Planet Musings

October 28, 2025

Scott Aaronson An Experimental Program for AI-Powered Feedback at STOC: Guest Post from David Woodruff

This year for STOC, we decided to run an experiment to explore the use of Large Language Models in the theoretical computer science community, and we’re inviting the entire community to participate.

We—a team from the STOC PC—are offering authors the chance to get automated pre-submission feedback from an advanced, Gemini-based LLM tool that’s been optimized for checking mathematical rigor. The goal is simple: to provide constructive suggestions and, potentially, help find technical mistakes before the paper goes to the PC. Some important points:

This is 100% optional and opt-in.
The reviews generated WILL NOT be passed on to the PC. They are for your eyes only.
Data Privacy is Our #1 Commitment. We commit that your submitted paper will NOT be logged, stored, or used for training.
Please do not publicly share these reviews without contacting the organizing team first.

This tool is specifically optimized for checking a paper’s mathematical rigor. It’s a hopefully useful way to check the correctness of your arguments. Note that sometimes it does not possess external, area-specific knowledge (like “folklore” results). This means it may flag sections that rely on unstated assumptions, or it might find simple omissions or typos.

Nevertheless, we hope you’ll find this feedback valuable for improving the paper’s overall clarity and completeness.

If you’re submitting to STOC, we encourage you to opt-in. You’ll get (we hope) useful feedback, and you’ll be providing invaluable data as we assess this tool for future theory conferences.

The deadline to opt-in on the HotCRP submission form is November 1 (5pm EST).

You can read the full “Terms of Participation” (including all privacy and confidentiality details) at the link below.

This experiment is being run by PC members David Woodruff (CMU) and Rajesh Jayaram (Google), as well as Vincent Cohen-Addad (Google) and Jon Schneider (Google).

We’re excited to offer this resource to the community.

Please see the STOC Call for Papers here and specific details on the experiment here.

by Scott at October 28, 2025 09:36 PM

n-Category Café Applied Category Theory 2026

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

The next annual conference on applied category theory is in Estonia!

Applied Category Theory 2026, Tallinn, Estonia, 6–10 July, 2026. Preceded by the Adjoint School Research Week, 29 June – 3 July.

For more details, read on!

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

The conference particularly encourages participation from underrepresented groups. The organizers are committed to non-discrimination, equity, and inclusion. The code of conduct for the conference is available here.

Deadlines

Registration: TBA
Abstracts Due: 23 March 2026
Full Papers Due: 30 March 2026
Author Notification: 11 May 2026
Adjoint School: 29 June – 3 July 2026
Conference: 6 – 10 July 2026
Final versions of papers for proceedings due: TBA

Submissions

ACT2026 accepts submissions in English, in the following three tracks:

Research
Software demonstrations
Teaching and communication

The detailed Call for Papers is available here.

Extended abstracts and conference papers should be prepared with LaTeX. For conference papers please use the EPTCS style files available here. The submission link is here.

Reviewing is single-blind, and we are not making public the reviews, reviewer names, the discussions nor the list of under-review submissions. This is the same as previous instances of ACT.

Program Committee Chairs

Geoffrey Cruttwell, Mount Allison University, Sackville
Priyaa Varshinee Srinivasan, Tallinn University of Technology, Estonia

Program Committee

Alexis Toumi, Planting Space
Bryce Clarke, Tallinn University of Technology
Barbara König, University of Duisburg-Essen
Bojana Femic, Serbian Academy of Sciences and Arts
Chris Heunen, The University of Edinburgh
Daniel Cicala, Southern Connecticut State University
Dusko Pavlovic, University of Hawaii
Evan Patterson, Topos Institute
Fosco Loregian, Tallinn University of Technology
Gabriele Lobbia, Università di Bologna
Georgios Bakirtzis, Institut Polytechnique de Paris
Jade Master, University of Strathclyde
James Fairbanks, University of Florida
Jonathan Gallagher, Hummingbird Biosciences
Joe Moeller, Caltech
Jules Hedges, University of Strathclyde
Julie Bergner, University of Virginia
Kohei Kishida, University of Illinois, Urbana-Champaign
Maria Manuel Clementino, CMUC, Universidade de Coimbra
Mario Román, University of Oxford
Marti Karvonen, University College London
Martina Rovelli, UMass Amherst
Masahito Hasegawa, Kyoto University
Matteo Capucci, University of Strathclyde
Michael Shulman, University of San Diego
Nick Gurski, Case Western Reserve University
Niels Voorneveld, Cybernetica
Paolo Perrone, University of Oxford
Peter Selinger, Dalhousie University
Paul Wilson, University of Southampton
Robin Cockett, University of Calgary
Robin Piedeleu, University College London
Rory Lucyshyn-Wright, Brandon University
Rose Kudzman-Blais, University of Ottawa
Ryan Wisnesky, Conexus AI
Sam Staton, University of Oxford
Shin-Ya Katsumata, Kyoto Sangyo University
Simon Willerton, University of Sheffield
Spencer Breiner, National Institute of Standards and Technology
Tai Danae Bradley, SandboxAQ
Titouan Carette, École Polytechnique
Tom Leinster, The University of Edinburgh
Walter Tholen, York University

Teaching & Communication

Selma Dündar-Coecke, University College London, Institute of Education
Ted Theodosopoulos, Nueva School

Organizing Committee

Pawel Sobocinski, Tallinn University of Technology
Priyaa Varshinee Srinivasan, Tallinn University of Technology
Sofiya Taskova, Tallinn University of Technology
Kristi Ainen, Tallinn University of Technology

Steering Committee

John Baez, University of California, Riverside
Bob Coecke, University of Oxford
Dorette Pronk, Dalhousie University
David Spivak, Topos Institute
Michael Johnson, Macquarie University
Simona Paoli, University of Aberdeen

October 27, 2025

John Baez — Philip Gibbs – Black Holes and White Holes

A white hole is a purely hypothetical time-reversed black hole. What does general relativity say about them? Would they repel you? Could you fall into a white hole—or only fall out? Could the universe be a white hole?

Philip Gibbs answers all these questions and more in my first interview for Edinburgh Explorations—a series put out by the School of Mathematics and the School of Physics and Astronomy at the University of Edinburgh.

I met Philip online on sci.physics in the early 1990s, and together with a bunch of other folks we created the Physics FAQ, which answers a lot of the most fascinating questions about physics. At first I didn’t believe everything he said about white holes, but eventually I realized he was right!

What do I mean by “right”? Be careful: white holes are just solutions of the equations of general relativity, not things we’ve actually seen. But you can work out what general relativity predicts about them: that’s the game here, and that determines what’s “right”. It doesn’t mean white holes actually exist and do these things.

For the physics FAQ, much of it created by Philip Gibbs, go here.

The cover picture, showing the maximally extended Schwarzschild solution containing both a black hole and white hole, was made by Isaak Neutelings.

by John Baez at October 27, 2025 09:54 AM

John Preskill — The sequel

This October, fantasy readers are devouring a sequel: the final installment in Philip Pullman’s trilogy The Book of Dust. The series follows student Lyra Silvertongue as she journeys from Oxford to the far east. Her story features alternate worlds, souls that materialize as talking animals, and a whiff of steampunk. We first met Lyra in the His Dark Materials trilogy, which Pullman began publishing in 1995. So some readers have been awaiting the final Book of Dust volume for 30 years.

Another sequel debuts this fall. It won’t spur tens of thousands of sales; nor will Michael Sheen narrate an audiobook version of it. Nevertheless, the sequel should provoke as much thought as Pullman’s: the sequel to the Maryland Quantum-Thermodynamics Hub’s first three years.

More deserving of a Carnegie Medal than our hub, but the hub deserves no less enthusiasm!

The Maryland Quantum-Thermodynamics Hub debuted in 2022, courtesy of a grant from the John F. Templeton Foundation. Six theorists, three based in Maryland, have formed the hub’s core. Our mission has included three prongs: research, community building, and outreach. During the preceding decade, quantum thermodynamics had exploded, but mostly outside North America. We aimed to provide a lodestone for the continent’s quantum-thermodynamics researchers and visitors.

Also, we aimed to identify the thermodynamics of how everyday, classical physics emerges from quantum physics. Quantum physics is reversible (doesn’t distinguish the past from the future), is delicate (measuring a quantum system can disturb it), and features counterintuitive phenomena such as entanglement. In contrast, our everyday experiences include irreversibility (time has an arrow), objectivity (if you and I read this article, we should agree about its contents), and no entanglement. How does quantum physics give rise to classical physics at large energy and length scales? Thermodynamics has traditionally described macroscopic, emergent properties. So quantum thermodynamics should inform our understanding of classical reality’s emergence from quantum mechanics.

Our team has approached this opportunity from three perspectives. One perspective centers on quantum Darwinism, a framework for quantifying how interactions spread information about an observed quantum system. Another perspective highlights decoherence, the contamination of a quantum system by its environment. The third perspective features incompatible exchanged quantities, described in an earlier blog post. Or two. Or at least seven.

Each perspective led us to discover a tension, or apparent contradiction, that needs resolving. One might complain that we failed to clinch a quantum-thermodynamic theory of the emergence of classical reality. But physicists adore apparent contradictions as publishers love splashing “New York Times bestseller” on their book covers. So we aim to resolve the tensions over the next three years.

Physicists savor paradoxes and their ilk.

I’ll illustrate the tensions with incompatible exchanged quantities, of course. Physicists often imagine a small system, such as a quantum computer, interacting with a large environment, such as the surrounding air and the table on which the quantum computer sits. The system and environment may exchange energy, particles, electric charge, etc. Typically, the small system thermalizes, or reaches a state mostly independent of its initial conditions. For example, after exchanging enough energy with its environment, the system ends up at the environment’s temperature, mostly regardless of the system’s initial temperature.

For decades, physicists implicitly assumed that the exchanged quantities are compatible: one can measure them simultaneously. But one can’t measure all of a quantum system’s properties simultaneously. Position and momentum form the most famous examples. Incompatibility epitomizes quantum physics, underlying Heisenberg’s uncertainty relation, quantum error correction, and more. So collaborators and I ask how exchanged quantities’ incompatibility alters thermalization, which helps account for time’s arrow.

Our community has discovered that such incompatibility can hinder certain facets of thermalization—in a sense, stave off certain aspects of certain quantum systems’ experience of time. But incompatible exchanged quantities enhance other features of thermalization. How shall we reconcile the hindrances with the enhancements? Does one of the two effects win out? I hope to report back in three years. For now, I’m rooting for Team Hindrance.

In addition to resolving apparent conflicts, we’re adding a fourth perspective to our quiver—a gravitational one. In our everyday experiences, space-time appears smooth; unlike Lyra’s companion Will in The Subtle Knife, we don’t find windows onto other worlds. But quantum physics, combined with general relativity, suggests that you’d find spikes and dips upon probing space-time over extremely short length scales. How does smooth space-time emerge from its quantum underpinnings? Again, quantum thermodynamics should help us understand.

To address these challenges, we’re expanding the hub’s cast of characters. The initial cast included six theorists. Two more are joining the crew, together with the hub’s first two experimentalists. So is our first creative-writing instructor, who works at the University of Maryland (UMD) Jiménez-Porter Writers’ House.

As the hub has grown, so has the continent’s quantum-thermodynamics community. We aim to continue expanding that community and strengthening its ties to counterparts abroad. As Lyra learned in Pullman’s previous novel, partnering with Welsh miners and Czech book sellers and Smyrnan princesses can further one’s quest. I don’t expect the Maryland Quantum-Thermodynamics Hub to attract Smyrnan princesses, but a girl can dream. The hub is already partnering with the John F. Templeton Foundation, Normal Computing, the Fidelity Center for Applied Technology, the National Quantum Laboratory, Maryland’s Capital of Quantum team, and more. We aim to integrate quantum thermodynamics into North America’s scientific infrastructure, so that the field thrives here even after our new grant terminates. Reach out if you’d like to partner with us.

To unite our community, the hub will host a gathering—a symposium or conference—each year. One conference will feature quantum thermodynamics and quantum-steampunk creative writing. Scientists and authors will present. We hope that both groups will inspire each other, as physicist David Deutsch’s work on the many-worlds formulation of quantum theory inspired Pullman.

That conference will follow a quantum-steampunk creative-writing course to take place at UMD during spring 2026. I’ll co-teach the course with creative-writing instructor Edward Daschle. Students will study quantum thermodynamics, read published science-fiction stories, write quantum-steampunk stories, and critique each other’s writing. Five departments have cross-listed the course: physics, arts and humanities, computer science, chemistry, and mechanical engineering. If you’re a UMD student, you can sign up in a few weeks. Do so early; seats are limited! We welcome graduate students and undergrads, the latter of whom can earn a GSSP general-education credit.¹ Through the course, the hub will spread quantum thermodynamics into Pullman’s world—into literature.

Pullman has entitled his latest novel The Rose Field. The final word refers to an object studied by physicists. A field, such as an electric or gravitational field, is a physical influence spread across space. Hence fiction is mirroring physics—and physics can take its cue from literature. As ardently as Lyra pursues the mysterious particle called Dust, the Maryland Quantum-Thermodynamics Hub is pursuing a thermodynamic understanding of the classical world’s emergence from quantum physics. And I think our mission sounds as enthralling as Lyra’s. So keep an eye on the hub for physics, community activities, and stories. The telling of Lyra’s tale may end this month, but the telling of the hub’s doesn’t.

¹Just don’t ask me what GSSP stands for.

by Nicole Yunger Halpern at October 27, 2025 12:03 AM

October 26, 2025

Doug Natelson — Science journalism - dark times

At this point it's old hat to decry the problems facing traditional news media. Still, it is abundantly clear in our late stage capitalist society that there has been a collective business decision over the last 20+ years that, like local newspapers and television news, real science journalism is not a money maker. Just a few examples: Seventeen years ago, CNN cut its entire science, technology and environment reporting team. In 2022, Popular Science ceased publication. In 2023, National Geographic laid off their staff writers. Last week, the Wall Street Journal laid off their science and health reporters.

I have it on good authority that there is now only one science reporter left at the WSJ. One, at a time when science and technology are more critically important to our rapidly changing society than ever, and there is enormous tumult in the US and elsewhere about how science is or is not supported and is or is not factoring into policy decisions. All of this is happening at a time when public trust in science is falling. (Check out this from Science Friday.)

To be sure, there are some great publications out there, like Quanta and Nautilus (both founded by nonprofits). There are outstanding public writers of science, like Philip Ball, Helen Czerski, Katie Mack, Ethan Siegel, and many others (apologies for the incompleteness of this list). There are some excellent freelance journalists. The internet also means that there are many opportunities for great engagement. For example, the videos from 3blue1brown are uniformly outstanding. However, there are no filters, and the temptation to be click-baity or sensationalistic is problematic.

I have no solutions to offer, except that I encourage you to support good science journalism and reporting when you see it. It's important.

by Douglas Natelson at October 26, 2025 01:52 AM

October 24, 2025

Matt von Hippel — C. N. Yang, Dead at 103

I don’t usually do obituaries here, but sometimes I have something worth saying.

Chen Ning Yang, a towering figure in particle physics, died last week.

Picture from 1957, when he received his Nobel

I never met him. By the time I started my PhD at Stony Brook, Yang was long-retired, and hadn’t visited the Yang Institute for Theoretical Physics in quite some time.

(Though there was still an office door, tucked behind the institute’s admin staff, that bore his name.)

The Nobel Prize doesn’t always honor the most important theoretical physicists. In order to get a Nobel Prize, you need to discover something that gets confirmed by experiment. Generally, it has to be a very crisp, clear statement about reality. New calculation methods and broader new understandings are on shakier ground, and theorists who propose them tend to be left out, or at best combined together into lists of partial prizes long after the fact.

Yang was lucky. With T. D. Lee, he had made that crisp, clear statement. He claimed that the laws of physics, counter to everyone’s expectations, are not the same when reflected in a mirror. In 1956, Wu confirmed the prediction, and Lee and Yang got the prize the year after.

That’s a huge, fundamental discovery about the natural world. But as a theorist, I don’t think that was Yang’s greatest accomplishment.

Yang contributed to other fields. Practicing theorists have seen his name strewn across concepts, formalisms, and theorems. I didn’t have space to talk about him in my article on integrability for Quanta Magazine, but only just barely: another paragraph or two, and he would have been there.

But his most influential contribution is something even more fundamental. And long-time readers of this blog should already know what it is.

Yang, along with Robert Mills, proposed Yang-Mills Theory.

There isn’t a Nobel prize for Yang-Mills theory. In 1953, when Yang and Mills proposed the theory, it was obviously wrong, a theory that couldn’t explain anything in the natural world, mercilessly mocked by famous bullshit opponent Wolfgang Pauli. Not even an ambitious idea that seemed outlandish (like plate tectonics), it was a theory with such an obvious missing piece that, for someone who prioritized experiment like the Nobel committee does, it seemed pointless to consider.

All it had going for it was that it was a clear generalization, an obvious next step. If there are forces like electromagnetism, with one type of charge going from plus to minus, why not a theory with multiple, interacting types of charge?

Nothing about Yang-Mills theory was impossible, or contradictory. Mathematically, it was fine. It obeyed all the rules of quantum mechanics. It simply didn’t appear to match anything in the real world.

But, as theorists learn, nature doesn’t let a good idea go to waste.

Of the four fundamental forces of nature, as it would happen, half are Yang-Mills theories. Gravity is different, electromagnetism is simpler, and could be understood without Yang and Mills’ insights. But the weak nuclear force, that’s a Yang-Mills theory. It wasn’t obvious in 1953 because it wasn’t clear how the massless, photon-like particles in Yang-Mills theory could have mass, and it wouldn’t become clear until the work of Peter Higgs over a decade later. And the strong nuclear force, that’s also a Yang-Mills theory, missed because of the ability of such a strong force to “confine” charges, hiding them away.

So Yang got a Nobel, not for understanding half of nature’s forces before anyone else had, but from a quirky question of symmetry.

In practice, Yang was known for all of this, and more. He was enormously influential. I’ve heard it claimed that he personally kept China from investing in a new particle collider, the strength of his reputation the most powerful force on that side of the debate, as he argued that a developing country like China should be investing in science with more short-term industrial impact, like condensed matter and atomic physics. I wonder if the debate will shift with his death, and what commitments the next Chinese five-year plan will make.

Ultimately, Yang is an example of what a theorist can be, a mix of solid work, counterintuitive realizations, and the thought-through generalizations that nature always seems to make use of in the end. If you’re not clear on what a theoretical physicist is, or what one can do, let Yang’s story be your guide.

by 4gravitons at October 24, 2025 04:00 PM

Tommaso Dorigo — Are We Stochastic Parrots, Too? What LLMs Teach Us About Intelligence And Understanding

Having interacted for a few months with ChatGPT 5 now, both for work-related problems and for private / self-learning tasks, I feel I might share some thoughts here on what these large models can tell us about our own thought processes.

The sentence above is basically giving away my bottomline from square one, but I suppose I can elaborate a bit more on the concept. LLMs have revolutionized a wide range of information-processing tasks in just three or four years. Looking back, the only comparable breakthrough I can recall is the advent of internet search engines in the early 1990s. But as exciting and awesome this breakthrough is, it inspires me still more to ponder on how this is even possible. Let me unpack this.

by Tommaso Dorigo at October 24, 2025 11:48 AM

October 22, 2025

Terence Tao — Smooth numbers and max-entropy

Given a threshold ${y>1}$ , a ${y}$ -smooth number (or ${y}$ -friable number) is a natural number ${n}$ whose prime factors are all at most ${y}$ . We use ${\Psi(x,y)}$ to denote the number of ${y}$ -smooth numbers up to ${x}$ . In studying the asymptotic behavior of ${\Psi(x,y)}$ , it is customary to write ${y}$ as ${x^{1/u}}$ (or ${x}$ as ${y^u}$ ) for some ${u>0}$ . For small values of ${u}$ , the behavior is straightforward: for instance if ${0 < u < 1}$ , then all numbers up to ${x}$ are automatically ${y}$ -smooth, so

$\displaystyle \Psi(x,y) \sim x$

in this case. If ${1 < u < 2}$ , the only numbers up to ${x}$ that are not ${y}$ -smooth are the multiples of primes ${p}$ between ${y}$ and ${x}$ , so

$\displaystyle \Psi(x,y) \sim x - \sum_{y < p \leq x} (\frac{x}{p} + O(1))$

$\displaystyle \sim x - x (\log\log x - \log\log y)$

$\displaystyle \sim x (1 - \log u)$

where we have employed Mertens’ second theorem. For ${2 < u < 3}$ , there is an additional correction coming from multiples of two primes between ${y}$ and ${x}$ ; a straightforward inclusion-exclusion argument (which we omit here) eventually gives

$\displaystyle \Psi(x,y) \sim x (1 - \log u + \int_2^u \frac{\log(t-1)}{t} dt)$

in this case.

More generally, for any fixed ${u>0}$ , de Bruijn showed that

$\displaystyle \Psi(x, y) \sim \rho(u) x$

where ${\rho(u)}$ is the Dickman function. This function is a piecewise smooth, decreasing function of ${u}$ , defined by the delay differential equation

$\displaystyle u \rho'(u) + \rho(u-1) = 0$

with initial condition ${\rho(u) = 1}$ for ${0 \leq u \leq 1}$ .

The asymptotic behavior of ${\rho(u)}$ as ${u \rightarrow \infty}$ is rather complicated. Very roughly speaking, it has inverse factorial behavior; there is a general upper bound ${\rho(u) \leq 1/\Gamma(u+1)}$ , and a crude asymptotic

$\displaystyle \rho(u) = u^{-u+o(u)} = \exp( - u \log u + o(u \log u)).$

With a more careful analysis one can refine this to

$\displaystyle \rho(u) = \exp( - u \log u - u \log\log u + u + o(u)); \ \ \ \ \ (1)$

and with a very careful application of the Laplace inversion formula one can in fact show that

$\displaystyle \rho(u) \sim \sqrt{\frac{\xi'(u)}{2\pi}} \exp( \gamma - u \xi(u) + \int_0^{\xi(u)} \frac{e^s - 1}{s} ds) \ \ \ \ \ (2)$

where ${\gamma}$ is the Euler-Mascheroni constant and ${\xi(u)}$ is defined implicitly by the equation

$\displaystyle e^{\xi(u)} - 1 = u \xi(u). \ \ \ \ \ (3)$

One cannot write ${\xi(u)}$ in closed form using elementary functions, but one can express it in terms of the Lambert ${W}$ function as ${\xi(u) = -W(-\frac{1}{u} e^{-1/u}) - 1/u}$ . This is not a particularly enlightening expression, though. A more productive approach is to work with approximations. It is not hard to get the initial approximation ${\xi(u) \approx \log u}$ for large ${u}$ , which can then be re-inserted back into (3) to obtain the more accurate approximation

$\displaystyle \xi(u) = \log u + \log\log u + O(1)$

and inserted once again to obtain the refinement

$\displaystyle \xi(u) = \log u + \log\log u + O(\frac{\log\log u}{\log u}).$

We can now see that (2) is consistent with previous asymptotics such as (1), after comparing the integral ${\int_0^{\xi(u)} \frac{e^s - 1}{s} ds}$ to

$\displaystyle \int_0^{\xi(u)} \frac{e^s - 1}{\xi(u)} ds = u - 1.$

For more details of these results, one can see for instance this survey by Granville.

This asymptotic (2) is quite complicated, and so one does not expect there to be any simple argument that could recover it without extensive computation. However, it turns out that one can use a “maximum entropy” analysis to get a reasonably good heuristic approximation to (2), that at least reveals the role of the mysterious function ${\xi(u)}$ . The purpose of this blog post is to give this heuristic.

Viewing ${x = y^u}$ , the task is to try to count the number of ${y}$ -smooth numbers of magnitude ${y^u}$ . We will propose a probabilistic model to generate ${y}$ -smooth numbers as follows: for each prime ${p \leq y}$ , select the prime ${p}$ with an independent probability ${c_p/p}$ for some coefficient ${c_p}$ , and then multiply all the selected primes together. This will clearly generate a random ${y}$ -smooth number ${n}$ , and by the law of large numbers, the (log-)magnitude of this number should be approximately

$\displaystyle \log n \approx \sum_{p \leq y} \frac{c_p}{p} \log p, \ \ \ \ \ (4)$

(where we will be vague about what “ ${\approx}$ ” means here), so to obtain a number of magnitude about ${y^u}$ , we should impose the constraint

$\displaystyle \sum_{p \leq y} \frac{c_p}{p} \log p = u \log y. \ \ \ \ \ (5)$

The indicator ${1_{p|n}}$ of the event that ${p}$ divides this number is a Bernoulli random variable with mean ${c_p/p}$ , so the Shannon entropy of this random variable is

$\displaystyle \mathbf{H}(1_{p|n}) = - \frac{c_p}{p} \log(\frac{c_p}{p}) - (1 - \frac{c_p}{p}) \log(1 - \frac{c_p}{p}).$

If ${c_p}$ is not too large, then Taylor expansion gives the approximation

$\displaystyle \mathbf{H}(1_{p|n}) \approx \frac{c_p}{p} \log p - \frac{c_p}{p} \log c_p + \frac{c_p}{p}.$

Because of independence, the total entropy of this random variable ${n}$ is

$\displaystyle \mathbf{H}(n) = \sum_{p \leq y} \mathbf{H}(1_{p|n});$

inserting the previous approximation as well as (5), we obtain the heuristic approximation

$\displaystyle \mathbf{H}(n) \approx u \log y - \sum_{p \leq y} \frac{c_p}{p} (\log c_p - 1).$

The asymptotic equipartition property of entropy, relating entropy to microstates, then suggests that the set of numbers ${n}$ that are typically generated by this random process should have cardinality approximately

$\displaystyle \exp(\mathbf{H}(n)) \approx \exp\left(u \log y - \sum_{p \leq y} \frac{c_p}{p} (\log c_p - 1)\right)$

$\displaystyle = \exp\left(- \sum_{p \leq y} \frac{c_p \log c_p - c_p}{p}\right) x.$

Using the principle of maximum entropy, one is now led to the approximation

$\displaystyle \rho(u) \approx \exp\left(- \sum_{p \leq y} \frac{c_p \log c_p - c_p}{p}\right). \ \ \ \ \ (6)$

where the weights ${c_p}$ are chosen to maximize the right-hand side subject to the constraint (5).

One could solve this constrained optimization problem directly using Lagrange multipliers, but we simplify things a bit by passing to a continuous limit. We take a continuous ansatz ${c_p = f(\log p / \log y)}$ , where ${f: [0,1] \rightarrow {\bf R}}$ is a smooth function. Using Mertens’ theorem, the constraint (5) then heuristically becomes

$\displaystyle \int_0^1 f(t)\ dt = u \ \ \ \ \ (7)$

and the expression (6) simplifies to

$\displaystyle \rho(u) \approx \exp( - \int_0^1 \frac{f(t) \log f(t) - f(t)}{t}\ dt). \ \ \ \ \ (8)$

So the entropy maximization problem has now been reduced to the problem of minimizing the functional ${\int_0^1 \frac{f(t) \log f(t) - f(t)}{t}\ dt}$ subject to the constraint (7). The astute reader may notice that the integral in (8) might diverge at ${t=0}$ , but we shall ignore this technicality for the sake of the heuristic arguments.

This is a standard calculus of variations problem. The Euler-Lagrange equation for this problem can be easily worked out to be

$\displaystyle \frac{\log f(t)}{t} = \lambda$

for some Lagrange multiplier ${\lambda}$ ; in other words, the optimal ${f}$ should have an exponential form ${f(t)= e^{\lambda t}}$ . The constraint (7) then becomes

$\displaystyle \frac{e^\lambda - 1}{\lambda} = u$

and so the Lagrange multiplier ${\lambda}$ is precisely the mysterious quantity ${\xi(u)}$ appearing in (2)! The formula (8) can now be evaluated as

$\displaystyle \rho(u) \approx \exp\left( - \int_0^1 \frac{e^{\xi(u) t} \xi(u) t - e^{\xi(u) t}}{t}\ dt \right)$

$\displaystyle \approx \exp\left( - e^{\xi(u)} + 1 + \int_0^1 \frac{e^{\xi(u) t} - 1}{t}\ dt + \int_0^1 \frac{1}{t}\ dt \right)$

$\displaystyle \approx \exp\left( - u \xi(u) + \int_0^{\xi(u)} \frac{e^s - 1}{s}\ ds + C\right)$

where ${C}$ is the divergent constant

$\displaystyle C = \int_0^1 \frac{1}{t}\ dt.$

This recovers a large fraction of (2)! It is not completely accurate for multiple reasons. One is that the hypothesis of joint independence on the events ${p|n}$ is unrealistic when trying to confine ${n}$ to a single scale ${x}$ ; this comes down ultimately to the subtle differences between the Poisson and Poisson-Dirichlet processes, as discussed in this previous blog post, and is also responsible for the otherwise mysterious ${e^\gamma}$ factor in Mertens’ third theorem; it also morally explains the presence of the same ${e^\gamma}$ factor in (2). A related issue is that the law of large numbers (4) is not exact, but admits gaussian fluctuations as per the central limit theorem; morally, this is the main cause of the ${\sqrt{\frac{\xi'(u)}{2\pi}}}$ prefactor in (2).

Nevertheless, this demonstrates that the maximum entropy method can achieve a reasonably good heuristic understanding of smooth numbers. In fact we also gain some insight into the “anatomy of integers” of such numbers: the above analysis suggests that a typical ${y}$ -smooth number ${n}$ will be divisible by a given prime ${p \sim y^t}$ with probability about ${e^{\xi(u) t}/p}$ . Thus, for ${t = 1 - O(1/\log u)}$ , the probability of being divisible by ${p}$ is elevated by a factor of about ${\asymp e^{\xi(u)} \asymp u \log u}$ over the baseline probability ${1/p}$ of an arbitrary (non-smooth) number being divisible by ${p}$ ; so (by Mertens’ theorem) a typical ${y}$ -smooth number is actually largely comprised of something like ${\asymp u}$ prime factors all of size about ${y^{1-O(1/\log u)}}$ , with the smaller primes contributing a lower order factor. This is in marked contrast with the anatomy of a typical (non-smooth) number ${n}$ , which typically has ${O(1)}$ prime factors in each hyperdyadic scale ${[\exp\exp(k), \exp\exp(k+1)]}$ in ${[1,n]}$ , as per Mertens’ theorem.

by Terence Tao at October 22, 2025 04:59 PM

John Baez — The Standard Model (Part 1)

It’s our best theory of elementary particles and forces. It’s absolutely amazing: it took centuries of genius to discover that the world is like this, and it’s absolutely shocking. But nobody believes it’s the last word, so we simply call it The Standard Model.

But what does this theory say? I’ll try to explain part of it in this series of videos. I begin by introducing the cast of characters—the particles—and a bit about their interactions:

If you have questions, please ask—either here or on YouTube! Intelligent questions keep me motivated. Without them, I get bored.

By the way, these videos will contain mistakes. For example, this time I forgot to mention one key particle before saying “So I’ve introduced all the actors in the drama.” When I get better at editing videos, I will correct slips like this. But I will always try to point out errors in a “pinned” comment right below the video. So look down there.

Also: I don’t plan to explain the details of quantum field theory. So even if you watch all my videos, you’ll get just a taste of the Standard Model. But I will get into some of the math, so it will be much more than just chat. It will roughly follow this paper:

• John Baez and John Huerta, The algebra of grand unified theories, Bulletin of the American Mathematical Society 47 (2010), 483–552.

But I may explain more prerequisites, like a bit of quantum theory and group representation theory. That would let more people follow along.

This is part of my Edinburgh Exploration series, which will also include interviews.

by John Baez at October 22, 2025 10:06 AM

October 20, 2025

Scott Aaronson My talk at Columbia University: “Computational Complexity and Explanations in Physics”

Last week, I gave the Patrick Suppes Lecture in the Columbia University Philosophy Department. Patrick Suppes was a distinguished philosopher at Stanford who (among many other things) pioneered remote gifted education through the EPGY program, and who I was privileged to spend some time with back in 2007, when he was in his eighties.

My talk at Columbia was entitled “Computational Complexity and Explanations in Physics.” Here are the PowerPoint slides, and here’s the abstract:

The fact, or conjecture, of certain computational problems being intractable (that is, needing astronomical amounts of time to solve) clearly affects our ability to learn about physics. But could computational intractability also play a direct role in physical explanations themselves? I’ll consider this question by examining three possibilities:

(1) If quantum computers really take exponential time to simulate using classical computers, does that militate toward the many-worlds interpretation of quantum mechanics, as David Deutsch famously proposed?

(2) Are certain speculative physical ideas (e.g., time travel to the past or nonlinearities in quantum mechanics) disfavored, over and above any other reasons to disfavor them, because they would lead to “absurd computational superpowers”?

(3) Do certain effective descriptions in physics work only because of the computational intractability of violating those descriptions — as for example with Harlow and Hayden’s resolution of the “firewall paradox” in black hole thermodynamics, or perhaps even the Second Law of Thermodynamics itself?

I’m grateful to David Albert and Lydia Goehr of Columbia’s Philosophy Department, who invited me and organized the talk, as well as string theorist Brian Greene, who came and contributed to the discussion afterward. I also spent a day in Columbia’s CS department, gave a talk about my recent results on quantum oracles, and saw many new friends and old there, including my and my wife’s amazing former student Henry Yuen. Thanks to everyone.

This was my first visit to Columbia University for more than a decade, and certainly my first since the upheavals following the October 7 massacre. Of course I was eager to see the situation for myself, having written about it on this blog. Basically, if you’re a visitor like me, you now need both a QR code and an ID to get into the campus, which is undeniably annoying. On the other hand, once you’re in, everything is pleasant and beautiful. Just from wandering around, I’d have no idea that this campus had recently been Ground Zero for the pro-intifada protests, and then for the reactions against those protests (indeed, the use of the protests as a pretext to try to destroy academia entirely) that rocked the entire country, filling my world and my social media feed.

When I asked friends and colleagues about the situation, I heard a range of perspectives: some were clearly exasperated with the security measures; others, while sharing in the annoyance, suggested the measures seem to be needed, since every time the university has tried to relax them, the “intifada” has returned, with non-university agitators once again disrupting research and teaching. Of course we can all pray that the current ceasefire will hold, for many reasons, the least of which is that perhaps then the obsession of the world’s young and virtuous to destroy the world’s only Jewish state will cool down a bit, and they’ll find another target for their rage. That would also help life at Columbia and other universities return to how it was before.

Before anyone asks: no, Columbia’s Peter Woit never showed up to disrupt my talk with rotten vegetables or a bullhorn—indeed, I didn’t see him at all on his trip, nor did I seek him out. Given that Peter chose to use his platform, one of the world’s best-known science blogs, to call me a mentally ill genocidal fascist week after week, it meant an enormous amount to me to see how many friends and supporters I have right in his own backyard.

All in all, I had a wonderful time at Columbia, and based on what I saw, I won’t hesitate to come back, nor will I hesitate to recommend Jewish or Israeli or pro-Zionist students to study there.

by Scott at October 20, 2025 01:55 AM

October 18, 2025

Doug Natelson — Interesting preprints: chirality-induced spin selectivity + quantum gravity

This continues to be a very busy time, but I wanted to point out two preprints that caught my eye this week. Their subjects are completely disparate, but they stand out as essentially reviews written in a much more conversational tone than the usual literature.

The first is this preprint about chirality-induced spin selectivity, a subject that I've mentioned before on this blog. There is now an extensive body of evidence (of varying quality) that there is a connection between structural chirality of molecules and their interactions with the spin angular momentum of electrons. This includes monolayers of chiral molecules leading to net spin polarization of photoemitted electrons (here), a lot of electronic transport experiments involving chiral molecules and magnetic electrodes that seem to show spin-dependent transmission that is absent with achiral molecules, and even a chirality dependence of molecular adsorption kinetics on magnetic surfaces (here). The preprint is a provocative discussion of the topic and possible mechanisms, and the importance of precision in the description of the various phenomena.

On a completely different topic, this preprint is a fun discussion about quantum gravity (!) and how condensed matter ideas of "the vacuum" can lead to insights about how quantum mechanics and gravity might need to play together. One fun bit early on is a discussion of something I like to point out to my undergrad stat mech students: A single hydrogen atom in a very very large box will apparently (if the usual stat mech formalism of partition functions is valid) be spontaneously ionized, even when the box and atom are at temperatures faaaaaar below the energy scale for ionization. This is discussed nicely in this 1966 article in the Journal of Chemical Education. Anyway, I thought this was an interesting discussion from three condensed matter theorists.

by Douglas Natelson at October 18, 2025 01:41 PM

October 17, 2025

Matt von Hippel — AGI Is an Economic Term, Not a Computer Science Term

I ran into this Bluesky post, and while a lot of the argument resonated with me, I think the author is missing something important.

Shannon Vallor is a philosopher of technology at the University of Edinburgh. She spoke recently at a meeting honoring the 75th anniversary of the Turing Test. The core of her argument, recapped in the Bluesky post, is that artificial general intelligence, or AGI, represents an outdated scientific concept, like phlogiston. While some researchers in the past thought of humans as having a kind of “general” intelligence that a machine would need to replicate, scientists today break down intelligence into a range of capabilities that can be present in different ways. From that perspective, searching for artificial general intelligence doesn’t make much sense: instead, researchers should focus on the particular capabilities they’re interested in.

I have a lot of sympathy for Vallor’s argument, though perhaps from a different direction than what she had in mind. I don’t know enough about intelligence in a biological context to comment there. But from a computer science perspective, intelligence obviously is composed of distinct capabilities. Something that computes, like a human or a machine, can have different amounts of memory, different processing speeds, different input and output rates. In terms of ability to execute algorithms, it can be a Turing machine, or something less than a Turing machine. In terms of the actual algorithms it runs, they can have different scaling for large inputs, and different overhead for small inputs. In terms of learning, one can have better data, or priors that are closer to the ground truth.

These days, all of these Turing machine algorithm capabilities are in some sense obviously not what the people interested in AGI are after. We already have them in currently-existing computers, after all. Instead, people who pursue AGI, and AI researchers more generally, are interested in heuristics. Humans do certain things without reliable algorithms, instead we do them faster, but unreliably. And while some human heuristics seem pretty general, it’s widely understood that in the heuristics world there is no free lunch. No heuristic is good for everything, and no heuristic is bad for everything.

So is “general intelligence” a mirage, like phlogiston?

If you think about it as a scientific goal, sure. But as a product, not so much.

Consider a word processor.

Obviously, from a scientific perspective, there are lots of capabilities that involve processing words. Some were things machines could do well before the advent of modern computers: consider typewriters, for instance. Others still are out of reach, after all, we do still pay people to write. (I myself am such person!)

But at the same time, if I say that a computer program is a word processor, you have a pretty good idea of what that means. There was a time when processing words involved an enormous amount of labor, work done by a large number of specialized people (mostly women). Look at a workplace documentary from the 1960’s, and compare it to a workplace today, and you’ll see that word processor technology has radically changed what tasks people do.

AGI may not make sense as a scientific goal, but it’s perfectly coherent in these terms.

Right now, a lot of tasks are done by what one could broadly call human intelligence. Some of these tasks have already fallen to technology, others will fall one by one. But it’s not unreasonable to think of a package deal, a technology that covers enough of such tasks that human intelligence stops being economically viable. That’s not because there will be some scientific general intelligence that the technology would then have, but because a decent number of intellectual tasks do seem to come bundled together. And you don’t need to cover 100% of human capabilities to radically change workplaces, any more than you needed to cover 100% of the work of a 1960’s secretary with a word processor for modern secretarial work to have a dramatically different scope and role.

It’s worth keeping in mind what is and isn’t scientifically coherent, to be aware that you can’t just extrapolate the idea of general intelligence to any future machine. (For one, it constrains what “superintelligence” could look like.) But that doesn’t mean we should be complacent, and assume that AGI is impossible in principle. AGI, like a word processor, would be a machine that covers a set of tasks well enough that people use it instead of hiring people to do the work by hand. It’s just a broader set of tasks.

by 4gravitons at October 17, 2025 04:00 PM

October 16, 2025

John Baez — The Kepler Problem (Part 12)

It’s been a while. Let me finally wrap up this this series! I’ll show you how we can get the periodic table of elements from a quantum field theory of massless spin-1/2 particles.

We’ve been studying the hydrogen atom using Schrödinger’s equation, but still taking the electron’s spin into account. This is more realistic than the basic Schrödinger equation that ignores spin, but less realistic than a full-fledged relativistic treatment using the Dirac equation. It’s a pretty good approximation. We saw that bound states of this hydrogen atom can be reinterpreted as states of a massless left-handed spin-1/2 particle in the Einstein universe—a universe where space is the 3-sphere $S^3.$

Then I ‘second quantized’ both theories. If we do this to the massless spin-1/2 particle, we get a free quantum field theory on the Einstein universe! This describes arbitrary collections of noninteracting massless spin-1/2 particles. If we second quantize the hydrogen atom, we get a theory of multi-electron atoms—but a naive theory where the electrons don’t interact. In this naive theory we don’t get the periodic table of elements. But today I want to tweak the Hamiltonian so we do get the observed periodic table, at least roughly.

Let’s do it!

In Part 7 we saw how the Hilbert space of bound states of the hydrogen atom, taking the electron’s spin into account, is

$\mathcal{H} = L^2(S^3) \otimes \mathbb{C}^2$

In atomic physics, the eigenspaces of the Hamiltonian $H$ on $\mathcal{H}$ are called shells, while the joint eigenspaces of the operators $H$ and the angular momentum squared, $L^2,$ are called subshells. We denote the shells as

$\displaystyle{ \mathcal{H}_n = \{ \psi \in \mathcal{H} \; H\psi = -\frac{1}{2n^2} \psi \} }$

and the subshells as

$\mathcal{H}_{n,\ell} = \{ \psi \in \mathcal{H}_n : \; L^2 \psi = \ell(\ell + 1) \psi \}$

The shells are direct sums of subshells as follows:

$\mathcal{H}_n = \bigoplus_{\ell = 0}^{n-1} \mathcal{H}_{n,\ell}$

and the direct sum of all the shells is the whole Hilbert space of bound states of the hydrogen atom:

$\mathcal{H} = \bigoplus_{n = 1}^\infty \mathcal{H}_n$

The dimension of the subshell $\mathcal{H}_{n,\ell}$ is $2(2\ell + 1),$ so the dimension of the shell $\mathcal{H}_n$ is

$2(1 + 3 + 5 + \cdots + (2n - 1)) = 2n^2$

In Part 11 we second quantized the hydrogen atom and got the fermionic Fock space $\mathbf{\Lambda} \mathcal{H}$ which describes collections of electrons bound to the nucleus. This suggests that we could understand the periodic table this way!

The Aufbau principle is a famous approximate way to describe the ground state of an $N$ -electron atom as a state $\phi$ in the $N$ -particle subspace of the Fock space $\mathbf{\Lambda} \mathcal{H}.$ To do this, we choose a Hamiltonian $H_{\text{Fock}}$ on $\mathbf{\Lambda} \mathcal{H}$ and decree that $\phi$ must minimize the expected energy $\langle \phi , H_{\text{Fock}}\, \phi \rangle$ among all unit vectors in the $N$ -particle subspace. However, we choose the Hamiltonian $H_{\text{Fock}}$ in a very simplistic way. We ignore the details of electron-electron interactions! Instead, we simply assign an energy $E_{n,\ell}$ to each subshell, let $H_{\text{single}}$ be the unique Hamiltonian on $\mathcal{H}$ such that

$\psi \in \mathcal{H}_{n,\ell} \implies H_{\text{single}} \psi = E_{n,\ell} \,\psi$

and then we let

$H_{\text{Fock}} = d\mathbf{\Lambda}(H_{\text{single}})$

Thus, $H_{\text{Fock}}$ has a basis of eigenvectors that are wedge products of single-particle states lying in various subshells. Explicitly, if

$\phi = \psi_1 \wedge \cdots \wedge \psi_N$ where $\psi_i \in \mathcal{H}_{n_i, \ell_i}$

then we have

$H_{\text{Fock}} \, \phi = (E_{n_1,\ell_1} + \cdots + E_{n_N, \ell_N}) \phi$

Thus, we can minimize $\langle \phi , H_{\text{Fock}}\, \phi \rangle$ among unit vectors in the $N$ -particle subspace by choosing $N$ distinct basis vectors

$\psi_i = |n_i, \ell_i, m_i, s_i \rangle$

in a way that minimizes the total energy $E_{n_1,\ell_1} + \cdots + E_{n_N, \ell_N}.$

If we follow this recipe taking $H_{\text{single}}$ to be the hydrogen atom Hamiltonian $H,$ we get results that do not closely match the observed periodic table of elements. With this choice we get energies

$\displaystyle{ E_{n,\ell} = -\frac{1}{2n^2} }$

that depend only on the shell, not the subshell. Thus, this choice makes no prediction about the order in which subshells are filled! That’s no good.

For the recipe to give results that more closely match the periodic table, we need to choose the energies $E_{n,\ell}$ in a more clever way. In 1936, Madelung argued for these rules:

• subshells are filled in order of increasing value of $n + \ell$ ;

• for subshells with the same value of $n + \ell,$ subshells are filled in order of decreasing $\ell$ (or equivalently, increasing $n$ ).

In reality this nice pattern is broken by quite a few elements, but here we only consider a simple model in which the Madelung rules hold. The pattern of subshell filling then looks like this:

The above chart uses some old but still popular notation from spectroscopy:

• $\ell = 0$ : $s$
• $\ell = 1$ : $p$
• $\ell = 2$ : $d$
• $\ell = 3$ : $f$

For example, the subshell $\mathcal{H}_{3,2}$ is denoted $3d$ while $\mathcal{H}_{5,3}$ is denoted $5f.$

In 1945, a chemist named Wiswesser noted that the Madelung rules follow from the recipe we outlined if we choose

$E_{n,\ell} = n + \ell - \frac{\ell}{\ell + 1}$

There are many other functions of $n$ and $\ell$ that achieve the same effect. For example, we can also obtain the Madelung rules if we take

$E_{n,\ell} = 2n + (2\ell + 1) + (2\ell + 1)^{-1}$

and this formula is more convenient for us.

The Madelung rules do not always hold! The first exception is element 24, chromium. The Madelung rules predict that chromium has 2 electrons in the $4s$ subshell and 4 electrons in the $3d$ subshell, while in fact it has 1 in the $4s$ and 5 in the $3d.$ There are eleven exceptions to the Madelung rules in the so-called $d$ -block elements (shown in purple in the periodic table below), and nine exceptions in the $f$ -block elements (shown in pink). Nonetheless the general structure of the periodic table is in reasonably good accord with the Madelung rules for all the elements studied chemically so far, though relativistic effects may end this for very heavy elements.

Thus it is of some interest, if only as a curiosity, to define a Hamiltonian on the Hilbert space $\mathcal{H}$ that takes the eigenvalue $E_{n,\ell}$ in the subshell $\mathcal{H}_{n,\ell}.$ These energies are not at all close to the actual energies of the various multi-electron atoms, and any monotone function of $E_{n,\ell}$ would also give the Madelung rules—but this particular Hamiltonian is fairly simple.

Recall from Part 7:

$\begin{array}{cclll} A^2 |n , \ell, m \rangle &=& \frac{1}{4}(n^2 - 1) |n , \ell, m, s \rangle \\ [3pt] L^2 |n , \ell, m \rangle &=& \ell(\ell + 1) |n , \ell, m, s \rangle \end{array}$

The Duflo isomorphism, as discussed in Part 6, makes it natural to define operators

$\tilde{A}^2 = A^2 + \frac{1}{4}, \qquad \tilde{L}^2 = L^2 + \frac{1}{4}$

If we then define $\tilde{A}$ and $\tilde{L}$ to be the square roots of these operators, we have

$\begin{array}{cclcl} \tilde{A} |n , \ell, m \rangle &=& \frac{1}{2} n |n , \ell, m \rangle \\ [3pt] \tilde{L} |n , \ell, m \rangle &=& (\ell + \frac{1}{2}) |n , \ell, m \rangle \end{array}$

and thus

$(2\tilde{A} + 2\tilde{L} + (2\tilde{L})^{-1})|n , \ell, m, s \rangle = E_{n,\ell} |n , \ell, m, s\rangle$

This suggests taking our single-particle Hamiltonian to be

$H_{\text{single}} = 2\tilde{A} + 2\tilde{L} + (2\tilde{L})^{-1}$

If we then define a Hamiltonian on the Fock space $\mathbf{\Lambda} \mathcal{H}$ by

$H_{\text{Fock}} = d\mathbf{\Lambda}(H_{\text{single}})$

and create an orthonormal basis $\psi_i$ of eigenvectors of $H_{\text{Fock}},$ listed in order of increasing eigenvalue, these eigenvectors correspond to the elements with subshells filled as predicted by the Madelung rules. The one exception is the state $\psi_0$ with no electrons, sometimes called ‘element zero’ and identified with the neutron. For example:

$\begin{array}{ccll} \psi_1 &=& |1,0,0,\frac{1}{2} \rangle & \text{hydrogen} \\ \\ \psi_2 &=& |1,0,0,\frac{1}{2} \rangle \wedge |1,0,0,-\frac{1}{2}\rangle & \text{helium} \\ \\ \psi_3 &=& |1,0,0,\frac{1}{2} \rangle \wedge |1,0,0,-\frac{1}{2}\rangle \wedge |2,0,0,\frac{1}{2}\rangle & \text{lithium} \end{array}$

and so on.

Here the assignments of magnetic quantum numbers $m$ and spins $s$ are not determined by the rules we have laid out. These are governed, at least approximately, by Hund’s rules:

• every $m$ state in a subshell is singly occupied before any is doubly occupied;

• all of the electrons in singly occupied orbitals have the same spin.

We could go further and attempt to choose a simple Hamiltonian for which the principle of energy mimization also gives Hund’s rules. However, we prefer to stop here, leaving you with the challenge of finding a better-behaved quantum field theory on the Einstein universe whose Hamiltonian gives the Madelung rules, or perhaps better understanding the Hamiltonian we have given here.

Here is the periodic table we get from our approach:

and here are the energies for subshells

$E_{n,\ell} = 2n + (2\ell + 1) + (2\ell + 1)^{-1}$

that we’re using in our approach:

For more, read my paper:

• Second quantization for the Kepler problem.

or these blog articles, which are more expository and fun:

• Part 1: a quick overview of Kepler’s work on atoms and the solar system, and more modern developments.

• Part 2: why the eccentricity vector is conserved for a particle in an inverse square force, and what it means.

• Part 3: why the momentum of a particle in an inverse square force moves around in a circle.

• Part 4: why the 4d rotation group $\text{SO}(4)$ acts on bound states of a particle in an attractive inverse square force.

• Part 5: quantizing the bound states of a particle in an attractive inverse square force, and getting the Hilbert space $L^2(S^3)$ for bound states of a hydrogen atom, neglecting the electron’s spin.

• Part 6: how the Duflo isomorphism explains quantum corrections to the hydrogen atom Hamiltonian.

• Part 7: why the Hilbert space of bound states for a hydrogen atom including the electron’s spin is $L^2(S^3) \otimes \mathbb{C}^2.$

• Part 8: why $L^2(S^3) \otimes \mathbb{C}^2$ is also the Hilbert space for a massless spin-1/2 particle in the Einstein universe.

• Part 9: a quaternionic description of the hydrogen atom’s bound states (a digression not needed for later parts).

• Part 10: changing the complex structure on $L^2(S^3) \otimes \mathbb{C}^2$ to eliminate negative-energy states of the massless spin-1/2 particle, as often done.

• Part 11: second quantizing the massless spin-1/2 particle and getting a quantum field theory on the Einstein universe, or alternatively a theory of collections of electrons orbiting a nucleus.

• Part 12: obtaining the periodic table of elements from a quantum field theory on the Einstein universe.

by John Baez at October 16, 2025 02:57 PM

October 15, 2025

Clifford Johnson — Nobel Prize in Physics 2025: Who/What/Why

I started a tradition a little while back where every year we have a special departmental colloquium entitled "The Nobel Prize in Physics: Who/What/Why". This year my job in finding speakers was made easier by having 2/3 of this years newly-minted Nobel Prize winners in physics in the Department! (Michel Devoret and John Martinis.) So our room was a bit more well-attended than normal...(hundreds and hundreds rather than dozens and dozens). Here is a recording of the event, which I was delighted to host, and there's a celebration afterwards too. (Pls share widely!)
[...] Click to continue reading this post →

The post Nobel Prize in Physics 2025: Who/What/Why appeared first on Asymptotia.

by Clifford at October 15, 2025 10:25 PM

Jordan Ellenberg — International Conference on Ancient Magic

I have nothing to say about this, I just think it’s cool that Ohio State is hosting an International Conference on Ancient Magic this weekend. Open to the public! Go to this if you’re in Columbus and feeling eldritch!

by JSE at October 15, 2025 08:19 PM

October 14, 2025

Scott Aaronson Sad and happy day

Today, of course, is the second anniversary of the genocidal Oct. 7 invasion of Israel—the deadliest day for Jews since the Holocaust, and the event that launched the current wars that have been reshaping the Middle East for better and/or worse. Regardless of whether their primary concern is for Israelis, Palestinians, or both, I’d hope all readers of this blog could at least join me in wishing this barbaric invasion had never happened, and in condemning the celebrations of it taking place around the world.

Now for the happy part: today is also the day when the Nobel Prize in Physics is announced. I was delighted to wake up to the news that this year, the prize goes to John Clarke of Berkeley, John Martinis of UC Santa Barbara, and Michel Devoret of UC Santa Barbara (formerly Yale), for their experiments in the 1980s that demonstrated the reality of macroscopic quantum tunneling in superconducting circuits. Among other things, this work laid the foundation for the current effort by Google, IBM, and many others to build quantum computers with superconducting qubits. To clarify, though, today’s prize is not for quantum computing per se, but for the earlier work.

While I don’t know John Clarke, and know Michel Devoret only a little, I’ve been proud to count John Martinis as a good friend for the past decade—indeed, his name has often appeared on this blog. When Google hired John in 2014 to build the first programmable quantum computer capable of demonstrating quantum supremacy, it was clear that we’d need to talk about the theory, so we did. Through many email exchanges, calls, and visits to Google’s Santa Barbara Lab, I came to admire John for his iconoclasm, his bluntness, and his determination to make sampling-based quantum supremacy happen. After Google’s success in 2019, I sometimes wondered whether John might eventually be part of a Nobel Prize in Physics for his experimental work in quantum computing. That may have become less likely today, now that he’s won the Nobel Prize in Physics for his work before quantum computing, but I’m guessing he doesn’t mind! Anyway, huge congratulations to all three of the winners.

by Scott at October 14, 2025 06:14 PM

October 12, 2025

Jordan Ellenberg — A favorite tactic of the self-identified iconoclast

A good line by Lauren Oyler, in a Harper’s article about the Goop Cruise:

“A favorite tactic of the self-identified iconoclast is to argue that things that have already happened need, still, to happen.”

I like the placement of “still” and the commas a lot. Is “self-identified” one notch too sneery? Would “would-be” be better? Or even no adjective at all? Maybe the second part of the sentence does enough to establish that the title of iconoclast has not been firmly earned by its claimer.

by JSE at October 12, 2025 04:16 PM

October 11, 2025

John Baez — Crown Ethers

Students who memorize organic chemistry consider it torture. But to explore it is a delight. It’s like the difference between being force-fed and grazing at a buffet.

For example, I recently learned about ‘crown ethers‘: beautiful crown-shaped molecules of carbon, hydrogen and oxygen. Above is a ball-and-stick model of a crown ether called 15-crown-5.

Why is it called that? I guess because it has 5 oxygens (in red) and 10 carbons (in black) for a total of 15 heavier atoms. Then there are a bunch of hydrogens poking out. It has perfect 5-fold symmetry.

Yasui Yoshio won the Nobel Prize in 1987 for discovering crown ethers around 1967. He’s usually known as Charles J. Pedersen. He was born in Korea but later moved to Japan and then the US.

One use of crown ethers is to hold metal ions. A sodium atom with one electron missing can snugly fit inside 15-crown-5. So can a transition metal with two electrons missing, like cobalt (Co²⁺), nickel (Ni²⁺), copper (Cu²⁺), or zinc (Zn²⁺).

Other metal ions fit better in larger crown ethers. For example, here is 18-crown-6 holding a potassium ion. Beautiful 6-fold symmetry!

The 6 bonds here come from 6 oxygens connecting to the central potassium atom in purple. I don’t know, but I bet each oxygen donates 1/6 of an electron to the potassium atom, which is missing one.

1/6 of an electron?!?

You can’t actually chop an electron into parts, but you can have a single electron whose wavefunction is smeared out around all 6 oxygen atoms and the central potassium.

So, this ball-and-stick model is pretty misleading! The molecule doesn’t really have sticks in it. Let me show you another picture of it:

This more chubby depiction is called a space-filling model. This makes it clear how the potassium fits snugly inside the crown.

Another thing you can put in 18-crown-6 is hydronium, H₃O⁺:

Hydronium is the ion formed by a water molecule and an extra proton. We see here that its 3-fold symmetry fits nicely into the 6-fold symmetry of 18-crown-6.

But when 18-crown-6 does not have an ion inside it, it folds into a shape that lacks 6-fold symmetry:

Here are some more crown ethers:

They are:

1) 12-crown-4,
2) 15-crown-5,
3) 18-crown-6,
4) dibenzo-18-crown-6,
6) an aza-crown ether, meaning one that contains nitrogen.

For a final burst of fun, here’s an aza-crown ether holding a nickel atom in the center, and two chlorines (in green):

It’s called transNi(cyclam)Cl₂.

The diversity of highly symmetrical structures in chemistry is truly wondrous! And needless to say, I didn’t draw any of the pictures here. I got them from Wikicommons, and you can find out where by clicking on them. Most are in the public domain, thanks to the generosity of their creators.

by John Baez at October 11, 2025 01:03 PM

Doug Natelson — ACS National Nanotechnology Day webinar, Thursday Oct 9

Time for a rare bit of explicit self-promotion on this blog. This coming Thursday, October 9, as part of the American Chemical Society's activities for National Nanotechnology Day (Why October 9? In US convention, Oct 9 = 10/9, and 10^-9m = 1 nm. Look, it wasn't my idea....), I'm speaking in a free webinar titled "Illuminating the Nano Frontier", with Prof. Dongling Ma of INRS in Quebec. The event is 11am-12:30pm EDT, and there will also be a recording for people who are unable to watch it live. Should be a fun event.

Update: Here is the link to the webinar recording. It's free and open-access.

by Douglas Natelson at October 11, 2025 02:40 AM

October 10, 2025

Matt von Hippel — Congratulations to John Clarke, Michel Devoret, and John Martinis!

The 2025 Physics Nobel Prize was announced this week, awarded to John Clarke, Michel Devoret, and John Martinis for building an electrical circuit that exhibited quantum effects like tunneling and energy quantization on a macroscopic scale.

Press coverage of this prize tends to focus on two aspects: the idea that these three “scaled up” quantum effects to medium-sized objects (the technical account quotes a description that calls it “big enough to get one’s grubby fingers on”), and that the work paved the way for some of the fundamental technologies people are exploring for quantum computing.

That’s a fine enough story, but it leaves out what made these folks’ work unique, why it differs from other Nobel laureates working with other quantum systems. It’s a bit more technical of a story, but I don’t think it’s that technical. I’ll try to tell it here.

To start, have you heard of Bose-Einstein Condensates?

Bose-Einstein Condensates are macroscopic quantum states that have already won Nobel prizes. First theorized based on ideas developed by Einstein and Bose (the namesake of bosons), they involve a large number of particles moving together, each in the same state. While the first gas that obeyed Einstein’s equations for a Bose-Einstein Condensate was created in the 1990’s, after Clarke, Devoret, and Martinis’s work, other things based on essentially the same principles were created much earlier. A laser works on the same principles as a Bose-Einstein condensate, as do phenomena like superconductivity and superfluidity.

This means that lasers, superfluids, and superconductors had been showing off quantum mechanics on grubby finger scales well before Clarke, Devoret, and Martinis’s work. But the science rewarded by this year’s Nobel turns out to be something quite different.

Because the different photons in laser light are independently in identical quantum states, lasers are surprisingly robust. You can disrupt the state of one photon, and it won’t interfere with the other states. You’ll have weakened the laser’s consistency a little bit, but the disruption won’t spread much, if at all.

That’s very different from the way quantum systems usually work. Schrodinger’s cat is the classic example. You have a box with a radioactive atom, and if that atom decays, it releases poison, killing the cat. You don’t know if the atom has decayed or not, and you don’t know if the cat is alive or not. We say the atom’s state is a superposition of decayed and not decayed, and the cat’s state is a superposition of alive and dead.

But unlike photons in a laser, the atom and the cat in Schrodinger’s cat are not independent: if the atom has decayed, the cat is dead, if the atom has not, the cat is alive. We say the states of atom and cat are entangled.

That makes these so-called “Schrodinger’s cat” states much more delicate. The state of the cat depends on the state of the atom, and those dependencies quickly “leak” to the outside world. If you haven’t sealed the box well, the smell of the room is now also entangled with the cat…which, if you have a sense of smell, means that you are entangled with the cat. That’s the same as saying that you have measured the cat, so you can’t treat it as quantum any more.

What Clarke, Devoret, and Martinis did was to build a circuit that could exhibit, not a state like a laser, but a “cat state”: delicately entangled, at risk of total collapse if measured.

That’s why they deserved a Nobel, even in a world where there are many other Nobels for different types of quantum states. Lasers, superconductors, even Bose-Einstein condensates were in a sense “easy mode”, robust quantum states that didn’t need all that much protection. This year’s physics laureates, in contrast, showed it was possible to make circuits that could make use of quantum mechanics’ most delicate properties.

That’s also why their circuits, in particular, are being heralded as a predecessor for modern attempts at quantum computers. Quantum computers do tricks with entanglement, they need “cat states”, not Bose-Einstein Condensates. And Clarke, Devoret, and Martinis’s work in the 1980’s was the first clear proof that this was a feasible thing to do.

by 4gravitons at October 10, 2025 04:00 PM

October 09, 2025

Doug Natelson — Postdoctoral opportunity in materials

The Rice Advanced Materials Research Institute is having its 2025-2026 competition for prestigious postdoctoral fellowships - see here: https://rami.rice.edu/rami-postdoctoral-fellowship-program .

If you are interested and meet the criteria, I'd be happy to talk. I have some ideas that lean into the materials for electronics direction, and other possibilities are welcome.

by Douglas Natelson at October 09, 2025 01:27 PM

Jordan Ellenberg — MacArthur Fellows: Wisconsin and Williams

The 2025 MacArthur Fellows have been announced, and I’m very pleased that two of the 22 awardees are my UW-Madision colleagues: congratulations to Ángel F. Adames Corraliza from atmospheric and oceanic sciences, and Sébastien Phillippe from nuclear engineering and engineering physics. The only mathematician to win the award this year was Lauren Williams, who true devotees of this blog will remember as the person who gave the best talk I’ve ever seen about cluster algebras. Congratulations to all the winners!

by JSE at October 09, 2025 02:04 AM

October 08, 2025

Doug Natelson — 2025 Physics Nobel: Macroscopic quantum tunneling

As announced this morning, the 2025 Nobel Prize in Physics has been awarded to John Clarke, Michel Devoret, and John Martinis, for a series of ground-breaking experiments in the 1980s that demonstrated macroscopic quantum tunneling.

For non-experts: "Tunneling" was originally coined to describe the physical motion of a quantum object, which can pass through a "classically forbidden" region. I've written about this here, and here is an evocative picture. Suppose there is a particle with a certain amount of total energy in the left region. Classically, the particle is trapped, because going too far to the left (gray region) or too far to the right (gray region) is forbidden: Putting the particle inside the shaded regions is "classically forbidden" by conservation of energy. The particle bounces back and forth in the left well. If the particle is a quantum object, though, it is described by a wave function, and that wave function has some non-zero amplitude on the far side of barrier in the middle. The particle can "tunnel" through the barrier, with a probability that decreases exponentially with the height of the barrier and its width.

Fig. 2 from here

Clarke, Devoret, and Martinis were working not with a single particle, but with electrons in a superconductor (many many electrons in a coherent quantum state). The particular system they chose was a Josephson junction made from an oxide-coated Nb film contacted by a PbIn electrode with a dc current flowing through it. Instead of an x coordinate of a particle, the relevant coordinate in this system is the phase difference $\delta$ of the superconducting wave function across the junction. There is an effective potential energy for this system called a "washboard" potential, $U(\delta)$, as in this figure. At the particular DC current, which tilts $U(\delta)$, the system can transition from one state ($\delta$ bopping around a constant value, no voltage across the junction) to a state where $\delta$ is continuously ramping (corresponding to a nonzero voltage across the junction). The system can get thermally kicked from the zero voltage state to the nonzero voltage state (thermal energy doinks it over the barrier), but the really interesting thing is that the system can quantum mechanically tunnel "through" the barrier as well.

This idea, that a macroscopic (in the sense of comprising many many electrons) system could tunnel out of a metastable state like this, had been investigated by Amir Caldeira and Tony Leggett in this important paper, where they worried about the role of dissipation in the environment. People tried hard to demonstrate this, but issues with thermal radiation and other noise in the experiments were extremely challenging. With great care in experimental setup, the three laureates put together a remarkable series of papers (here, here, here) that showed all the hallmarks, including resonantly enhancing tunneling with tuned microwaves (designed to kick the system between the levels shown in panel (d) of the figure above).

This was an impressive demonstration of controllable, macroscopic quantum tunneling, and it also laid the foundation for the devices now used by the whole superconducting quantum computing community.

by Douglas Natelson at October 08, 2025 05:31 PM

Tommaso Dorigo — Interna

With this post I would like to present a short update of my personal life to the few readers who are interested in that topic. You know, when I started writing online (over 20 years ago!), blogs used to contain a much more personal, sometimes introspective, description of the owner's private life and actions. Since long, they have been substituted by much more agile, quick-to-consume videos. But the old-fashioned bloggers who stuck with that medium continue to have a life - albeit certainly a less glamorous one than that of today's influencers; so some reporting of personal affairs is not out of place here.

by Tommaso Dorigo at October 08, 2025 11:56 AM

October 07, 2025

n-Category Café A Complex Qutrit Inside an Octonionic One

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

Dubois-Violette and Todorov noticed that the Standard Model gauge group is the intersection of two maximal subgroups of $\mathrm{F}_4$ . I’m trying to understand these subgroups better.

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

Very roughly speaking, $\mathrm{F}_4$ is the symmetry group of an octonionic qutrit. Of the two subgroups I’m talking about, one preserves a chosen octonionic qubit, while the other preserves a chosen complex qutrit.

A precise statement is here:

Can we understand the Standard model using octonions?

Over on Mathstodon I’m working with Paul Schwahn to improve this statement. He made a lot of progress on characterizing the first subgroup. $\mathrm{F}_4$ is really the group of automorphisms of the Jordan algebra of $3 \times 3$ self-adjoint octonion matrices, $\mathfrak{h}_3(\mathbb{O})$ . He showed the first subgroup, the one I said “preserves a chosen octonionic qubit”, is really the subgroup that preserves any chosen Jordan subalgebra isomorphic to $\mathfrak{h}_2(\mathbb{O})$ .

Now we want to show the second subgroup, the one I said “preserves a chosen complex qutrit”, is really the subgroup that preserves any chosen Jordan subalgebra isomorphic to $\mathfrak{h}_3(\mathbb{C})$ .

I want to sketch out a proof strategy. So, I’ll often say “I hope” for a step that needs to be filled in.

Choose an inclusion of algebras $\mathbb{C} \hookrightarrow \mathbb{O}$ . All such choices are related by an automorphism of the octonions, so it won’t matter which one we choose.

There is then an obvious copy of $\mathfrak{h}_3(\mathbb{C})$ sitting inside $\mathfrak{h}_3(\mathbb{O})$ . I’ll call this the standard copy. To prove the desired result, it’s enough to show:

The subgroup of $\mathrm{F}_4$ preserving the standard copy of $\mathfrak{h}_3(\mathbb{C})$ in $\mathfrak{h}_3(\mathbb{O})$ is a maximal subgroup of $\mathrm{F}_4$ , namely $(\text{SU}(3) \times \text{SU}(3))/\mathbb{Z}_3$ .
All Jordan subalgebras of $\mathfrak{h}_3(\mathbb{O})$ isomorphic to $\mathfrak{h}_3(\mathbb{C})$ are related to the standard copy by an $\mathrm{F}_4$ transformation.

Part 1. should be the easier one to show, but I don’t even know if this one is true! $(\text{SU}(3) \times \text{SU}(3))/\mathbb{Z}_3$ is a maximal subgroup of $\mathrm{F}_4$ , and Yokota shows it preserves the standard copy of $\mathfrak{h}_3(\mathbb{C})$ in $\mathfrak{h}_3(\mathbb{O})$ . But he shows it also preserves more, seemingly: it preserves a complex structure on the orthogonal complement of that standard copy. Is this really ‘more’ or does it hold automatically for any element of $\mathrm{F}_4$ that preserves the standard copy of $\mathfrak{h}_3(\mathbb{C})$ ? I don’t know.

But I want to focus on part 2). Here’s what we’re trying to show: any Jordan subalgebra of $\mathfrak{h}_3(\mathbb{O})$ isomorphic to $\mathfrak{h}_3(\mathbb{C})$ can be obtained from the standard copy of $\mathfrak{h}_3(\mathbb{C})$ by applying some element of $\mathrm{F}_4$ .

So, pick a Jordan subalgebra A of $\mathfrak{h}_3(\mathbb{O})$ isomorphic to $\mathfrak{h}_3(\mathbb{C})$ . Pick an isomorphism A ≅ $\mathfrak{h}_3(\mathbb{C})$ .

Consider the idempotents

$\begin{array}{ccl} e_1 &=& diag(1,0,0) \\ e_2 &=& diag(0,1,0) \\ e_3 &=& diag(0,0,1) \end{array}$

in $\mathfrak{h}_3(\mathbb{C})$ . Using our isomorphism $A \cong \mathfrak{h}_3(\mathbb{C})$ they give idempotents in $A$ , which I’ll call $f_1, f_2, f_3$ . Since $A \subset \mathfrak{h}_3(\mathbb{O})$ these are also idempotents in $\mathfrak{h}_3(\mathbb{O})$ .

Hope 1: I hope there is an element $g$ of $\mathrm{F}_4$ mapping $f_1, f_2, f_3 \mathfrak{h}_3(\mathbb{O})$ to $e_1, e_2, e_3 \in \mathfrak{h}_3(\mathbb{C})$ ⊂ $\mathfrak{h}_3(\mathbb{O})$ .

Hope 2: Then I hope there is an element $h$ of $\mathrm{F}_4$ that fixes $e_1, e_2, e_3$ and maps the subalgebra $g A$ to the standard copy of $\mathfrak{h}_3(\mathbb{C})$ in $\mathfrak{h}_3(\mathbb{O})$ .

If so, we’re done: $h g$ maps $A$ to the standard copy of $\mathfrak{h}_3(\mathbb{C})$ .

Hope 1 seems to be known. The idempotents $e_1, e_2, e_3$ form a so-called ‘Jordan frame’ for $\mathfrak{h}_3(\mathbb{O})$ , and so do $f_1, f_2, f_3$ . Faraut and Korányi say that “in the irreducible case, the group $K$ acts transitively on the set of all Jordan frames”, and I think that implies Hope 1.

As for Hope 2, I know the subgroup of $\mathrm{F}_4$ that fixes $e_1, e_2, e_3$ contains $\text{Spin}(8)$ . I bet it’s exactly $\text{Spin}(8)$ . But to prove Hope 2 it may be enough to use $\text{Spin}(8)$ .

Let me say a bit more about how we might realize Hope 2. It suffices to consider a Jordan subalgebra $B$ of $\mathfrak{h}_3(\mathbb{O})$ that is isomorphic to $\mathfrak{h}_3(\mathbb{C})$ and contains

$\begin{array}{ccl} e_1 &=& diag(1,0,0) \\ e_2 &=& diag(0,1,0) \\ e_3 &=& diag(0,0,1) \end{array}$

and prove that there is an element $h$ of $\mathrm{F}_4$ that fixes $e_1, e_2, e_3$ and maps the subalgebra $B$ to the standard copy of $\mathfrak{h}_3(\mathbb{C})$ in $\mathfrak{h}_3(\mathbb{O})$ . (In case you’re wondering, this $B$ is what I was calling $g A$ .)

Hope 3: I hope that we can show $B$ consists of matrices

$\left( \begin{array}{ccc} a_1 & z^\ast & y^\ast \\ z & a_2 & x \\ y & x^\ast & a_3 \end{array} \right)$

where $a_1, a_2, a_3$ are arbitrary real numbers and $x, y, z$ range over 2-dimensional subspaces $V_1, V_2, V_3$ of $\mathbb{O}$ . This would already make it look fairly similar to the standard copy of $\mathfrak{h}_3(\mathbb{C})$ , where the subspaces $V_1, V_2, V_3$ are all our chosen copy of $\mathbb{C}$ in $\mathbb{O}$ .

If Hope 3 is true, the subspaces $V_1, V_2, V_3$ don’t need to be the same, but I believe they do need to obey $V_1 V_2 \subseteq V_3$ and cyclic permutations thereof, simply because $B$ is closed under the Jordan product.

So, we naturally want to know if such a triple of 2d subspaces of $\mathbb{O}$ must be related to the ‘standard’ one (where they are all $\mathbb{C}$ ) by an element of $\text{Spin}(8)$ , where $\text{Spin}(8)$ acts on the three copies of $\mathbb{O}$ by the vector, left-handed spinor, and right-handed spinor representations, respectively — since this is how $\text{Spin}(8)$ naturally acts on $\mathfrak{h}_3(\mathbb{O})$ while fixing all the diagonal matrices.

This is a nice algebra question for those who have thought about triality, and more general ‘trialities’.

So, that’s where I am now: a bunch of hopes which might add up to a clarification of what I mean by “the subgroup of symmetries of an octonionic qutrit that preserve a complex qutrit”.

October 05, 2025

Jordan Ellenberg — This condition of ill-training

This condition of ill-training is intensified considerably in an institution like the state university, because of the large number of technical students in attendance, many of whom are more interested in acquiring information than getting a real education, and who look upon time as wasted unless it is put in in the acquiring of cold facts which may later be put to use in the earning of money.

That’s Thomas Arkle Clark, Dean of Men at UIUC, writing in 1921 in his book Discipline and the Derelict. He also writes that 70% of students in his anonymous survey admitted to cheating (“cribbing,” as it was then called.) He is pretty high on the student-athlete, who he says subscribes to ideals that were less-well known in his own time as an Illinois undergrad, back in the ’80s:

The athlete was not always so worthy of emulation as he is at present. I do not have to go back farther than my own college days nor even so far as that to recall instances of men who found their way into colleges for the sole purpose of developing or exhibiting their physical powers, of making an athletic team, and without any intention of adding to their intellectual strength.

by JSE at October 05, 2025 08:38 PM

John Baez — The Kepler Problem (Part 7)

In Part 5 I explained a cool way to treat bound states of the hydrogen atom as wavefunctions on a sphere in 4-dimensional space. But so far I’ve been neglecting the electron’s spin. Now let’s throw that in too!

This will wind up leading us in some surprising directions. So far I’ve just been reviewing known ideas, but now we’re getting into my new paper:

• Second quantization for the Kepler problem.

It starts out being quite routine: to include spin, we just tensor our previous Hilbert space $L^2(S^3)$ with a copy of $\mathbb{C}^2$ describing the electron’s spin. The resulting space

$L^2(S^3) \otimes \mathbb{C}^2$

is the Hilbert space of bound states of a spinor-valued version of the Schrödinger equation for the hydrogen atom.

Beware: this is a simplification of a more careful treatment of hydrogen using the Dirac equation: it neglects all spin-dependent terms in Hamiltonian, like spin-orbit interactions. These spin-dependent terms give corrections that go to zero in the limit where the speed of light approaches infinity. So what we’re doing now is giving a nonrelativistic treatment of the hydrogen atom, but taking into account the fact that the electron is a spin-½ particle.

Things get fun now. The Hilbert space $L^2(S^3) \otimes \mathbb{C}^2$ becomes a unitary representation of $\text{SU}(2)$ in three important ways. The first two come from the actions of $\text{SU}(2)$ on $L^2(S^3)$ by left and right translation, which I explained in Part 5. The third comes from the natural action of $\text{SU}(2)$ on $\mathbb{C}^2.$ All three of these actions of $\text{SU}(2)$ on $L^2(S^3) \otimes \mathbb{C}^2$ commute with each other. We thus get a unitary representation of $\text{SU}(2) \times \text{SU}(2) \times \text{SU}(2)$ on $L^2(S^3) \otimes \mathbb{C}^2.$

It is useful to spell this out at the Lie algebra level. In Part 5, I introduced self-adjoint operators $A_j$ and $B_j$ on $L^2(S^3)$ : the self-adjoint generators of the left and right translation actions of $\text{SU}(2),$ respectively. Now we’ll tensor these operators with the identity on $\mathbb{C}^2$ and get operators on $L^2(S^3) \otimes \mathbb{C}^2,$ which by abuse of notation we’ll denote with the same names: $A_j$ and $B_j.$ But we’ll also introduce spin angular momentum operators

$S_j = 1 \otimes \frac{1}{2} \sigma_j$

on $L^2(S^3) \otimes \mathbb{C}^2.$ These operators obey the following commutation relations:

$\begin{array}{cclcccl} [A_j, A_k] &=& i\epsilon_{jk\ell} A_\ell &\quad & [A_j, B_k] &=& 0 \\ [2pt] [B_j, B_k] &=& i\epsilon_{jk\ell} B_\ell && [A_j, S_k] &=& 0 \\ [2pt] [S_j, S_k] &=& i\epsilon_{jk\ell} S_\ell && [B_j, S_k] &=& 0 \end{array}$

Once we have 3 commuting actions of $\text{SU}(2)$ on a Hilbert space we can get more by mixing and matching them. I won’t go overboard and describe all 2³ = 8 of them, but I’ll mention some that we need for physics. First we can define orbital angular momentum operators

$L_j = A_j + B_j$

These obey

$\begin{array}{ccl} [L_j, L_k] &=& i\epsilon_{jk\ell} L_\ell \\ [2pt] [S_j, S_k] &=& i \epsilon_{jk\ell} S_\ell \\ [2pt] [L_j, S_k] &=& 0 \end{array}$

Physically speaking, the $L_j$ generate an action of $\text{SU}(2)$ that rotates the position of the electron in space while not changing its spin state, just as the $S_j$ rotate the electron’s spin state while not changing its position.

Adding the spin and orbital angular momentum, we get total angular momentum operators

$J_j = L_j + S_j$

which obey

$[J_j, J_k] = i \epsilon_{jk\ell} J_\ell$

These generate an action of $\text{SU}(2)$ that rotates the electron’s wavefunction along with its spin state!

Finally, we define a Hamiltonian for our new hydrogen atom with spin:

$\displaystyle{ H \; = \; - \frac{1}{8(A^2 + \frac{1}{4})} \; = \; - \frac{1}{8(B^2 + \frac{1}{4})} }$

This is just the Hamiltonian $H_0$ for the simplified hydrogen atom neglecting spin that we studied in Part 5, tensored with the identity operator on $\mathbb{C}^2.$ Thus it has the same spectrum, but the multiplicity of each eigenvalue has doubled. This Hamiltonian $H$ commutes with all the operators $A_j, B_j, S_j,$ and thus also $L_j$ and $J_j.$

Now we can reuse our work from Part 5 and decompose our new Hilbert space into eigenspaces of the Hamiltonian $H,$ labeled by $n = 1, 2, 3, \dots$ , and the orbital angular momentum operator $J^2,$ labeled by $\ell = 0 , \dots, n-1.$ We get this:

$\displaystyle{ L^2(S^3) \otimes \mathbb{C}^2 \cong \bigoplus_{n = 1}^\infty \bigoplus_{\ell = 0}^{n-1} V_\ell \otimes \mathbb{C}^2 }$

where $V_\ell$ is the spin- $\ell$ representation of the $\text{SU}(2)$ that rotates the electron’s position but not its spin.

In Part 5 we saw a basis $|n, \ell, m \rangle$ of $L^2(S^3).$ If we tensor that with the standard basis of $\mathbb{C}^2,$ we get an orthonormal basis $|n , \ell, m, s \rangle$ of $L^2(S^3) \otimes \mathbb{C}^2$ where:

• the principal quantum number $n$ ranges over positive integers;

• the azimuthal quantum number $\ell$ ranges from $0$ to $n-1$ in integer steps;

• the magnetic quantum number $m$ ranges from $-\ell$ to $\ell$ in integer steps;

• the spin quantum number $s$ is $+\frac{1}{2}$ or $-\frac{1}{2}.$

The calculations we did in Part 5 now imply that

$\begin{array}{ccl} A^2 |n, \ell, m, s \rangle &=& B^2 |n, \ell, m, s \rangle \; = \; \frac{1}{4}( n^2 - 1) |n, \ell, m, s\rangle \\ [8pt] H |n, \ell, m, s \rangle &=& \displaystyle{ - \frac{1}{2n^2}\, |n, \ell, m, s \rangle } \\ [12pt] L^2 |n, \ell, m, s\rangle &=& \ell(\ell + 1) |n , \ell, m, s \rangle \\ [3pt] L_3 |n , \ell, m, s \rangle &=& m |n , \ell, m, s \rangle \\ [3pt] S^2 |n , \ell, m, s \rangle &=& \frac{3}{4} |n , \ell, m, s \rangle \\ [3pt] S_3 |n , \ell, m, s \rangle &=& s |n , \ell, m, s \rangle \end{array}$

Combining this with the textbook treatment of the hydrogen atom, it follows that $L^2(S^3) \otimes \mathbb{C}^2$ is indeed unitarily equivalent to the subspace of $L^2(\mathbb{R}^3) \otimes \mathbb{C}^2$ consisting of bound states of the spinor-valued Schrödinger equation

$i \frac{\partial \psi}{\partial t} = -\frac{1}{2} \nabla^2 \psi - \frac{1}{r} \psi$

with the operators $H, L_j$ and $S_j$ having their usual definitions:

$\begin{array}{ccl} H &=& -\frac{1}{2} \nabla^2 - \frac{1}{r} \\ [12pt] L_j &=& -i\epsilon_{jk\ell} x_k \frac{\partial}{\partial x_\ell} \\ [10pt] S_j &=& \frac{1}{2} \sigma_j \end{array}$

In short, the Hamiltonian $H$ on $L^2(S^3) \otimes \mathbb{C}^2$ is unitarily equivalent to the Hamiltonian on bound states of the hydrogen atom defined in the usual way! We’ve turned hydrogen into a festival of commuting $\text{SU}(2)$ actions.

Next we’ll do something a bit wild, and new.