Optimized guest post? Harvey replied—what might be the highest praise this blog has ever received—well, that would be even better than the national magazine, as it would reach more relevant people.

And so without further ado, I present to you…

ChatGPT and the Meaning of Life, by Harvey Lederman

For the last two and a half years, since the release of ChatGPT, I’ve been suffering from fits of dread. It’s not every minute, or even every day, but maybe once a week, I’m hit by it—slackjawed, staring into the middle distance—frozen by the prospect that someday, maybe pretty soon, everyone will lose their job.

At first, I thought these slackjawed fits were just a phase, a passing thing. I’m a philosophy professor; staring into the middle distance isn’t exactly an unknown disease among my kind. But as the years have begun to pass, and the fits have not, I’ve begun to wonder if there’s something deeper to my dread. Does the coming automation of work foretell, as my fits seem to say, an irreparable loss of value in human life?

The titans of artificial intelligence tell us that there’s nothing to fear. Dario Amodei, CEO of Anthropic, the maker of Claude, suggests that: “historical hunter-gatherer societies might have imagined that life is meaningless without hunting,” and “that our well-fed technological society is devoid of purpose.” But of course, we don’t see our lives that way. Sam Altman, the CEO of OpenAI, sounds so similar, the text could have been written by ChatGPT. Even if the jobs of the future will look as “fake” to us as ours do to “a subsistence farmer”, Altman has “no doubt they will feel incredibly important and satisfying to the people doing them.”

Alongside these optimists, there are plenty of pessimists who, like me, are filled with dread. Pope Leo XIV has decried the threats AI poses to “human dignity, labor and justice”. Bill Gates has written about his fear, that “if we solved big problems like hunger and disease, and the world kept getting more peaceful: What purpose would humans have then?” And Douglas Hofstadter, the computer scientist and author of Gödel, Escher, Bach, has spoken eloquently of his terror and depression at “an oncoming tsunami that is going to catch all of humanity off guard.”

Who should we believe? The optimists with their bright visions of a world without work, or the pessimists who fear the end of a key source of meaning in human life?

I was brought up, maybe like you, to value hard work and achievement. In our house, scientists were heroes, and discoveries grand prizes of life. I was a diligent, obedient kid, and eagerly imbibed what I was taught. I came to feel that one way a person’s life could go well was to make a discovery, to figure something out.

I had the sense already then that geographical discovery was played out. I loved the heroes of the great Polar Age, but I saw them—especially Roald Amundsen and Robert Falcon Scott—as the last of their kind. In December 1911, Amundsen reached the South Pole using skis and dogsleds. Scott reached it a month later, in January 1912, after ditching the motorized sleds he’d hoped would help, and man-hauling the rest of the way. As the black dot of Amundsen’s flag came into view on the ice, Scott was devastated to reach this “awful place”, “without the reward of priority”. He would never make it back.

Scott’s motors failed him, but they spelled the end of the great Polar Age. Even Amundsen took to motors on his return: in 1924, he made a failed attempt for the North Pole in a plane, and, in 1926, he successfully flew over it, in a dirigible. Already by then, the skis and dogsleds of the decade before were outdated heroics of a bygone world.

We may be living now in a similar twilight age for human exploration in the realm of ideas. Akshay Venkatesh, whose discoveries earned him the 2018 Fields Medal, mathematics’ highest honor, has written that, the “mechanization of our cognitive processes will alter our understanding of what mathematics is”. Terry Tao, a 2006 Fields Medalist, expects that in just two years AI will be a copilot for working mathematicians. He envisions a future where thousands of theorems are proven all at once by mechanized minds.

Now, I don’t know any more than the next person where our current technology is headed, or how fast. The core of my dread isn’t based on the idea that human redundancy will come in two years rather than twenty, or, for that matter, two hundred. It’s a more abstract dread, if that’s a thing, dread about what it would mean for human values, or anyway my values, if automation “succeeds”: if all mathematics—and, indeed all work—is done by motor, not by human hands and brains.

A world like that wouldn’t be good news for my childhood dreams. Venkatesh and Tao, like Amundsen and Scott, live meaningful lives, lives of purpose. But worthwhile discoveries like theirs are a scarce resource. A territory, once seen, can’t be seen first again. If mechanized minds consume all the empty space on the intellectual map, lives dedicated to discovery won’t be lives that humans can lead.

The right kind of pessimist sees here an important argument for dread. If discovery is valuable in its own right, the loss of discovery could be an irreparable loss for humankind.

A part of me would like this to be true. But over these last strange years, I’ve come to think it’s not. What matters, I now think, isn’t being the first to figure something out, but the consequences of the discovery: the joy the discoverer gets, the understanding itself, or the real life problem their knowledge solves. Alexander Fleming discovered penicillin, and through that work saved thousands, perhaps millions of lives. But if it were to emerge, in the annals of an outlandish future, that an alien discovered penicillin thousands of years before Fleming did, we wouldn’t think that Fleming’s life was worse, just because he wasn’t first. He eliminated great suffering from human life; the alien discoverer, if they’re out there, did not. So, I’ve come to see, it’s not discoveries themselves that matter. It’s what they bring about.

But the advance of automation would mean the end of much more than human discovery. It could mean the end of all necessary work. Already in 1920, the Czech playwright Karel Capek asked what a world like that would mean for the values in human life. In the first act of R.U.R.—the play which introduced the modern use of the word “robot”—Capek has Henry Domin, the manager of Rossum’s Universal Robots (the R.U.R. of the title), offer his corporation’s utopian pitch. “In ten years”, he says, their robots will “produce so much corn, so much cloth, so much everything” that “There will be no poverty.” “Everybody will be free from worry and liberated from the degradation of labor.” The company’s engineer, Alquist, isn’t convinced. Alquist (who, incidentally, ten years later, will be the only human living, when the robots have killed the rest) retorts that “There was something good in service and something great in humility”, “some kind of virtue in toil and weariness”.

Service—work that meets others’ significant needs and wants— is, unlike discovery, clearly good in and of itself. However we work— as nurses, doctors, teachers, therapists, ministers, lawyers, bankers, or, really, anything at all—working to meet others’ needs makes our own lives go well. But, as Capek saw, all such work could disappear. In a “post-instrumental” world, where people are comparatively useless and the bots meet all our important needs, there would be no needed work for us to do, no suffering to eliminate, no diseases to cure. Could the end of such work be a better reason for dread?

The hardline pessimists say that it is. They say that the end all needed work would not only be a loss of some value to humanity, as everyone should agree. For them it would be a loss to humanity on balance, an overall loss, that couldn’t be compensated in another way.

I feel a lot of pull to this pessimistic thought. But once again, I’ve come to think it’s wrong. For one thing, pessimists often overlook just how bad most work actually is. In May 2021, Luo Huazhang, a 31 year-old ex-factory worker in Sichuan wrote a viral post, entitled “Lying Flat is Justice”. Luo had searched at length for a job that, unlike his factory job, would allow him time for himself, but he couldn’t find one. So he quit, biked to Tibet and back, and commenced his lifestyle of lying flat, doing what he pleased, reading philosophy, contemplating the world. The idea struck a chord with overworked young Chinese, who, it emerged, did not find “something great” in their “humility”. The movement inspired memes, selfies flat on one’s back, and even an anthem.

That same year, as the Great Resignation in the United States took off, the subreddit r/antiwork played to similar discontent. Started in 2013, under the motto “Unemployment for all, not only the rich!”, the forum went viral in 2021, starting with a screenshot of a quitting worker’s texts to his supervisor (“No thanks. Have a good life”), and culminating in labor-actions, first supporting striking workers at Kelloggs by spamming their job application site, and then attempting to support a similar strike at McDonald’s. It wasn’t just young Chinese who hated their jobs.

In Automation and Utopia: Human Flourishing in a World without Work, the Irish lawyer and philosopher John Danaher imagines an antiwork techno-utopia, with plenty of room for lying flat. As Danaher puts it: “Work is bad for most people most of the time.”“We should do what we can to hasten the obsolescence of humans in the arena of work.”

The young Karl Marx would have seen both Domin’s and Danaher’s utopias as a catastrophe for human life. In his notebooks from 1844, Marx describes an ornate and almost epic process, where, by meeting the needs of others through production, we come to recognize the other in ourselves, and through that recognition, come at last to self-consciousness, the full actualization of our human nature. The end of needed work, for the Marx of these notes, would be the impossibility of fully realizing our nature, the end, in a way, of humanity itself.

But such pessimistic lamentations have come to seem to me no more than misplaced machismo. Sure, Marx’s and my culture, the ethos of our post-industrial professional class, might make us regret a world without work. But we shouldn’t confuse the way two philosophers were brought up with the fundamental values of human life. What stranger narcissism could there be than bemoaning the end of others’ suffering, disease, and need, just because it deprives you of the chance to be a hero?

The first summer after the release of ChatGPT—the first summer of my fits of dread—I stayed with my in-laws in Val Camonica, a valley in the Italian alps. The houses in their village, Sellero, are empty and getting emptier; the people on the streets are old and getting older. The kids that are left—my wife’s elementary school class had, even then, a full complement of four—often leave for better lives. But my in-laws are connected to this place, to the houses and streets where they grew up. They see the changes too, of course. On the mountains above, the Adamello, Italy’s largest glacier, is retreating faster every year. But while the shows on Netflix change, the same mushrooms appear in the summer, and the same chestnuts are collected in the fall.

Walking in the mountains of Val Camonica that summer, I tried to find parallels for my sense of impending loss. I thought about William Shanks, a British mathematician who calculated π to 707 digits by hand in 1873 (he made a mistake at 527; almost 200 digits were wrong). He later spent years of his life, literally years, on a table of the reciprocals of the primes up to one-hundred and ten thousand, calculating in the morning by hand, and checking it over in the afternoon. That was his life’s work. Just sixty years after his death, though, already in the 1940s, the table on which his precious mornings were spent, the few mornings he had on this earth, could be made by a machine in a day.

I feel sad thinking about Shanks, but I don’t feel grief for the loss of calculation by hand. The invention of the typewriter, and the death of handwritten notes seemed closer to the loss I imagined we might feel. Handwriting was once a part of your style, a part of who you were. With its decline some artistry, a deep and personal form of expression, may be lost. When the bots help with everything we write, couldn’t we too lose our style and voice?

But more than anything I thought of what I saw around me: the slow death of the dialects of Val Camonica and the culture they express. Chestnuts were at one time so important for nutrition here, that in the village of Paspardo, a street lined with chestnut trees is called “bread street” (“Via del Pane”). The hyper-local dialects of the valley, outgrowths sometimes of a single family’s inside jokes, have words for all the phases of the chestnut. There’s a porridge made from chestnut flour that, in Sellero goes by ‘skelt’, but is ‘pult’ in Paspardo, a cousin of ‘migole’ in Malonno, just a few villages away. Boiled, chestnuts are tetighe; dried on a grat, biline or bascocc, which, seasoned and boiled become broalade. The dialects don’t just record what people eat and ate; they recall how they lived, what they saw, and where they went. Behind Sellero, every hundred-yard stretch of the walk up to the cabins where the cows were taken to graze in summer, has its own name. Aiva Codaola. Quarsanac. Coran. Spi. Ruc.

But the young people don’t speak the dialect anymore. They go up to the cabins by car, too fast to name the places along the way. They can’t remember a time when the cows were taken up to graze. Some even buy chestnuts in the store.

Grief, you don’t need me to tell you, is a complicated beast. You can grieve for something even when you know that, on balance, it’s good that it’s gone. The death of these dialects, of the stories told on summer nights in the mountains with the cows, is a loss reasonably grieved. But you don’t hear the kids wishing more people would be forced to stay or speak this funny-sounding tongue. You don’t even hear the old folks wishing they could go back fifty years—in those days it wasn’t so easy to be sure of a meal. For many, it’s better this way, not the best it could be, but still better, even as they grieve what they stand to lose and what they’ve already lost.

The grief I feel, imagining a world without needed work, seems closest to this kind of loss. A future without work could be much better than ours, overall. But, living in that world, or watching as our old ways passed away, we might still reasonably grieve the loss of the work that once was part of who we were.

In the last chapter of Edith Wharton’s Age of Innocence, Newland Archer contemplates a world that has changed dramatically since, thirty years earlier, before these new fangled telephones and five-day trans-Atlantic ships, he renounced the love of his life. Awaiting a meeting that his free-minded son Dallas has organized with Ellen Olenska, the woman Newland once loved, he wonders whether his son, and this whole new age, can really love the way he did and does. How could their hearts beat like his, when they’re always so sure of getting what they want?

There have always been things to grieve about getting old. But modern technology has given us new ways of coming to be out of date. A generation born in 1910 did their laundry in Sellero’s public fountains. They watched their grandkids grow up with washing machines at home. As kids, my in-laws worked with their families to dry the hay by hand. They now know, abstractly, that it can all be done by machine. Alongside newfound health and ease, these changes brought, as well, a mix of bitterness and grief: grief for the loss of gossip at the fountains or picnics while bringing in the hay; and also bitterness, because the kids these days just have no idea how easy they have it now.

As I look forward to the glories that, if the world doesn’t end, my grandkids might enjoy, I too feel prospective bitterness and prospective grief. There’s grief, in advance, for what we now have that they’ll have lost: the formal manners of my grandparents they’ll never know, the cars they’ll never learn to drive, and the glaciers that will be long gone before they’re born. But I also feel bitter about what we’ve been through that they won’t have to endure: small things like folding the laundry, standing in security lines or taking out the trash, but big ones too—the diseases which will take our loved ones that they’ll know how to cure.

All this is a normal part of getting old in the modern world. But the changes we see could be much faster and grander in scale. Amodei of Anthropic speculates that a century of technological change could be compressed into the next decade, or less. Perhaps it’s just hype, but—what if it’s not? It’s one thing for a person to adjust, over a full life, to the washing machine, the dishwasher, the air-conditioner, one by one. It’s another, in five years, to experience the progress of a century. Will I see a day when childbirth is a thing of the past? What about sleep? Will our ‘descendants’ have bodies at all?

And this round of automation could also lead to unemployment unlike any our grandparents saw. Worse, those of us working now might be especially vulnerable to this loss. Our culture, or anyway mine—professional America of the early 21st century—has apotheosized work, turning it into a central part of who we are. Where others have a sense of place—their particular mountains and trees—we’ve come to locate ourselves with professional attainment, with particular degrees and jobs. For us, ‘workists’ that so many of us have become, technological displacement wouldn’t just be the loss of our jobs. It would be the loss of a central way we have of making sense of our lives.

None of this will be a problem for the new generation, for our kids. They’ll know how to live in a world that could be—if things go well—far better overall. But I don’t know if I’d be able to adapt. Intellectual argument, however strong, is weak against the habits of years. I fear they’d look at me, stuck in my old ways, with the same uncomprehending look that Dallas Archer gives his dad, when Newland announces that he won’t go see Ellen Olenska, the love of his life, after all. “Say”, as Newland tries to explain to his dumbfounded son, “that I’m old fashioned, that’s enough.”

And yet, the core of my dread is not about aging out of work before my time. I feel closest to Douglas Hofstadter, the author of Gödel, Escher, Bach. His dread, like mine, isn’t only about the loss of work today, or the possibility that we’ll be killed off by the bots. He fears that even a gentle superintelligence will be “as incomprehensible to us as we are to cockroaches.”

Today, I feel part of our grand human projects—the advancement of knowledge, the creation of art, the effort to make the world a better place. I’m not in any way a star player on the team. My own work is off in a little backwater of human thought. And I can’t understand all the details of the big moves by the real stars. But even so, I understand enough of our collective work to feel, in some small way, part of our joint effort. All that will change. If I were to be transported to the brilliant future of the bots, I wouldn’t understand them or their work enough to feel part of the grand projects of their day. Their work would have become, to me, as alien as ours is to a roach.

But I’m still persuaded that the hardline pessimists are wrong. Work is far from the most important value in our lives. A post-instrumental world could be full of much more important goods— from rich love of family and friends, to new undreamt of works of art—which would more than compensate the loss of value from the loss of our work.

Of course, even the values that do persist may be transformed in almost unrecognizable ways. In Deep Utopia: Life and Meaning in a Solved World, the futurist and philosopher Nick Bostrom imagines how things might look. In one of the most memorable sections of the book—right up there with an epistolary novella about the exploits of Pignolius the pig (no joke!)—Bostrom says that even child-rearing may be something that we, if we love our children, would come to forego. In a truly post-instrumental world, a robot intelligence could do better for your child, not only in teaching the child to read, but also in showing unbreakable patience and care. If you’ll snap at your kid, when the robot would not, it would only be selfishness for you to get in the way.

It’s a hard question whether Bostrom is right. At least some of the work of care isn’t like eliminating suffering or ending mortal disease. The needs or wants are small-scale stuff, and the value we get from helping each other might well outweigh the fact that we’d do it worse than a robot could.

But even supposing Bostrom is right about his version of things, and we wouldn’t express our love by changing diapers, we could still love each other. And together with our loved ones and friends, we’d have great wonders to enjoy. Wharton has Newland Archer wonder at five-day transatlantic ships. But what about five day journeys to Mars? These days, it’s a big deal if you see the view from Everest with your own eyes. But Olympus Mons on Mars is more than twice as tall.

And it’s not just geographical tourism that could have a far expanded range. There’d be new journeys of the spirit as well. No humans would be among the great writers or sculptors of the day, but the fabulous works of art a superintelligence could make could help to fill our lives. Really, for almost any aesthetic value you now enjoy—sentimental or austere, minute or magnificent, meaningful or jocular—the bots would do it much better than we have ever done.

Humans could still have meaningful projects, too. In 1976, about a decade before any of Altman, Amodei or even I were born, the Canadian philosopher Bernhard Suits argued that “voluntary attempts to overcome unnecessary obstacles” could give people a sense of purpose in a post-instrumental world. Suits calls these “games”, but the name is misleading; I prefer “artificial projects”. The projects include things we would call games like chess, checkers and bridge, but also things we wouldn’t think of as games at all, like Amundsen’s and Scott’s exploits to the Pole. Whatever we call them, Suits—who’s followed here explicitly by Danaher, the antiwork utopian and, implicitly, by Altman and Amodei—is surely right: even as things are now, we get a lot of value from projects we choose, whether or not they meet a need. We learn to play a piece on the piano, train to run a marathon, or even fly to Antartica to “ski the last degree” to the Pole. Why couldn’t projects like these become the backbone of purpose in our lives?

And we could have one real purpose, beyond the artificial ones, as well. There is at least one job that no machine can take away: the work of self-fashioning, the task of becoming and being ourselves. There’s an aesthetic accomplishment in creating your character, an artistry of choice and chance in making yourself who you are. This personal style includes not just wardrobe or tattoos, not just your choice of silverware or car, but your whole way of being, your brand of patience, modesty, humor, rage, hobbies and tastes. Creating this work of art could give some of us something more to live for.

Would a world like that leave any space for human intellectual achievement, the stuff of my childhood dreams? The Buddhist Pali Canon says that “All conditioned things are impermanent—when one sees this with wisdom, one turns away from suffering.” Apparently, in this text, the intellectual achievement of understanding gives us a path out of suffering. To arrive at this goal, you don’t have to be the first to plant your flag on what you’ve understood; you just have to get there.

A secular version of this idea might hold, more simply, that some knowledge or understanding is good in itself. Maybe understanding the mechanics of penicillin matters mainly because of what it enabled Fleming and others to do. But understanding truths about the nature of our existence, or even mathematics, could be different. That sort of understanding plausibly is good in its own right, even if someone or something has gotten there first.

Venkatesh the Fields Medalist seems to suggest something like this for the future of math. Perhaps we’ll change our understanding of the discipline, so that it’s not about getting the answers, but instead about human understanding, the artistry of it perhaps, or the miracle of the special kind of certainty that proof provides.

Philosophy, my subject, might seem an even more promising place for this idea. For some, philosophy is a “way of life”. The aim isn’t necessarily an answer, but constant self-examination for its own sake. If that’s the point, then in the new world of lying flat, there could be a lot of philosophy to do.

I don’t myself accept this way of seeing things. For me, philosophy aims at the truth as much as physics does. But I of course agree that there are some truths that it’s good for us to understand, whether or not we get there first. And there could be other parts of philosophy that survive for us, as well. We need to weigh the arguments for ourselves, and make up our own minds, even if the work of finding new arguments comes to belong to a machine.

I’m willing to believe, and even hope that future people will pursue knowledge and understanding in this way. But I don’t find, here, much consolation for my personal grief. I was trained to produce knowledge, not merely to acquire it. In the hours when I’m not teaching or preparing to teach, my job is to discover the truth. The values I imbibed—and I told you I was an obedient kid—held that the prize goes for priority.

Thinking of this world where all we learn is what the bots have discovered first, I feel sympathy with Lee Sedol, the champion Go player who retired after his defeat by Google’s AlphaZero in 2016. For him, losing to AI “in a sense, meant my entire world was collapsing”. “Even if I become the number one, there is an entity that cannot be defeated.” Right or wrong, I would feel the same about my work, in a world with an automated philosophical champ.

But Sedol and I are likely just out of date models, with values that a future culture will rightly revise. It’s been more than twenty years since Garry Kasparov lost to IBM’s Deep Blue, but chess has never been more popular. And this doesn’t seem some new-fangled twist of the internet age. I know of no human who quit the high-jump after the invention of mechanical flight. The Greeks sprinted in their Olympics, though they had, long before, domesticated the horse. Maybe we too will come to value the sport of understanding with our own brains.

Frankenstein, Mary Shelley’s 1818 classic of the creations-kill-creator genre, begins with an expedition to the North Pole. Robert Walton hopes to put himself in the annals of science and claim the Pole for England, when he comes upon Victor Frankenstein, floating in the Arctic Sea. It’s only once Frankenstein warms up, that we get into the story everyone knows. Victor hopes he can persuade Walton to turn around, by describing how his own quest for knowledge and glory went south.

Frankenstein doesn’t offer Walton an alternative way of life, a guide for living without grand goals. And I doubt Walton would have been any more personally consoled by the glories of a post-instrumental future than I am. I ended up a philosopher, but I was raised by parents who, maybe like yours, hoped for doctors or lawyers. They saw our purpose in answering real needs, in, as they’d say, contributing to society. Lives devoted to families and friends, fantastic art and games could fill a wondrous future, a world far better than it has ever been. But those aren’t lives that Walton or I, or our parents for that matter, would know how to be proud of. It’s just not the way we were brought up.

For the moment, of course, we’re not exactly short on things to do. The world is full of grisly suffering, sickness, starvation, violence, and need. Frankenstein is often remembered with the moral that thirst for knowledge brings ruination, that scientific curiosity killed the cat. But Victor Frankenstein makes a lot of mistakes other than making his monster. His revulsion at his creation persistently prevents him, almost inexplicably, from feeling the love or just plain empathy that any father should. On top of all we have to do to help each other, we have a lot of work to do, in engineering as much as empathy, if we hope to avoid Frankenstein’s fate.

But even with these tasks before us, my fits of dread are here to stay. I know that the post-instrumental world could be a much better place. But its coming means the death of my culture, the end of my way of life. My fear and grief about this loss won’t disappear because of some choice consolatory words. But I know how to relish the twilight too. I feel lucky to live in a time where people have something to do, and the exploits around me seem more poignant, and more beautiful, in the dusk. We may be some of the last to enjoy this brief spell, before all exploration, all discovery, is done by fully automated sleds.

Guest post by Mark Meckes

Around 2010, in papers that both appeared in print in 2012, two different mathematical notions were introduced and given the name “diversity”.

One, introduced by Tom Leinster and Christina Cobbold, is already familiar to regular readers of this blog. Say $X$ is a finite set, and for each $x,y \in X$ we have a number $Z(x,y) = Z(y,x) \in [0,1]$ that specifies how “similar” $x$ and $y$ are. (Typically we also assume $Z(x,x) = 1$.) Fix a parameter $q \in [0,\infty]$. If $p$ is a probability distribution on $X$, then the quantity $$D_q^Z(p) = \left(\sum_{x\in supp(p)} \left( \sum_{y\in supp(p)} Z(x,y) p(y)\right)^{q-1} p(x)\right)^{1/(1-q)}$$ (with the cases $q=1,\infty$ defined by taking limits) can be interpreted as the “effective number of points” in $X$, taking into account both the similarities between points as quantified by $Z$ and the weights specified by $p$. Its logarithm $\log D_q^Z(p)$ is a refinement of the $q$-Rényi entropy of $p$. The main motivating example is when $X$ is a set of species of organisms present in an ecosystem, and $D_q^Z(p)$ quantifies the “effective number of species” in $X$, accounting for both similarities between species and their relative abundances. This family of quantities turns out to subsume many of the diversity measures previously introduced in the theoretical ecology literature, and they are now often referred to as Leinster–Cobbold diversities.

The parameter $q$ determines how much $D_q^Z(p)$ counts the very “rare” points (those for which $p(x)$ is very small). An interesting question from an ecological point of view is, given $X$ and $Z$, which probability distribution $p$ maximizes the diversity $D_q^Z(p)$? It turns out that the answer is independent of $q$. Moreover, if $X$ is a metric space and $Z(x,y) = e^{-d(x,y)}$, this maximum diversity $$D(X) := \max_p D_q^Z(p)$$ is an isometric invariant closely related to the magnitude of $X$. It also extends in a natural way to compact metric spaces.

Independently, David Bryant and Paul Tupper defined a diversity on a set $X$ to be a $[0,\infty)$-valued function $\delta$ on the finite subsets of $X$ which satisfies:

• $\delta(A) = 0$ if $A$ has at most one element, and

• $\delta(A\cup B) \le \delta(A \cup C) + \delta(C \cup B)$ whenever $C \neq \emptyset$.

I will refer to a diversity in this sense as a BT diversity. If $\delta$ were defined only on sets with at most two elements, this would amount to the definition of a metric. In fact, if $d$ is a metric on $X$, then $$\delta(A) = diam (A) := \max_{a,b \in A} d(a,b)$$ defines a BT diversity on $X$, so BT diversities are actually a generalization of metrics.

Here as well, the motivation for the name “diversity” comes from an example in theoretical ecology: suppose $X$ is a set of species in a phylogenetic tree $T$. Define $\delta(A)$ to be the length of the smallest subtree of $T$ containing $A$. Then $\delta$ is a BT diversity, known in the literature as phylogenetic diversity. However, just as with the maximum diversity discussed above, most of the subsequent work on BT diversities has focused on geometric examples.

So we now have two seemingly quite different geometric notions, introduced about the same time, going by strikingly similar names for conceptually similar reasons. One can’t help wondering, do they have something to do with each other? In particular, could maximum (LC) diversity be an example of a BT diversity?

In a new paper with Gautam Ashwarya, Dongbin Li, and Mokshay Madiman, we show that, after a minor tweak, maximum diversity does give rise to a BT diversity. The minor tweak is necessary to handle the first condition in the definition of BT diversity: if $X$ is a metric space and $x \in X$, it’s easy to check that $D(\{x\}) = 1$, whereas a BT diversity must satisfy $\delta(\{x\}) = 0$. This can be dealt with in the simplest imaginable way:

Theorem 1 Let $X$ be a metric space. For each nonempty finite $A \subseteq X$ set $\delta(A) = D(A) - 1$, and define also $\delta(\emptyset) = 0$. Then $\delta$ is a BT diversity on $X$.

(In the paper itself, we adopt the term complexity when referring to the quantities $\log D_q^Z(p)$ and $\log D(X)$, and state most of the results in terms of complexity instead of maximum diversity; we further deduce from Theorem 1 that the complexity $log D(X)$ is also a BT diversity. This terminology is used partly to cut down on the potential confusion created by using “diversity” in multiple ways. It also alludes to the relationship between $\log D_q^Z(p)$ and Rényi entropy, which is widely understood as a measure of “complexity”. Further connections between LC complexity and Rényi entropy are the subject of forthcoming work that I hope to be able to tell you more about soon! But for the remainder of this blog post I’ll stick to the maximum diversity formulation.)

Interestingly, maximum diversity has some properties that are quite nice and natural, but turn out to make it intriguingly different from the heretofore most thoroughly studied BT diversities. For example, $D = 1 + \delta$ has the following subadditivity property, which is not shared by the functional $1 + diam$:

Theorem 2 Let $X$ be a metric space, and let $A_1, \ldots, A_n \subseteq X$ be compact subsets. Then $$D\left(\bigcup_{i=1}^n A_i \right) \le \sum_{i=1}^n D(A_i).$$

Maximum diversity actually satisfies a much stronger property called fractional subadditivity, which arises naturally in inequalities for entropy. Another special case of fractional subadditivity is the following.

Theorem 3 Let $X = \{x_1, \ldots, x_n\}$ be a finite metric space. Then $$\frac{D(X)}{n} \le \frac{1}{n} \sum_{i=1}^n \frac{D(X \setminus \{x_i\})}{n-1}.$$

Theorem 3 can be interpreted as saying that the “complexity per element” of $X$ is at most the average complexity per element of a randomly chosen subset of cardinality $n-1$. This captures the natural intuition that as the size of a metric space increases, its complexity per element decreases.

In the setting of $\mathbb{R}^n$, many examples of BT diversities are homogeneous, in the sense that $\delta(\lambda A) = \lambda \delta(A)$ for all $\lambda \ge 0$ and nonempty finite $A \subseteq \mathbb{R}^n$, and either sublinear, meaning homogeneous and also satisfying $$\delta(A + B) \le \delta(A) + \delta(B),$$ or else linear, where we have equality in the condition above. For example, the diameter is a sublinear diversity. (Diversities with these properties are the focus of a recent work by Bryant and Tupper.)

By contrast, maximum diversity has no simple homogeneity property; in fact its complex behavior with respect to scaling is part of what gives it such rich geometric interest. And at least in one dimension, the diversity $\delta = \log D$ satisfies the following superlinearity properties.

Theorem 4 Let $\delta$ be the diversity $\delta = \log D$ defined on compact subsets of $\mathbb{R}$. Then $$\delta(A + B) \ge \delta(A) + \delta(B)$$ and $$\delta(\lambda A + (1-\lambda)B) \ge \lambda \delta(A) + (1-\lambda) \delta(B)$$ for every $0 \le \lambda \le 1$ and nonempty compact $A,B \subseteq \mathbb{R}$.

The first inequality in Theorem 4 can be regarded as a generalization of the Cauchy–Davenport inequality in $\mathbb{R}$, and the second as a version of the Brunn–Minkowski inequality in $\mathbb{R}$. (In fact, since Lebesgue measure can be recovered from maximum diversity, it implies the Brunn–Minkowski inequality in $\mathbb{R}$.) It is an open question, for which we know some partial results, whether Theorem 4 can be extended to higher dimensions.

In conclusion, our results make (at least) the following points:

• The seemingly independent mathematical notions of diversity introduced by Leinster and Cobbold on the one hand, and Bryant and Tupper on the other hand, are actually closely connected.

• Maximum diversity, in the sense of LC diversities, leads to a geometrically interesting example of a BT diversity whose behavior is quite different from many of the previously studied examples of BT diversities.

• Maximum diversity, at least in certain contexts, satisfies a number of inequalities which extend important classical inequalities, and it would be especially interesting to push this line of inquiry further.

Please read the paper itself for more detail and other remarks (it’s short!).

There’s a lot of joyful knife-work in my future. #bolognese #summersalad –cvj

The post Harvest appeared first on Asymptotia.

Today I heard from David Benson that Jack Morava died yesterday. This comes as such a huge shock that I can’t help but hope Benson was somehow misinformed. Morava has been posting comments to the n-Café and sending emails to me even very recently.

This is all I know, now.

The story opens:

Most of the people in the damn place were hacking away at their disgusting lunch, but I was still drinking Martinis and sitting alone in this thing that I guess could be called a booth, although it wasn’t even the height of my shoulder….. Those that came in together would blab-blab about what they were going to drink, and then, when they would order their drinks, they would have the same things they always had. Those that came in by themselves would light their silly cigarettes and bore the bartender with their phony politeness, just to prove to anybody at all that they knew the bartender.

This reads pretty differently than most of the stories in the anthology I’m reading (Hellbox). I would imagine that anybody who reads mid-20c American fiction would have the same reaction I did to this scene of a man drinking alone in New York, moodily hating all the chatty phonies within earshot — oh, this is a Catcher in the Rye imitation thing. But “Wise Guy” was published in the New Yorker on May 18, 1945 — Salinger’s first story in Caulfield’s voice, “I’m Crazy,” doesn’t come out until December.

I don’t think Salinger was imitating O’Hara. My sense is that the germ of Catcher in the Rye already existed for Salinger during the war.

But even if he was — I mean, the O’Hara is fine, but you go back and look at any of Catcher-era Salinger and it’s like nothing else. Yes, superficially, it’s cranky like this O’Hara passage but every sentence sings with life, joyous despite itself.

Have you heard of “vibe physics”?

The phrase “vibe coding” came first. People have been using large language models like ChatGPT to write computer code (and not the way I did last year). They chat with the model, describing what they want to do and asking the model to code it up. You can guess the arguments around this, from people who are convinced AI is already better than a human programmer to people sure the code will be riddled with errors and vulnerabilities.

Now, there are people claiming not only to do vibe coding, but vibe physics: doing theoretical physics by chatting with an AI.

I think we can all agree that’s a lot less plausible. Some of the people who do vibe coding actually know how to code, but I haven’t seen anyone claiming to do vibe physics who actually understands physics. They’re tech entrepreneurs in the most prominent cases, random people on the internet otherwise. And while a lot of computer code is a minor tweak on something someone has already done, theoretical physics doesn’t work that way: if someone has already come up with your idea, you’re an educator, not a physicist.

Still, I think there is something to keep in mind about the idea of “vibe physics”, related to where physics comes from.

Here’s a question to start with: go back a bit before the current chat-bot boom. There were a ton of other computational and mathematical tools. Theorem-proving software could encode almost arbitrary mathematical statements in computer code and guarantee their accuracy. Statistical concepts like Bayes’ rule described how to reason from evidence to conclusions, not flawlessly but as well as anyone reliably can. We had computer simulations for a wealth of physical phenomena, and approximation schemes for many others.

With all those tools, why did we still have human physicists?

That is, go back before ChatGPT, before large language models. Why not just code up a program that starts with the evidence and checks which mathematical model fits it best?

In principle, I think you really could have done that. But you could never run that program. It would take too long.

Doing science 100% correctly and reliably is agonizingly slow, and prohibitively expensive. You cannot check every possible model, nor can you check those models against all the available data. You must simplify your problem, somehow, even if it makes your work less reliable, and sometimes incorrect.

And for most of history, humans have provided that simplification.

A physicist isn’t going to consider every possible model. They’re going to consider models that are similar to models they studied, or similar to models others propose. They aren’t going to consider all the evidence. They’ll look at some of the evidence, the evidence other physicists are talking about and puzzled by. They won’t simulate the consequences of their hypotheses in exhaustive detail. Instead, they’ll guess, based on their own experience, a calculation that captures what they expect to be relevant.

Human physicists provided the unreliable part of physics, the heuristics. The “vibe physics”, if you will.

AI is also unreliable, also heuristic. But humans still do this better than AI.

Part of the difference is specificity. These AIs are trained on all of human language, and then perhaps fine-tuned on a general class of problems. A human expert has spent their life fine-tuning on one specific type of problem, and their intuitions, their heuristics, their lazy associations and vibes, all will be especially well-suited to problems of that type.

Another part of the difference, though, is scale.

When you talk to ChatGPT, it follows its vibes into paragraphs of text. If you turn on reasoning features, you make it check its work in the background, but it still is generating words upon words inside, evaluating those words, then generating more.

I suspect, for a physicist, the “control loop” is much tighter. Many potential ideas get ruled out a few words in. Many aren’t even expressed in words at all, just concepts. A human physicist is ultimately driven by vibes, but they check and verify those vibes, based on their experience, at a much higher frequency than any current AI system can achieve.

(I know almost nothing about neuroscience. I’m just basing this on what it can feel like, to grope through a sentence and have it assemble itself as it goes into something correct, rather than having to go back and edit it.)

As companies get access to bigger datacenters, I suspect they’ll try to make this loop tighter, to get AI to do something closer to what (I suspect, it appears) humans do. And then maybe AI will be able to do vibe physics.

Even then, though, you should not do vibe physics with the AI.

If you look at the way people describe doing vibe physics, they’re not using the AI for the vibes. They’re providing the vibes, and the AI is supposed to check things.

And that, I can confidently say, is completely ass-backwards. The AI is a vibe machine, it is great at vibes. Substituting your vibes will just make it worse. On the other hand, the AI is awful at checking things. It can find published papers sometimes, which can help you check something. But it is not set up to do the math, at least not unless the math can be phrased as a simple Python script or an IMO problem. In order to do anything like that, it has to call another type of software to verify. And you could have just used that software.

Theoretical physics is still not something everyone can do. Proposing a crackpot theory based on a few papers you found on Google and a couple YouTube videos may make you feel less confident than proposing a crackpot theory based on praise from ChatGPT and a list of papers it claims have something to do with your idea, which makes it more tempting. But it’s still proposing a crackpot theory. If you want to get involved, there’s still no substitute for actually learning how physics works.

Sorry for the long blog-hiatus! I was completely occupied for weeks, teaching an intensive course on theoretical computer science to 11-year-olds (!), at a math camp in St. Louis that was also attended by my 8-year-old son. Soon I’ll accompany my 12-year-old daughter to a science camp in Connecticut, where I’ll also give lectures.

There’s a great deal to say about these experiences, but for now: it’s been utterly transformative and life-affirming to spend my days in teaching precocious, enthusiastic, non-jaded children the material I love in the real world, rather than (let’s say) in scrolling through depressing world news and social media posts and emails from hateful trolls on my phone. It’s made me feel 25 years younger (well, at least until I need to walk up a flight of stairs). It’s made me want to go back to actual research and teaching, which besides family and friends have been the main sources of joy in my life.

So on that note, and without further ado: I hereby present the latest Quantum Complexity Theory Student Project Showcase! As the name suggests, this is where I share a selection of the best research projects, from the students who took my graduate class on Quantum Complexity Theory at UT Austin this past spring.

See here for the four previous iterations of the Showcase:

• 2011 edition (MIT)
• 2012 edition (MIT)
• 2014 edition (MIT)
• 2021 edition (MIT / UT Austin)

(As you can see, the timing hasn’t been 100% consistent.)

I expect that, as in past editions, many of this year’s projects will lead to published research papers, or at the very least, preprints on the arXiv.

And now, really without further ado, the projects!

(1) Quantum Hermite Transform and Gaussian Goldreich-Levin, by Vishnu Iyer and Siddhartha Jain.

Vishnu and Sid propose a new primitive for quantum algorithms—the Hermite transform, as opposed to the Fourier transform—and give at least one successful example of its use. They’d be eager to know if anyone can think of other applications!

(2) Quantum Statistical Witness Indistinguishability, by Shafik Nassar and Ronak Ramachandran.

In modern cryptography, even if it isn’t statistical zero-knowledge (SZK), a proof protocol might have the weaker property of being statistically witness-indistinguishable (SWI): that is, Arthur can’t tell which of two possible yes-witnesses Merlin holds. Here Shafik and Ronak initiate the study of quantum SWI, and prove the basic properties of this notion, such as the equivalence of honest and dishonest verifier. Hopefully this will serve as a springboard for someone to find an actual QSWI protocol for an interesting problem.

(3) A Zero-Knowledge Protocol for Keyed Unitary Families, by David Joy and Angela Zhang.

Continuing the theme of quantum zero-knowledge, David and Angela give a protocol by which Merlin can convince Arthur that he knows a unitary relating one pure state to another, without revealing the unitary. Again continuing a theme, applications of this protocol are sought!

(4) On Query Lower Bounds for Aaronson-Kuperberg Unitary Synthesis Circuits, by Arko Banerjee.

Back in 2006, when we formulated our so-called “Unitary Synthesis Conjecture,” Greg Kuperberg and I showed that if a quantum algorithm applies an n-qubit unitary U(f) after making a single query to a Boolean function f, then as we range over f’s, there can be at most 4ⁿ possible values of U(f). Here Arko improves our bound to 2ⁿ, which is tight. He also tries extremely hard to generalize our bound to the two-query case, not quite succeeding but proving partial results that hopefully will be helpful to others.

(5) Quantum Search with Non-Interacting Bosons and Fermions, by Aravind Karthigeyan.

This one really made me think. Aravind studies the problem of search for a single marked vertex, on the complete graph with N vertices, using either M bosons or M fermions that can hop between the vertices. With M bosons, he shows that the search succeeds in Θ(√(N/M)) time with high probability, which is just the usual runtime for Grover search with M parallel searchers. With fermions, by contrast, he shows that more time is needed. Why? Because of the Pauli Exclusion Principle! The fermions all “step on each others’ toes,” competing to be the one that jumps onto the marked vertex, which limits the advantage of having M fermions searching in parallel.

(6) Limits to Pseudodeterminism in Quantum Communication Protocols, by Jiawei Li.

Jiawei revisits the famous Hidden Matching Problem, which is known to have an exponential gap between its randomized one-way communication complexity of ~√n, and its quantum one-way communication complexity of ~log(n). He makes a new observation about this problem: namely, if you want the exponential quantum communication advantage, then you must content yourself with a protocol that can generate many different possible correct answers with appreciable probabilities (i.e., that generates large min-entropy). In other words, no good quantum protocol for the problem is pseudodeterministic. This complements, for example, my and Shih-Han Hung’s work, which showed the same statement for quantum supremacy experiments based on Random Circuit Sampling, or the long line of works that showed it for experiments that violate the Bell/CHSH inequality.

Congratulations to my students for their accomplishments, and thanks to them for giving me permission to include their work in this showcase!

read more

For every insult, it is possible to conceive of an ideal type who displays all the features the insult conveys, but in whom they are somehow virtues rather than deficits, and Tom Lehrer was that for “smart-ass.”

Also, I thought I’d seen just about every speck of Tom Lehrer content there was, but nope — here he is doing a promo for the new Dodge models of 1967.

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.

On Friday, Kareem El-Badry (Caltech) gave a seminar about looking for (and finding!) stars in binary orbits around dark or much darker companions, like black holes, neutron stars, and white dwarfs. He showed results that involve ESA Gaia astrometry, where he noted that the Gaia Mission has no sensitivity to periods right at (or within an inverse mission-length frequency difference of) one-year periods (inverse year frequencies). After the talk I objected that these are not exactly degenerate; El-Badry said that the inferences blow up there.

I spent some time on the weekend thinking about this point, and I now understand it: There is a particular one-year orbit that a star can have (around a darker companion) such that the photocenter of the system makes a motion that is identical to the apparent parallax motion. Thus there is an exact degeneracy between the parallax and a certain one-year orbit.

Does that mean that we can't measure orbits at one year (or, for that matter, parallaxes)? No, it does not. After all, the parallax ellipse has a particular celestial (angular) shape and phase. But it might require some kind of reparameterization of orbits near one-year periods. I think I know how to do that. Should we find the missing binaries? (Oh and by the way, this degeneracy means that, in a strict frequentist sense, Gaia can't measure parallaxes at all without additional information.)

A common saying goes, you should never meet your heroes, because they’ll disappoint you. But you shouldn’t trust every common saying; some heroes impress you more, the better you know them. Ray Laflamme was such a hero.

I first heard of Ray in my undergraduate quantum-computation course. The instructor assigned two textbooks: the physics-centric “Schumacher and Westmoreland” and “Kaye, Laflamme, and Mosca,” suited to computer scientists. Back then—in 2011—experimentalists were toiling over single quantum logic gates, implemented on pairs and trios of qubits. Some of today’s most advanced quantum-computing platforms, such as ultracold atoms, resembled the scrawnier of the horses at a racetrack. My class studied a stepping stone to those contenders: linear quantum optics (quantum light). Laflamme, as I knew him then, had helped design the implementation. 

Imagine my awe upon meeting Ray the following year, as a master’s student at the Perimeter Institute for Theoretical Physics. He belonged to Perimeter’s faculty and served as a co-director of the nearby Institute for Quantum Computing (IQC). Ray was slim, had thinning hair of a color similar to mine, and wore rectangular glasses frames. He often wore a smile, too. I can hear his French-Canadian accent in my memory, but not without hearing him smile at the ends of most sentences.

My master’s program entailed a research project, which I wanted to center on quantum information theory, one of Ray’s specialties. He met with me and suggested a project, and I began reading relevant papers. I then decided to pursue research with another faculty member and a postdoc, eliminating my academic claim on Ray’s time. But he agreed to keep meeting with me. Heaven knows how he managed; institute directorships devour one’s schedule like ravens dining on a battlefield. Still, we talked approximately every other week.

My master’s program intimidated me, I confessed. It crammed graduate-level courses, which deserved a semester each, into weeks. My class raced through Quantum Field Theory I and Quantum Field Theory II—a year’s worth of material—in part of an autumn. General relativity, condensed matter, and statistical physics swept over us during the same season. I preferred to learn thoroughly, deeply, and using strategies I’d honed over two decades. But I didn’t have time, despite arriving at Perimeter’s library at 8:40 every morning and leaving around 9:30 PM.

In response, Ray confessed that his master’s program had intimidated him. Upon completing his undergraduate degree, Ray viewed himself as a nobody from nowhere. He chafed in the legendary, if idiosyncratically named, program he attended afterward: Part III of the Mathematical Tripos at the University of Cambridge. A Cambridge undergraduate can earn a master’s degree in three steps (tripos) at the Department of Applied Mathematics and Theoretical Physics. Other students, upon completing bachelor’s degrees elsewhere, undertake the third step to earn their master’s. Ray tackled this step, Part III.

He worked his rear off, delving more deeply into course material than lecturers did. Ray would labor over every premise in a theorem’s proof, including when nobody could explain the trickiest step to him.¹ A friend and classmate helped him survive. The two studied together, as I studied with a few fellow Perimeter students; and Ray took walks with his friend on Sundays, as I planned lunches with other students on weekends.

Yet the program’s competitiveness appalled Ray. All students’ exam scores appeared on the same piece of paper, posted where everyone could read it. The department would retain the highest scorers in its PhD program; the other students would have to continue their studies elsewhere. Hearing about Ray’s program, I appreciated more than ever the collaboration characteristic of mine.

Ray addressed that trickiest proof step better than he’d feared, come springtime: his name appeared near the top of the exam list. Once he saw the grades, a faculty member notified him that his PhD advisor was waiting upstairs. Ray didn’t recall climbing those stairs, but he found Stephen Hawking at the top.

As one should expect of a Hawking student, Ray studied quantum gravity during his PhD. But by the time I met him, Ray had helped co-found quantum computation. He’d also extended his physics expertise as far from 1980s quantum gravity as one can, by becoming an experimentalist. The nobody from nowhere had earned his wings—then invented novel wings that nobody had dreamed of. But he descended from the heights every other week, to tell stories to a nobody of a master’s student.

Seven and a half years later, I advertised openings in the research group I was establishing in Maryland. A student emailed from the IQC, whose co-directorship Ray had relinquished in 2017. The student had seen me present a talk, it had inspired him to switch fields into quantum thermodynamics, and he asked me to co-supervise his PhD. His IQC supervisor had blessed the request: Ray Laflamme.

The student was Shayan Majidy, now a postdoc at Harvard. Co-supervising him with Ray Laflamme reminded me of cooking in the same kitchen as Julia Child. I still wonder how I, green behind the ears, landed such a gig. Shayan delighted in describing the difference between his supervisors’ advising styles. An energetic young researcher,² I’d respond to emails as early as 6:00 AM. I’d press Shayan about literature he’d read, walk him through what he hadn’t grasped, and toss a paper draft back and forth with him multiple times per day. Ray, who’d mellowed during his career, mostly poured out support and warmth like hollandaise sauce. 

Once, Shayan emailed Ray and me to ask if he could take a vacation. I responded first, as laconically as my PhD advisor would have: “Have fun!” Ray replied a few days later. He elaborated on his pleasure at Shayan’s plans and on how much Shayan deserved the break.

This June, an illness took Ray earlier than expected. We physicists lost an intellectual explorer, a co-founder of the quantum-computing community, and a scientist of my favorite type: a wonderful physicist who was a wonderful human being. Days after he passed, I was holed up in a New York hotel room, wincing over a web search. I was checking whether a quantum system satisfies certain tenets of quantum error correction, and we call those tenets the Knill–Laflamme conditions. Our community will keep checking the Knill–Laflamme conditions, keep studying quantum gates implementable with linear optics, and more. Part of Ray won’t leave us anytime soon—the way he wouldn’t leave a nobody of a master’s student who needed a conversation.

¹For the record, some of the most rigorous researchers I know work in Cambridge’s Department of Applied Mathematics and Theoretical Physics today. I’ve even blogged about some. 

²As I still am, thank you very much.

“Rest, Imagining Poisoning Park Pigeons,” that is.

On the occasion of Lehrer’s passing at 97 let us remember the most gloriously comic and enthusiastic celebration of mass death ever put to jaunty music.

Well, I can now officially mention that I've been part of the filmmaking team (in a way) working hard to bring you an enjoyable and interesting Fantastic Four movie! I think it has been about two and a half years (?) since this all began. This was a nearly perfect model of how science consulting can work in film. I worked with everyone, wherever I was needed, with the director, writers, producers, director of photography, VFX teams, set design, and so on. They made me feel welcome and part of whatever creative team I was talking to, which was great. They were open to lots of ideas right from when they were starting out thinking about tone, story ideas, and so forth, right through to final (key) tweaks right at the end of the process as recently as mere weeks ago.

It began early on with with having great conversations Matt Shakman and his writing team about the fact that Reed Richards is first and foremost a curiosity-driven physicist (and so quite different from the engineer we have in Tony Stark that we see RdJ bring out so well), and how things like his dedication to his work (and his outlook on things that comes from such work) might play out in terms of family dynamic, personal relationships, etc., - Without it turning into the tedious cliches about scientists somehow not being able to navigate the world of human relationships. Obviously, I could speak to this as a physicist who works on precisely the things Reed works on, as well as a family man, and as well as someone who remembers that it's still all about telling a story. And there are so many stories to tell at that intersection... Anyway, I think these early conversations (as well as suggestions I made in many sets of notes along the way) helped inform (even if only a little bit? who knows?) what Pedro Pascal brought to the character. This aspect of the film is one of the things I'm most pleased about seeing up on screen.

Beyond that, you'll see lots of things I gave them that I'm also delighted to see made it to the film, in many scenes. This includes (but not limited to!): [...] Click to continue reading this post →

The post Fantastic Collaboration! appeared first on Asymptotia.

So imagine that you have a unique data set Y, and in that data set Y you measure a bunch of parameters θ by a bunch of different methods. Then you find, in your favorite analysis, your estimate of one particular parameter is way out of line: All of physics must be wrong! How do you figure out the significance of your result?

If you only ever have data Y, you can't answer this question very satisfactorily: You searched Y for an anomaly, and now you want to test the significance. That's why so many a posteriori anomaly results end up going away: That search probably tested way more hypotheses than you think it did, so any significances should be reduced accordingly.

The best approach is to use only part of your data (somehow) to search, and then use a found anomaly to propose a hypothesis test, and then test that test in the held-out or new data. But that often isn't possible, or it is already too late. But if you can do this, then there is usually a likelihood ratio that is decisive about the significance of the anomaly!

I discussed all these issues today with Kate Storey-Fisher (Stanford) and Abby Williams (Chicago) today, as we are trying to finish a paper on the anomalous amplitude of the kinematic dipole in quasar samples.

read more

I showed my robust spectral decomposition (dimensionality reduction) and residuals to the MPIA Binaries group today. There was much useful feedback (including that my H-gamma was actually H-delta; embarassing!). One comment was that the model isn't truly a causal separation between star and lines, so there will be some mean lines in the star model; lines aren't entirely outliers. That's true! The group suggested that I iterate to remove stars with lines from the training set.

After the meeting, I implemented some of that, but problems like this have a pathology: If you carefully remove stars with high residuals at some wavelength, then the training data will be deficient, or low, at that wavelength. And then the model will go lower, and then more stars will have excess at that wavelength and: Disaster. So when I implemented, I required a 2-sigma deviation, and I removed both high and low outliers. I don't know if this will work, but I am testing now.

The beginning of a RET poster session

Readers may be more familiar with the sibling Research Experience for Undergraduates (REU) programs, which give undergraduate students the chance to work for 10 weeks or so in a lab that is very likely not at their home institution.  REUs are a great way for students interested in research to get broad exposure to new topics, meet people and acquire new skills, and for some, figure out whether they like research (and maybe which topics are exciting to them).  The educational goal of REUs is clear:  providing direct research experience to interested undergrads, ideally while advancing a research project and for some small fraction of students resulting in an eventual publication.  

RET programs are different:  They are intended as professional development.  The teachers are exposed to new topics, hopefully a fun research environment, and they are encouraged to think carefully about how they can take the concepts they learn and translate those for the classroom.  I am very much not an expert in education research, but there is evidence (see here, for example) that teachers who participate in these programs get a great deal of satisfaction and have lower attrition from teaching professions.  (Note that it's hard to do statistics well on questions like that, since the population of teachers that seek out opportunities like this may be a special subset of the total population of teachers.)  An idea that makes sense to me:  Enhancing the motivation and job satisfaction of a teacher can have a larger cumulative impact on educating students than an individual research project for a single student.

It would be a great shame if RET and REU programs are victims of large-scale cuts at NSF.  The NSF is the only science agency with education as part of its mission (at least historically).  All the more reason to try to persuade appropriators to not follow the draconian presidential budget request for the agency.

There are several interesting papers on the arXiv today. One of them, arXiv:2507.15949, involves my former PhD supervisor. It's on the subject of Quantum Entanglement at collider experiments, and relates back to a paper of his from 1992 that I didn't know about (there's a great line in the new paper where the authors complain that their earlier paper was ignored). (Quantum) Entanglement is the phenomenon where two or more particles are in a special state so that their properties are related, but we don't know what those properties are until we measure them. In Quantum Mechanics we would say that the actual state is not decided until we measure them, and this leads to 'spooky action at a distance' because by measuring one particle we appear to set the corresponding property of the other. An alternative explanation would be that there is some hidden quantity or 'hidden variable' where both particles secretly know all along what state they are in. However, surprisingly it's possible to discriminate between these two cases, and set up quantitative tests known as 'Bell inequalities': you can make a measurement and, if the result of that measurement is less than a certain value, then a hidden variable theory cannot explain it. Experiments to test this using photons at low energies were performed in the early 80s by Alain Aspect and others that violated Bell inequalities and thus confirming the Quantum Mechanical interpretation. 

In recent years, experimentalists have become interested in performing similar tests using different particles at higher energies; it is legitimate to ask "is this true for fermions?" or "does this break down at high energy?" Apparently similar questions were asked in the early 90s at LEP where electrons and positrons were collided (instead of protons at the LHC) and the 1992 paper pointed out that they were not really testing Bell Inequalities. The new paper revisits the older argument, and applies it to the new case of e.g. proton collisions producing a top-antitop pair. They argue that the quantity of interest for the Bell Inequality is the spin density matrix:

But what can actually be measured is the differential cross-section (the rate of production of particles in a certain angular volume):

I haven't worked on this topic myself, so it will be interesting to see if there is some pushback from the authors of papers such as arXiv:2003.02280 (who proposed such top-antitop studies). 

Fermi decay constant -- at three loops!

 I also want to point out arXiv:2507.15946 by Stephen Martin, who has performed a three-loop computation of the decay rate of the muon in the Standard Model at three loops. This quantity is incredibly important; it is measured very precisely, and so we use it to extract the underlying parameters of the Standard Model -- or, any theory beyond it. But since it's a complicated process, this is a tricky computation, even at low loop order. The results in this paper will be useful for all sorts of calculations, such as extracting the Higgs boson's self-coupling -- and working out whether the universe is metastable!

My goal this year in Heidelberg is to move forward all writing projects. I didn't really want to start new projects, but of course I can't help myself, hence the previous post. But today I crushed the writing: I wrote four pages in the book that Rix (MPIA) wants me to write, and I got more than halfway done with a Templeton Foundation pre-proposal that I'm thinking about, and I partially wrote up the method of the robust dimensionality reduction that I was working on over the weekend. So it was a good day.

That said, I don't think that the iteratively reweighted least squares implementation that I am using in my dimensionality reduction has a good probabilistic interpretation. That is, it can't be described in terms of a likelihood function. This is related to the fact that frequentist methods that enforce sparsity (like L1 regularization) don't look anything like Bayesian methods that encourage sparsity (like massed priors). I don't know how to present these issues in any paper I try to write.

1. The Classical vs. Quantum World

In our everyday experience of the world, things have precise positions, speeds, and outcomes. You throw a baseball—you know where it’s going. But when we zoom in to the world of atoms and particles, things get weird — and the rules change.

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2. The Probabilistic Nature (Uncertainty and Superposition)

🗨️ Metaphor:

"Imagine flipping a coin, while it is spinning in mid-air, it spins in mid-air being both at heads and tails at the same time, with the probability of being heads or tails is still 50-50. At this point, if we want to describe the state of this system (the coin), it would be a combination of both heads and tails — until you look, and then you can say whether the coin landed on heads or tails. That’s how particles behave in the quantum world: they exist in a state made of both heads and tails, a superposition of states, until they’re measured.

🎯 Main idea:

• Quantum Particles don’t have exact positions or velocities—just probabilities.

• Measurement collapses the particle’s wavefunction to a definite value.

Let’s look more closely at the idea that Particles behave probabilistically

In classical mechanics, we think of a particle as a tiny object with a definite position and velocity at any time. But in quantum mechanics, particles like electrons that are described by a wavefunction, a mathematical function that tells you the probability of finding the particle in different places. You can think of the particle not as a dot but as a fuzzy cloud, where he denser the cloud in one spot, the more likely the particle is to be found there.

This is why we say: "Particles don't have exact positions or velocities—just probabilities."

🎵 The Wave Nature of Matter

In our everyday life, we see systems that exhibit wave properties. Things like sound waves, water waves (surface waves), waves on a cable (vibrating), or if you live in certain places, you may experience seismic waves. These are all classical physics examples that are described by wave equations, where the disturbance propagates through a medium or field, transferring energy without necessarily transferring matter.

For example, when waves meet (i.e., waves in water), they combine through a process called interference. This can take a few forms:

· Constructive Interference: When the crests (high points) and troughs (low points) of two waves line up, they reinforce each other, creating a larger wave. Think of two ripples on a pond colliding and forming a bigger splash.

· Destructive Interference: When a crest meets a trough, they cancel out to some extent—sometimes completely—resulting in a smaller or flat wave.

This blending of energy is happening constantly in light, sound, water waves, and even quantum systems.

Below in Figure 1, is an example of superpositions of waves. The top image highlights full constructive interference and the bottom image shows destructive interference. You can see that the maximum of the two waves is 1 and its minimum is -1, where 1 and -1 are called the wave's amplitude. For these two points, for complete constructive interference, the superposition of these waves yields 2 (superposition means at each position point you add the two waves together) for the maximum and -2 for the minimum. For complete destructive interference, you can see the waves when at each point you add them together (superposition), completely cancel out (equal 0). This situation is often called completely out-of-phase . Using the same two points as in our constructive interference example, you now see that wave 1 equals 1 and wave 2 equals -1. In fact, for all the points, the two waves are equal but of opposite sign (meaning one is positive, say +1, and the other is -1). The superposition of these two waves produces 0 for all points.

Below in Figure 2, the waves are slightly shifted along the position axis (x-axis). Using our same points as before, you can see that the superposition wave doesn’t quite equal 2 and -2; they are less than 2 and greater than -2 (-2 is less than -1.9, say, meaning -2 does not get more negative, it is heading upwards towards 0). This is because each wave’s maximum and minimum values occur at different points in space, and this is true for the values of the superposition wave at all points in space. Imagine you fix wave 2, and you slowly pull wave 1 to the right (wave 1 could be referred to as phase-shifted relative to wave 2). The superposition wave continues to have positive values and negative values going towards 0. Once the maximums of wave 1 line up with the minimums of wave 2, the superposition wave is 0 for all points. This is the complete destructive interference as we saw in Figure 1. Now, if you continue to pull wave 1 to the right, the superposition wave starts growing, and if you keep pulling to the right, it will reach the complete constructive interference pattern like in Figure 1.

Notice the superposition wave (like the other waves) starts to repeat the pattern. The point where the pattern repeats itself would define the superposition wave’s wavelength 𝛌. Now imagine, if you had lots of waves where some are shifted relative to our wave 1, at some points in position, we will get a maximum amplitude resulting from constructive interference but necessarily complete constructive interference, giving the highest point of a wave (crest of water wave), while for others, we may get destructive interference, leading to the minimum amplitude (trough of a wave) and other intermediate amplitude that help to make-up the entire wave. Hopefully, this simplistic model helps us to understand how waves form and how you can get a big wave from many small waves.

Another feature of waves is that they have a wavelength that describes how far they propagate in space before repeating the same pattern over and over. If you remember what the mathematical functions, sine and cosine, they are waves that repeat in space and have a wavelength. Now the important part is that the momentum, p, of these waves is inversely proportional to their wavelength, that is, p=1/𝛌. So if you have a short wavelength, you have a large momentum, and vice versa.

These waves follow classical equations — disturbances that move through a medium, transferring energy. But in quantum mechanics, the wave isn't a ripple in water or air — it’s a probability wave.

Now comes the key idea: wave-particle duality. Particles act like waves. And waves behave very differently from particles in one crucial way:

A wave that's localized in space (i.e., sharply peaked in position) must be made by combining many different wavelengths. Think of a big wave in the ocean; it is formed by lots of waves coming together to form this big wave. This combining of waves also means you have a wide range of momenta.

Correspondingly, a wave with a defined momentum (i.e., well-defined momentum) must be spread out in space.

For example, let’s look at music and a pure note on a tuning fork (single frequency = defined momentum) lasts long but is hard to pin down in time (spread out). However, a short drumbeat is localized in time (defined position) but contains a spread of frequencies (momentum uncertainty).

For example, let’s look at music and a pure note on a tuning fork (single frequency = defined momentum) lasts long but is hard to pin down in time (spread out). However, a short drumbeat is localized in time (defined position) but contains a spread of frequencies (momentum uncertainty).

This is a fundamental mathematical property of waves called the Fourier transform. A Fourier transform contains both sine and cosine, just as waves, but is a more complicated function that involves complex numbers. The point about the Fourier transform is that you can obtain sine and cosine from it.

3. The Heisenberg Uncertainty Principle: Knowing Less to Understand More

One of the most famous — and misunderstood — ideas in quantum mechanics is the Heisenberg Uncertainty Principle.

It’s often summed up like this: You can’t know both where something is and how fast it’s moving — at the same time — with perfect precision.

At first glance, that sounds like a problem with our measuring tools, as if we just need better microscopes or sensors. But that’s not it.

This principle isn’t about technological limitations — it’s a fundamental property of nature.

What does it mean?

In classical physics, if you know where a car is and how fast it’s going, you can predict exactly where it’ll be a few seconds later. But in the quantum world, if you try to pin down the position of a particle more precisely, you automatically become less certain about its momentum (its speed and direction) — and vice versa.

It’s not because the particle is misbehaving — it’s because particles aren’t like tiny billiard balls. They behave like waves, and waves don’t have sharp edges.

---

🌀 Wave Metaphor

Think of a musical note. If a sound wave is spread out in time — like a long, steady tone — it has a very precise frequency (pitch). But if it’s a short, sharp “ping,” its frequency becomes less certain. You trade time for pitch.

In the same way, if a particle’s wave is sharply localized in space (you know where it is), the range of its momentum values must broaden. If the wave is spread out (you don’t know exactly where it is), the momentum is better defined.

---

🔬 So what’s uncertain?

It’s not that the particle is jittering around randomly. Instead:

• Before measurement, a particle’s position and momentum are both described by a range of probabilities.

• The more tightly you narrow one, the more uncertain the other becomes.

The Heisenberg Uncertainty Principle can be written down as,

𝚫p𝚫x ≤ ℏ/2

• 𝚫x is the uncertainty in position

• 𝚫p is the uncertainty in momentum

• ℏ is Planck’s constant (a very small number)

Let’s try to understand this formula a little better. In quantum mechanics, particles like electrons aren’t just little dots — they also act like waves. This means we describe them with wave packets, which are like short-lived ripples or pulses spread out over space.

To make a wave packet that’s narrow in space (so we know roughly where the particle is), we have to combine many different waves (i.e., sine waves) with various wavelengths and frequencies (think back to our above example of waves).

That’s because a single sine wave, for example, stretches out infinitely — it doesn’t give you a clear position. Only by mixing waves with different wavelengths (and therefore different momenta) can we build a localized bump.

So: Precise position → requires many different wavelengths → high momentum uncertainty.

Now reverse it. If we only use one sine wave, it has a very clear wavelength (momentum), but it stretches out forever — the particle could be anywhere.

So: Precise momentum → means the particle is spread out → high position uncertainty.

This trade-off is at the heart of the uncertainty principle:

𝚫p𝚫x ≤ ℏ/2

Here, 𝚫x is the uncertainty in position, 𝚫p is the uncertainty in momentum, and ℏ is a very tiny constant from quantum physics.

The key message: > The more precisely you know where something is, the less precisely you can know how fast it's going — and vice versa.

Imagine building a short splash on a pond with water waves (see Figure-3):

• A small, sharp splash uses many different ripple sizes (frequencies).

• A pure, smooth ripple has just one frequency but spreads out.

That’s the uncertainty principle in action, hiding in the rhythm of waves.

So what that tells us is that as we become more and more certain about the location of a particle (𝚫x is getting smaller and smaller, heading to 0), 𝚫p is getting larger and larger, heading to ∞. This tells us that if we knew x exactly, then we would not know the momentum p of the particle, since the uncertainty 𝚫p is infinite.

The Core Idea:

You can’t precisely know both where something is (position) and how fast it’s going or in what direction (momentum) at the same time. The more accurately you try to measure one, the fuzzier the other becomes.

🧠 Everyday Analogy:

Imagine you're trying to photograph a speeding car at night.

• If you use a fast shutter, you can see exactly where the car is, but the picture will be blurry — you can’t tell how fast it was going.

• If you use a slow shutter, you get a motion blur — which tells you how fast it was moving, but now you don’t know exactly where it was.

That’s the uncertainty principle in action: precision in one area means fuzziness in the other.

Again, this isn’t just a limitation of our instruments — it's a fundamental property of nature. It's like the universe itself has this built-in fuzziness at tiny scales.

This principle also tells us why electrons just don't spiral into the nucleus of an atom.

Because you can’t precisely know both the position and momentum of a particle at the same time.

If an electron got too close to the nucleus, its position would be very well known (i.e., tightly confined in space). According to the uncertainty principle, this would mean its momentum becomes highly uncertain. Because the kinetic energy is directly calculated from the momentum, and since you have large momentum fluctuations, you will have large kinetic energy.

This tells us that confining the electron too tightly costs energy — a lot of energy. That energy cost balances out the attractive pull of the nucleus. The result? The electron occupies a fuzzy “cloud” of most likely locations (remember it is based on probabilities)— what we call an orbital — and it doesn't just fall in.

This quantum balancing act gives rise to stable atoms, the periodic table, chemistry, etc.

Wave-particle duality

Wave-particle duality is one of the most astonishing ideas in modern physics. It says that tiny things—like electrons and light—can behave like particles and waves, depending on how you look at them.

• Waves (like ocean waves, or ripples in a pond, or even sound waves) are spread out, continuous disturbances. They travel, they can interfere with each other (creating bigger or smaller waves), and they bend around corners. You can't point to "one wave" and say it's at a single, precise location.

• Particles (like a baseball, or a tiny pebble) are distinct, localized objects. They have a definite position, mass, and can be tracked as they move from one point to another.

The Classical Difference: In our ordinary experience, something is clearly either a wave or a particle. Never both.

🌍 In the Classical World

In everyday experience:

• Objects are either particles (like baseballs) or waves (like sound or water ripples).

• Particles have defined positions and travel along clear paths.

• Waves are spread out, overlap, and interfere, but they don't "exist" in a single spot.

Think of throwing a rock into a pond—either you're dealing with the rock or the ripples it creates, never both at once.

⚛️ In the Quantum World

The Quantum Twist: Wave-Particle Duality

But when we zoom down to the incredibly tiny, fundamental level of reality – the quantum realm – things get weird. Particles like electrons, and even light itself (which we classically considered a wave), don't always fit neatly into one category. This is wave-particle duality:

• Light, for instance, can behave like a spread-out wave (which is why it can create interference patterns, just like water waves). But it can also act like a stream of tiny, discrete particles called photons (which is how it knocks electrons off a metal surface in the photoelectric effect, acting like tiny billiard balls).

• Similarly, electrons (which we think of as particles making up atoms) can, under certain experimental conditions, exhibit wave-like behavior, creating interference patterns as if they were spread out and passing through multiple places at once. Yet, when we try to pinpoint their location, they act like a localized particle.

This means a single electron, shot toward a double slit, doesn't just go through one slit—it behaves as if it explores all possibilities at once, producing an interference pattern typical of waves.

🤔 So What Does This Mean?

The amazing part is that a quantum entity isn't just sometimes a wave and sometimes a particle. Instead, it possesses both wave-like and particle-like properties simultaneously, and the act of observation or the type of experiment we perform determines which aspects we will observe. You can't observe both characteristics at the same exact time in the same experiment.

This seemingly paradoxical idea is a cornerstone of quantum mechanics and is absolutely essential for understanding how the universe works at its most fundamental level. It underpins all modern technologies from lasers and transistors to medical imaging and the very concept of quantum computing.

The objects aren't just "here or there"—they are probabilistic ripples, until observed.

Wave-particle duality is nature’s way of whispering: “The world is more nuanced than it seems.”

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© William Shelton at July 22, 2025 12:25 AM

July 18, 2025

Justin Wilson — Scientists Discover a New Phase of Game Show!

You’ve seen the headlines: “Scientists Discover a New Phase of Matter!” They usually go something like, “You’ve heard of solids, liquids, and gases—but now there’s a fourth (fifth) phase: [insert buzzword here].”1 You might think about these phases in terms of temperature: heat up ice and it melts, a phase change! And yes, that is a phase transition. But temperature is just one knob we can turn, and phases are far richer than just “solid, liquid, and gas.” In fact, new phases are surprisingly common, and to understand why, let’s play a little game.

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What is the Percolating Phase?

Imagine you’re on a game show called Are You Likeable? (the least-likeable game show). The rules of the game are simple:

1. You stand on the stage and try to win over the audience.

2. Each audience member votes whether they like you or not.

3. But the twist: votes aren’t tallied—they control a system of pipes above your head.

That system of pipes looks something like this2

Each “like” turns a spigot off, stopping water from flowing through one pipe in a grid overhead3. Once voting ends, water is dumped into the system. If it can find a path to the bottom, you get soaked. 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 percolation4.

But where is the phase transition?

Aside from asking when my game show will be green-lit5, we can ask: When are you most likely to get wet? If the audience is huge, and fewer than 50% of them like you, it’s nearly guaranteed that the water will find a path—you’ll be soaked. But if more than 50% like you, chances are good that you’ll stay dry.

This is a phase transition6: a sudden change in the system’s behavior. For a moderately sized audience, it looks something like this:

Your probability of getting soaked forms a curve that sharpens up with increasing audience size—becoming a near step at 50%. That is known as the percolation threshold.

This is hard to visualize, though; luckily this problem admits some very nice pictures. For instance, here is the problem with a large number of pipes:

If a pipe is blue, water is in it, and all the blue clusters flow down from the top. Notice what happens around 50%: even though spigots are randomly being turned off, the flow from top to bottom is entirely stopped around this value. Something is happening within the system that is allowing water to pass through on one side of the transition and not the other.

A closer look at the transition

To dig deeper, we simulate what happens at this threshold. Each spigot is either open or closed (randomly determined). If we visualize the grid (say 1024×1024 spigots), it looks like visual static: black and white dots with no obvious pattern7:

But now let’s color each connected cluster of open spigots—where water could flow and fill up this section of pipes. Suddenly, structure emerges. Some clusters are small, others large. If one spans from top to bottom, water flows and we’re in the percolating phase. If not, we’re in the non-percolating phase. At the transition (within the static above, we get this for the twelve largest clusters:

At exactly the percolation threshold (50% for the pipes above), there’s no single dominant cluster, but also no clear typical size. Instead, there’s a wide distribution of cluster sizes. The critical state behaves differently than either phase.

Scale Invariance: A Hallmark of Criticality

Let’s zoom out. Suppose we double the grid to 2048×2048.

The largest clusters are definitely larger—the largest here is 400,000 pipes/spigots large, while for the previous 1024×1024 case the largest was 180,000 large—but the pattern still looks… the same. We doubled the size, but if we slightly blur our vision, we cannot distinguish these two plots (even though one is quadruple the area of the other). Look at 512×512—even that looks similar:

You would be hard-pressed to say which one is larger if you blurred your eyes. This problem is apparent even down to 256×256 or 128×128.

This is called scale invariance—there is no characteristic length scale at the phase transition. It’s one of the defining features of what are known as second-order phase transitions.

It also explains why, at the threshold, you have a 50% chance of getting soaked. The largest cluster might span the system, but it might just as well fall short. There’s no guarantee either way.

Fractals in the Flow

These clusters within the above pictures don’t look like regular 2D structures or even 1D lines; they are, in fact, fractals. They aren’t exactly self-similar but they do behave the same at different scales. They fill space with a fractal dimension: not quite 1D, not quite 2D. In two-dimensional percolation, the clusters have a dimension of 91/48 ≈ 1.896—a universal number shared by all systems in this class, regardless of lattice type or other microscopic details.

This is part of the beauty of percolation: It shows us visually the underlying mathematical structure and even reveals some universality of phase transitions.

Why This Matters

Percolation is just one example, but it captures the essence of what physicists mean when they talk about “phases of matter.” It isn’t always about exotic particles or extreme temperatures turning gas into plasma. Sometimes, it’s about whether a liquid can find its way through a series of pipes. It’s about symmetry, structure, and emergence.

You’ve experienced water’s phases: ice, liquid, steam. But nature offers many more—some with no neat label like “solid” or “gas.” The theory of phase transitions explains them. Percolation is a window into that wider world.

1

What’s funny to me about this is how we use ice/water/vapor to expound on this. But water’s phase diagram is complex and deserves its own post. One point of interest: water and water vapor can be smoothly connected to each other without going through any phase transition. That and there’s something like 20 phases of ice.

2

Forgive me the ChatGPT weirdness: the drip on the left pipe and the weird long pipe on the right are just LLM quirks. Kind of like how hard it is to get AI to draw a full wine glass. (Or maybe now it can?)

3

Audience members can’t influence each other here. Assume the spigots are randomized and a stern librarian keeps everyone silent.

4

Technically, this is bond percolation on a square lattice.

5

NBC, call me!

6

A second-order phase transition is one where the change is continuous, but its derivatives (like heat capacity or cluster size) diverge. Percolation is a particularly visually clean example.

7

I have switched from bond percolation to site percolation to make plotting and cluster finding easier. The universal features do not depend on this.

© Justin H Wilson at July 18, 2025 02:30 PM

July 15, 2025

Mark Goodsell — The Ant Mill

Jesper Grimstrup kindly sent me an electronic copy of his new book, The Ant Mill. He was also kind enough to give me some feedback on a first version of this review.

It has a foreword by Peter Woit, who has commented briefly about the book on his blog; the author also has a substack. The subtitle is 'How theoretical high-energy physics descended into groupthink, tribalism and mass production of research' so you would expect it to be the sort of thing that I would take a strong objection to. However, I am the sort of person who likes to read things that challenge me; the only thing that gets under my skin in this book is attacking the whole of academia in public.

The story is an interweaving of the author's personal experiences in academia with his general observations. This personal story and his experiences are interesting, much like I expect those of everyone who has spent several years in academia would be. And he has clearly spent a lot of time thinking about thinking about research. I love meta-activities of this sort; the best example that I know of is You and Your Research by Hamming, which I stumbled on as a postdoc. Indeed, the existence of these sorts of things that are shared by young researchers is actually evidence against the central thesis of Grimstrup's book.

The market attacking High-Energy Physics seems to be burgeoning. On the one hand Hossenfelder believes that we have become 'lost in math,' and on the other Woit believes we are not mathematical enough; both attack string theory as a failed program. Grimstrup's book is in the mathematical camp, with the novelty that he piles scorn on all popular approaches to quantum gravity, in particular loop quantum gravity and noncommutative geometry, since he has come into closest contact with them. His observations about string theorists are mainly about the shoddy way that he was treated during his time at the NBI, with several egregious examples of bad behaviour. We are lead to conclude that it is not just string theorists who have formed a closed tribe, but that there are several such groups crowding out innovation.

Grimstrup refers to his own research program and gives examples of how it has just generally been ignored within academia. For example, he starts the book with a copy of a grant application by a 31-year-old Niels Bohr for an entire institute, and contrasts this with a grant application of his that was refused that effectively ended his career within academia (my understanding is that at the NBI in Copenhagen it is common to ask for and obtain grants to pay your own salary and prolong temporary contracts). He writes that he does not do this to compare himself to Niels Bohr, but inadvertently this is the impression I got from the book -- that he was doing this not in a self-aggrandising way, but in the sense that you can almost feel his frustration coming through the pages that his expectations did not meet reality. It seems like bait at times, inviting anyone who disagrees with the general thesis to attack him personally. Instead, I will have a look at his papers with an open mind, after writing this review, and keep my thoughts on them to myself.

The book made me think of how many of us enter academia. We grow up reading popular science accounts idolising physicists from a century ago. And it made me think more of the self-actualisation messages that were rammed down all our throats in the popular culture in the 80s and 90s: follow your dreams, stick to your principles, be true to yourself, this is the most important thing in life and you shouldn't worry about money, just be happy. And: working hard and getting good grades is the way to get to the top. The problem is that this is largely obsolete: it's based on the world that existed post world war two when there was a scarcity of labour and an economic boom. Then -- if you were from the right background and your face fit -- you could work hard, get a PhD and walk into a permanent academic job (yes this is a caricature). Science was respected and so were scientists; high-energy physics was at the top of the tree because of the connection with technological advancements and nuclear weapons. That world doesn't exist any more; while in many ways for the better, it is undeniable that we live in a world of much greater competition and public skepticism about science is increasing.

The scientific community has expanded, as has the population; and more importantly education throughout the world and global travel and communication has meant that the number of people around the world who are involved in research is much greater than it was. Grimstrup notes that increasing the size of the academic community has led to fundamental changes of behaviour: professionalisation of research and group think, and that this leads to an increasing incentive to work on mainstream topics. He has done bibliographical research to demonstrate this (in papers and presented in the book). It is clearly true that the Matthew effect exists in many branches of society, and therefore also in academia; governments wanting to exert some form of oversight in exchange for the funds that they provide has definitely led to changes in incentives for researchers. One aspect of this is that it is hard to judge the work of people from other fields, but we are required to do so; and then it is difficult to argue with quantitative measures such as number of papers, citations, h-indices. Then of course the measure becomes the target for certain people. 

Grimstrup rails against all these changes; he clearly believed that the correct thing to do for an aspiring researcher would be to work on their own ideas, stick to their principles and not compromise. They should work for a long time, in isolation, on a major paper, put it on arxiv.org and the next day their colleagues would read it and ask interesting questions about them. Fame and fortune would follow. The thing that shocked Grimstrup was that not only did people not even care about any papers he posted, a young competitor even once told him some ideas are simply not worth pursuing even though they may be interesting. For sure, this is horrible and shocking behaviour, and does not reflect well on the anonymous person who said it.

For my part I am still naive enough to think that if new ideas are good, someone will recognise them as such, and network effects will make them known. I know that many researchers already think more deeply about what they are doing than he gives us credit for: and we discuss it, during seminars, over a drink with colleagues, in the coffee-breaks of conferences, during our annual or five-year reviews, or in grant applications. When I discussed this review with a string-theorist colleague they remarked "of course we know the situation sucks!''  I think Grimstrup is therefore wrong to tar everyone with the same brush: the diversity in our community has increased greatly with time, and this means that there are indeed strong incentives to take a risk on a novel idea, because the rewards of opening a new research direction are immense! Being the originator of an idea, or the first to recognise the merit in even an old forgotten idea, can yield tremendous results and even greater recognition nowadays thanks to the same effects. Hence, starting a new field, or even a subfield, is something that most researchers aspire to; the rewards for doing so are even greater now than in times gone by, and the evidence that this is possible is even given in this book: the existence of several communities working on different approaches to quantum gravity. He argues that these are now old and stale, but my point is that the way that they were able to take root at all is an example of how this can happen. There are many subfields that have sprung up more recently, and in other branches of HEP there are of course many examples. Nowadays things can change very quickly: a new good idea will be very rapidly jumped on once it is recognised, and people are constantly on the lookout. 

Grimstrup also, like Lee Smolin, divides researchers into visionaries and technicians. He then complains that the technicians have taken over, with lots of disparaging comments about them digging endless holes. He then complains that there is an incentive to collaborate in modern research, only collaborators survive in the system: he has evidence that being a lone wolf is a poor survival strategy. He believes that we should work on our own; yet at the same time visionaries need to collaborate with technicians. I found this very jarring. Other than the facile placing of people into boxes, he is overlooking the benefits of collaboration -- his opinion is that it is just about inflating the number of papers one person can sign (and for sure there are people who cynically do this). But to me, discussing with other people, even just explaining something, is often the quickest way to generate genuinely new ideas or solutions to problems that we may never have come up with alone. At the same time, there are plenty of people who do write papers alone; to take a leaf from his book and share a personal story, I once had a comment on a postdoc application that I had no single-author papers and therefore did not demonstrate independence. Hence, there are incentives and a good reason for young researches to work alone sometimes. I then wrote a single-author paper, as I have occasionally done since (and got the fellowship next time I applied); I would agree that there is a pleasure and some advantages in doing this, but to do this all the time would mean I would risk missing out on lots of new ideas and other perspectives, as well as the pleasure of regular interactions with collaborators, and it would also limit the scope of my projects, where I benefit from others' expertise. Or collaborations may just be working with a student, pursuing my ideas (hopefully they contribute some of their own!) and imparting my knowledge in the process. This is why I do not think that encouraging people to predominantly cloister themselves away to work alone for a long time is the most productive or healthy one. 

The book also has a very narrow focus as to the goal of high-energy physics. For the author, the quest is a "the next theory," but in essence this means a theory of quantum gravity, which he acknowledges would be far from being able to be tested with any present or near-future data. Otherwise, we should look for a mathematically rigorous definition of quantum field theory; he hopes these will be one and the same thing. This latter problem has proven to be both very hard and not obviously useful -- it is certainly not obvious that the solution should even be unique, for example a theory of strings would cure ultra-violet divergences, and the question of whether strings should be necessary for such a theory is one that I know people have tried to explore. I also recently attended a talk by Michael Douglas where he reviewed recent attempts on rigorous QFT, so it is a subject that is regarded as important but very difficult, and still being explored by a small number of people. Regarding quantum gravity, some people in the community have taken the opinion that if you have no data, it is not a good problem, and are working on other things. Or people try to make contact with data using e.g. EFT approaches to measuring quantum effects of gravity. The string theory community might say that we do have a theory of quantum gravity, in fact we have a landscape of them, and try e.g. to use it to answer questions about black hole information. But at the same time some people then complain that the leading string theorists have moved on to other things: there are lots of important open fundamental problems, and we just do not know how they are interlinked, if at all!

Grimstrup's insistence that the solution to what he sees as problems is to shrink competition and also encourage research outside of academia, reminded me of another Dane, subject of another book I read recently: king Cnut, famous for (presumably apocryphally) standing on the beach in front of his ministers and commanding the tide to turn back. Otherwise Grimstrup hopes for a crisis, perhaps one provoked by his book. He explicitly states that he does not want to fuel the anti-establishment or ant-academic movements, but I suspect that the only crises we might suffer would not be good for the field.  Perhaps one is already taking place in the US; perhaps people will take his message to heart despite his protests and start a DOGE-style decimation of research. Necessarily, in science we mark our own homework: only other scientists are capable of judging the claims of their peers. If we start opening this up to question then we will only end with government appointees deciding what are acceptable topics and directions, or shutting public funding down altogether. What would be left over would surely be even greater competition for scarce resources.

For me, the solution to the problems in the book, to the extent that I agree with them, is to regularly remind ourselves that we should always maintain a childlike curiosity and not close our minds to new ideas and new possibilities. This is the message from the text of Hamming, and very well put in the writings of Feynman (who Grimstrup bizarrely dismisses as a technician compared to Bohr). Otherwise of course in science it is necessary to have a community spirit, to realise that we are all trying to make progress in the best way we know how, and to help each other do so; and it is necessary to maintain healthy competition as a motivator. But both conflicting instincts -- to compete and to group into communities -- are vital parts of human nature and denying this has been the mistake of utopians throughout history. 

I am also sure that many of the complaints that Grimstrup assigns to high-energy physics could also be applied to society more generally. So instead of trying to hold back or reverse the societal changes of the last century we should try to work with them as best we can. We have to accept that we live now in an attention economy; and this gives new opportunities: blogging, social media, writing articles in science magazines or popular press, etc. Since Grimstrup is now, interestingly, an independent scientist, perhaps tying his own research program so closely with his book is embracing the modern world at last, and creating a brand as a radical outside thinker, that will be attractive to private backers. He promotes the path that he has followed, crowdfunding his research or seeking support of patrons, as a possible path for the independently minded once they have completed their training in academia, and in this I wish him well: he is clearly serious, determined and sincere. But while this is now part of twenty-first century society, many people have noticed that this modern trend is a return to the nineteenth century (or even earlier, e.g. Leonardo da Vinci being invited to France by François 1) where a wealthy patron was the only source of funding. 

by Mark Goodsell at July 15, 2025 10:39 AM

July 14, 2025

Clifford Johnson — The Power of the String Equation

[More technical post follows.] I've been working on this project with (UCSB postdoc) Maciej Kolanowski on and off for a while now, but only in the last couple of weeks did I have the time to hunker down and help push the writing of the results to the finish. For your Sunday reading pleasure, it is already up on the arXiv here (it came out Thursday but I've been too busy to pause to post about it - partly because I've begun work on writing up the next paper in the backlog). The title is "Extended JT supergravity and random matrix models: The power of the string equation", and it is co-authored with Maciej Kolanowski.

In a way, it is a natural continuation of work I've described here from 2023 and 2024, described here and here. At a meeting at the Institute for Advanced Study in December 2023 I described in a talk (YouTube video here, look in particular from minute 35) something miraculous I'd discovered concerning capturing certain special supergravity (and black hole) behaviour using a random matrix model. The effective physics is [...] Click to continue reading this post →

The post The Power of the String Equation appeared first on Asymptotia.

by Clifford at July 14, 2025 09:05 PM

July 11, 2025

Justin Wilson — Two Dimensional Materials have gone crazy!

There are a ton of two-dimensional materials these days. You’ve probably heard of graphene, a single layer of carbon atoms arranged in a hexagonal grid.

In 2018, everything changed when two layers of graphene were twisted to reveal superconductivity! The twist itself is interesting (I briefly discussed it in a previous post), but the key takeaway is that these materials now come with an extra knob for accessing new phases of matter. It’s remarkable. We can first think of these materials like Lego blocks:

Each layer is a different material: mix and match, and you might discover an exotic new phase. This “Lego” idea had already been in the air before 2018, but the physics since then has shown that it’s not just about stacking—we can twist too, creating not just patterns, but new ways for electrons to move.

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We knew these patterns would occur, but we didn’t realize we could make it superconduct. Now we can stack and twist to great effect. Of course, twisted bilayer graphene isn’t about to revolutionize high-speed trains (it goes superconducting at only 4K1), but the way it goes superconducting is eerily reminiscent of higher-temperature superconductors. That means it might help us understand those other materials better.

And once people started twisting, they didn’t stop. We now have twisted multilayers of graphene, transition-metal dichalcogenide (TMD) bilayers2, and more. But it doesn’t end there; you can also apply magnetic fields, electric fields, and pattern the lattice in sophisticated ways. With all that in mind, here’s a short and incomplete survey of some of the exotic phases in these materials:

“Fractional… what now?”

All of these phases are exceptionally hard to understand and model. Some of the best minds in the field are actively working on them. One particularly exciting phase is the fractional Chern insulator, which could be useful for quantum computing.

But even setting aside applications, what’s astonishing is that all of these phenomena come from nothing more than electrons moving on a lattice and experiencing a few fields. Nature seems to treat electrons like Play-Doh, shaping them into wildly different quantum phases.

This is a deep and fundamental question: What can be accomplished using electrons alone?

1

That’s -452.47 degrees Fahrenheit.

2

To this day, I still can’t say the full name, so I just say “TMD.”

© Justin H Wilson at July 11, 2025 02:31 PM

July 10, 2025

Scott Aaronson Trump and Iran, by popular request

I posted this on my Facebook, but several friends asked me to share more widely, so here goes:

I voted against Trump three times, and donated thousands to his opponents. I’d still vote against him today, seeing him as a once-in-a-lifetime threat to American democracy and even to the Enlightenment itself.

But last night I was also grateful to him for overruling the isolationists and even open antisemites in his orbit, striking a blow against the most evil regime on the planet, and making it harder for that regime to build nuclear weapons. I acknowledge that his opponents, who I voted for, would’ve probably settled for a deal that would’ve resulted in Iran eventually getting nuclear weapons, and at any rate getting a flow of money to redirect to Hamas, Hezbollah, and the Houthis.

May last night’s events lead to the downfall of the murderous ayatollah regime altogether, and to the liberation of the Iranian people from 46 years of oppression. To my many, many Iranian friends: I hope all your loved ones stay safe, and I hope your great people soon sees better days. I say this as someone whose wife and 8-year-old son are right now in Tel Aviv, sheltering every night from Iranian missiles.

Fundamentally, I believe not only that evil exists in the world, but that it’s important to calibrate evil on a logarithmic scale. Trump (as I’ve written on this blog for a decade) terrifies me, infuriates me, and embarrasses me, and through his evisceration of American science and universities, has made my life noticeably worse. On the other hand, he won’t hang me from a crane for apostasy, nor will he send a ballistic missile to kill my wife and son and then praise God for delivering them into his hands.

---

Update: I received the following comment on this post, which filled me with hope, and demonstrated more moral courage than perhaps every other anonymous comment in this blog’s 20-year history combined. To this commenter and their friends and family, I wish safety and eventually, liberation from tyranny.

I will keep my name private for clear reasons. Thank you for your concern for Iranians’ safety and for wishing the mullah regime’s swift collapse. I have fled Tehran and I’m physically safe but mentally, I’m devastated by the war and the internet blackout (the pretext is that Israeli drones are using our internet). Speaking of what the mullahs have done, especially outrageous was the attack on the Weizmann Institute. I hope your wife and son remain safe from the missiles of the regime whose thugs have chased me and my friends in the streets and imprisoned my friends for simple dissent. All’s well that ends well, and I hope this all ends well.

by Scott at July 10, 2025 02:37 PM

July 08, 2025

Terence Tao — Salem Prize now accepting nominations for 2025

The Salem prize was established in 1968 and named in honor of Raphaël Salem (1898-1963), a mathematician famous notably for his deep study of the links between Fourier series and number theory and for pioneering applications of probabilistic methods to these fields. It was not awarded from 2019-2022, due to both the COVID pandemic and the death of Jean Bourgain who had been almost single-handedly administering the prize, but is now active again, being administered by Akshay Ventakesh and the IAS. I chair the scientific committee for this prize, whose other members are Guy David and Mikhail Sodin. Last year, the prize was awarded to Miguel Walsh and Yilin Wang.

Nominations for the 2025 Salem Prize are now open until September 15th. Nominations should include a CV of the nominee and a nomination letter explaining the significance of the nominee’s work. Supplementary documentation, such as supporting letters of recommendation or key publications, can additionally be provided, but are not required.

Nominees may be individuals from any country or institution. Preference will be given to nominees who have received their PhD in the last ten years, although this rule may be relaxed if there are mitigating personal circumstances, or if there have been few Salem prize winners in recent years.  Self-nominations will not be considered, nor are past Prize winners or Scientific Committee members eligible.

The prize does not come with a direct monetary award, but winners will be invited to visit the IAS and to give a lecture associated with the award of the prize.

See also the previous year’s announcement of the Salem prize nomination period.

by Terence Tao at July 08, 2025 03:30 PM

July 07, 2025

Matt Strassler Extreme and Dumb Cuts to US Science

As many of you are no doubt aware, in the past few days the US Congress voted to make major cuts to scientific research, and the president signed the bill. The government’s National Science Foundation has been cut by more than half, which means that its actual science budget has been cut by much more than that after you account for fixed costs. So vast, sudden and draconian are these cuts that it will take a long time for me and others in the field to figure out what has actually happened.

The reductions seem extreme, quite arbitrary and very poorly thought out. As an example, half of the LIGO observatory (the Laser Interferometer Gravitational-Wave Observatory, whose amazing discoveries, such as this one and this one, earned the United States a Nobel Prize in 2017) is being hit hard. There are currently two interferometers, one in Washington state and one in Lousiana, but one has been largely defunded in this bill, if I understand correctly.

I can see the logic: the scientists have two interferometers, but in tough times they ought to be able to get along with just one, right?

Well, that’s like cutting off one of a runner’s legs. Two were built because two were needed.

With just one, the signal from most gravitational wave events is so weak that you can’t distinguish it from noise. Other interferometers around the world just aren’t working well enough to make up for throwing away one of LIGOs. (And besides, you need three or four interferometers around the world to be able to know precisely in the sky where the waves are coming from, knowledge which can make other major discoveries possible.)

According to Science magazine, “In a two-sentence email to Science, an NSF spokesperson said the plan reflects `a strategic alignment of resources in a constrained fiscal environment.’ “

This is not strategic. This is stupid. The amount of money saved, less than 10 cents per year per US citizen, is very small compared to what we as a nation have already spent on this wonderful facility, and cutting LIGO in half makes it dramatically less than half as good — so this is actually a big waste of money both past and future. The decision to make this cut in this way is nothing short of ridiculous and incompetent.

[Not to mention that “constrained fiscal environment” is quite a phrase when you’re increasing the budget deficit rather than shrinking it.]

I fear there are many other similar examples to be found.

by Matt Strassler at July 07, 2025 02:05 PM

June 27, 2025

Justin Wilson — Water and its phases

I’m working on a much longer post on phases and phase transitions for next week1, but in the meantime, let me share with you some cool facts about water and its “phases.”

\We all know about solids, liquids, and gases from school. Heat up ice, and you get water; heat up water, and you get vapor. We may even have been slightly baffled if we saw this phase diagram with “pressure” added to the mix

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I see here a solid phase, a liquid phase, and a gas phase, but what is this “Critical point”? If you tune your temperature and pressure just right you can smoothly cross over from liquid to gas without ever undergoing a phase transition. Without getting into the molecular details, we can think of phases as particular valleys between mountains, and water wants to reach the absolute lowest point. Sometimes there are two valleys, but one is lower, and sometimes there is just one valley.

In fact, this “number of valleys” is why we see this odd behavior. If we sit at 100 degrees C and decrease or increase the pressure, there are two energy minima2—two valleys. At small pressure, the deepest valley is on the gas side, and at large pressure, the deepest valley is on the liquid side. As you then tune pressure across that one-bar point, one valley gets deeper than the other—it’s the true minimum! Yet, to get from one valley to the next, you need some energy to get you over that mountain in between. That’s the phase transition. However, that's not the only option. As the temperature increases, the mountain in between gets smaller and smaller until, at the critical point, it finally disappears, and the two valleys merge.

Without two distinguished valleys, there is no need to scale the mountain and no need for a phase transition. Liquid smoothly and easily becomes gas. At the temperatures above the critical point, you cannot meaningfully distinguish water and gas. OK, so perhaps we only have two phases?

Not quite; look at this more fleshed-out version of the phase diagram:

When ice forms, it adopts a low-energy crystal structure. However, there are numerous crystal structures to choose from. In fact, as you change pressure and temperature, it can completely reorganize how the ice bonds together into a crystal. This leads to over 20 phases of ice, labeled by some of the Roman numerals above.3

Then what are the phases? Solids undergo their own phase transitions—structural phase transitions. Are these not phases of matter? If they are, then we have already exceeded our three phases of matter just within water. But phases go beyond temperature and pressure. They also possess a multitude of interesting properties, particularly at that critical point. We'll cover some of that in detail next week.

1

We’ll be making our own phase! Related, of course, to a known phase transition.

2

For most of the phase diagram, there is one absolute minimum, and the other is a “metastable” or local minimum.

3

For those interested, this Wikipedia article has a lot of information on the phases of ice.

© Justin H Wilson at June 27, 2025 02:31 PM