Planet Musings

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

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

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

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.

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 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 07, 2025 05:29 PM

n-Category Café A Complex Qutrit Inside an Octonionic One

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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.

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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”.

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.

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 05, 2025 10:38 AM

John Baez — The Kepler Problem (Part 8)

Now comes the really new stuff. I want to explain how the hydrogen atom is in a certain sense equivalent to a massless spin-½ particle in the ‘Einstein universe’. This is the universe Einstein believed in before Hubble said the universe was expanding! It has a 3-sphere $S^3$ for space, and this sphere stays the same size as time passes.

Today I’ll just lay the groundwork. To study relativistic spin-½ quantum particles, we need to understand the Dirac operator. So, we need to bring out the geometrical content of what we’ve already done.

The main trick is to see the 3-sphere as the group $\text{SU}(2)$ , which acts on itself in two ways, via left and right translations. We get all the rotational symmetries of the 3-sphere this way. In Part 4 we studied operators called $A_i$ and $B_i$ on $L^2(S^3),$ which are the self-adjoint generators of these left and right translations. We saw that

$A^2 = B^2$

Today we’ll see that $A^2 = B^2$ is proportional to the Laplacian on the unit 3-sphere!

But then I want to look at spinor fields on the 3-sphere. We can think of elements of $L^2(S^3) \otimes \mathbb{C}^2$ as spinor fields on the 3-sphere if we trivialize the spinor bundle using the action of $\text{SU}(2)$ as right translations on $S^3 \cong \text{SU}(2).$ You could use left translations, but you have to pick one or the other, and we’ll use right translations.

In some notes from a course he gave at Harvard, Peter Kronheimer used this trick to study the Dirac operator $\partial\!\!\!/$ on these spinor fields:

• Peter Kronheimer, Bott periodicity and harmonic theory on the 3-sphere.

I’ll explain the geometry behind his computations using some ideas I got from Paul Schwahn. Then I’ll show that the hydrogen atom Hamiltonian, thought of as an operator on $L^2(S^3) \otimes \mathbb{C}^2,$ is

$\displaystyle{ H = - \frac{1}{2 (\partial\!\!\!/ - \frac{1}{2})^2} }$

Next time we’ll use this to relate hydrogen to the massless relativistic spin-½ particle on the Einstein universe.

Okay, on to business!

The Laplacian on the 3-sphere

Let’s start with the Laplacian on the 3-sphere. From what we’ve already seen, the operators $-iB_j$ are a basis of left-invariant vector fields on $S^3.$ Each vector field $-iB_j$ gives a tangent vector at the identity of $\text{SU}(2),$ namely

$-\frac{i}{2} \sigma_j \in \mathfrak{su}(2)$

What is the length of this vector if we give $\text{SU}(2)$ the usual Riemannian metric on the unit 3-sphere? Exponentiating this vector we get

$\exp(-\frac{i}{2} \sigma_j t)$

which is the identity precisely when $t$ is an integer times $4\pi.$ Since a great circle on the unit sphere has circumference $2\pi,$ this vector must have length ½. It follows that the vector fields

$X_j = -2i B_j$

have unit length everywhere, and one can check that they form an orthonormal basis of vector fields on $S^3.$ We thus define the (positive definite) Laplacian on $S^3$ to be the differential operator

$\displaystyle{ \Delta = - \sum_{i = 1}^3 X_j^2 = 4B^2 }$

In Part 5 we saw that

$\displaystyle{ L^2(S^3) \cong \bigoplus_j V_j \otimes V_j }$

where $V_j$ is the spin-j representation of $\text{SU}(2).$ We also saw that

$\phi \in V_j \otimes V_j \implies B^2 \phi = j(j+1) \phi$

It follows that

$\phi \in V_j \otimes V_j \implies \Delta \phi = 4j(j+1) \phi$

But chemists like to work with $n = 2j+1$ instead: they call this the ‘principal quantum number’ for a state of hydrogen atom. Since

$4j(j+1) = 4j^2 + 4j = n^2 - 1$

it follows that

$\phi \in V_j \otimes V_j \implies \Delta \phi = (n^2 - 1) \phi$

so the eigenvalues of the Laplacian on the unit 3-sphere are $n^2 - 1$ where $n$ ranges over all positive integers.

Tensoring $\Delta$ with the identity we obtain a differential operator on $L^2(S^3) \otimes \mathbb{C}^2,$ which by abuse of notation we again call $\Delta.$ We know from Part 7 that the hydrogen atom Hamiltonian is

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

but now we know $B^2 = \Delta,$ so

$\displaystyle{ H = - \frac{1}{2(\Delta + 1)} }$

The Dirac operator on the 3-sphere

Next we turn to the Dirac operator.

Up to isomorphism there is only one choice of spin structure on $S^3,$ namely the trivial bundle. To get this can trivialize the tangent bundle of $S^3 \cong \text{SU}(2)$ using left translations. This lets us identify the oriented orthonormal frame bundle of $S^3$ with the trivial bundle

$S^3 \times \text{SO}(3) \to S^3$

This gives a way to identify the spin bundle on $S^3$ with the trivial bundle

$S^3 \times \text{SU}(2) \to S^3$

This in turn lets us identify spinor fields on $S^3$ with $\mathbb{C}^2$ -valued functions.

There are at least two important connections on the tangent bundle of $S^3:$

• One is the Cartan connection: a vector field is covariantly constant with respect to this connection if and only if it is invariant under left translations on $S^3 \cong \text{SU}(2).$

• The other is the Levi–Civita connection: the unique torsion-free connection for which parallel translation preserves the metric.

Parallel translation with respect to the Cartan connection also preserves the metric, but the Cartan connection is flat and has torsion, while the Levi–Civita connection is curved and torsion-free.

Each of these connections lifts uniquely to a connection on the spin bundle which then gives a Dirac-like operator. The Cartan connection gives covariant derivative operators $\nabla^c_j$ on $L^2(S^3) \otimes \mathbb{C}^2$ with

$\nabla^c_j = X_j \otimes 1$

while the Levi–Civita connection gives covariant derivative operators $\nabla_j$ with

$\nabla_j = X_j \otimes 1 + \tfrac{i}{2}(1 \otimes \sigma_j)$

We can define a Dirac operator $\partial\!\!\!/$ on $L^2(S^3) \otimes \mathbb{C}^2$ using the Levi–Civita connection:

$\partial\!\!\!/ = -i (1 \otimes \sigma_j) \nabla_j$

Here I’m summing over repeated indices, and I’m not worrying about superscripts versus subcripts because we can raise and lower indices to our heart’s content using the standard metric on the unit 3-sphere.

I should warn you that this Dirac operator has an $i$ in it, to make it self-adjoint! This may be nonstandard, but it will make our life easier.

On the other hand, Kronheimer defined a Dirac-like operator $D$ using the Cartan connection:

$D = -i (1 \otimes \sigma_j) \nabla^c_j$

An easy calculation shows how $\partial\!\!\!/$ and $D$ are related:

$\begin{array}{ccl} \partial\!\!\!/ &=& -i (1 \otimes \sigma_j) \nabla_j \\ [3pt] &=& -i (1 \otimes \sigma_j) \left( \nabla^c_j + \frac{i}{2}(1 \otimes \sigma_j)\right) \\ [3pt] &=& D + \frac{3}{2} \end{array}$

where we use $\sigma_j^2 = 1$ and the 3-dimensionality of space.

Let us compute $D^2.$ Using the identities

$\sigma_j \sigma_k = \delta_{jk} + i \epsilon_{jk\ell} \sigma_\ell$

$\epsilon_{jk\ell} X_j X_k = 2 X_\ell$

$D = -i X_j \otimes \sigma_j$

we obtain

$\begin{array}{ccl} D^2 &=& -X_j X_k \otimes \sigma_j \sigma_k \\ [2pt] &=& -X_j X_k \otimes (\delta_{jk} + i \epsilon_{jk\ell} \sigma_\ell ) \\ [2pt] &=& 4X_j X_j \otimes 1 - 2i X_\ell \otimes \sigma_\ell \\ [2pt] &=& \Delta - 2 D \end{array}$

It follows that $\Delta = D(D+2),$ so

$\Delta + 1 = (D+1)^2 = (\partial\!\!\!/ - \frac{1}{2})^2$

Combining this with our earlier formula for the hydrogen atom Hamiltonian:

$\displaystyle{ H = - \frac{1}{2(\Delta + 1)} }$

we can now express the Hamiltonian for the hydrogen atom in terms of the Dirac operator on the 3-sphere:

$\displaystyle{ H \; = \; - \frac{1}{2(\partial\!\!\!/ - \frac{1}{2})^2} }$

This is pretty cool. We will exploit this later.

Further details

That was the main result we’ll need, but while working on this I got interested in understanding the eigenvectors and eigenvalues of the Dirac operator in more detail. Here are some facts about those.

Since $\partial\!\!\!/$ maps each finite-dimensional subspace

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

to itself, and it is self-adjoint on these subspaces, each of these subspaces has an orthonormal basis of eigenvectors. So, consider an eigenvector: suppose $\psi \in V_j \otimes V_j \otimes \mathbb{C}^2$ has

$\partial\!\!\!\psi = \lambda \psi.$

Then we must have

$(\lambda - \frac{1}{2})^2 \psi = (\partial\!\!\!/ - \frac{1}{2})^2 \psi = (\Delta + 1)\psi = n^2 \psi$

where $n = 2j+1$ as usual, so we must have $\lambda - \frac{1}{2} = \pm n.$ Thus, the only possible eigenvalues of $\partial\!\!\!/$ on the subspace $V_j \otimes V_j \otimes \mathbb{C}^2$ are $\pm n + \frac{1}{2},$ or in other words:

$\psi \in V_j \otimes V_j \otimes \mathbb{C}^2 \implies \partial\!\!\!/ \psi = \lambda \psi \text{ for } \lambda = \pm (2j+1) + \frac{1}{2}$

To go further, we can use some results from Kronheimer. First, he shows the spectrum of $\partial\!\!\!/$ is symmetric about the origin. To do this he identifies $\mathbb{C}^2$ with the quaternions, and thus $L^2(S^3) \otimes \mathbb{C}^2$ with a space of quaternion-valued functions on the 3-sphere. Then quaternionic conjugation gives a conjugate-linear operator

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

with $\dagger^2 = 1.$ He then proves a result, using his Dirac-like operator $D,$ that implies

$\partial\!\!\!/ \psi = \lambda \psi \; \iff \; \partial\!\!\!/ \psi^\dagger = -\lambda \psi^\dagger$

Thus the Dirac operator $\partial\!\!\!/$ has as a negative eigenvalue for each positive eigenvalue, and their multiplicities are the same!

Second, he proved a result which implies that the eigenspace

$F_\lambda = \{ \psi \in L^2(S^3) \otimes \mathbb{C}^2 : \; \partial\!\!\!/ \psi = \lambda \psi \}$

has dimension

$\text{dim}(F_\lambda) = (\lambda+\frac{1}{2})(\lambda-\frac{1}{2})$

when $\lambda \in \mathbb{Z} + \frac{1}{2}$ and zero otherwise. Thus every number that’s an integer plus $\frac{1}{2}$ is an eigenvalue of the Dirac operator on the 3-sphere—except $\pm\frac{1}{2}.$ Also, while we’ve already seen that

$V_j \otimes V_j \otimes \mathbb{C}^2 = F_{n+\frac{1}{2}} \oplus F_{-n +\frac{1}{2}}$

where $n = 2j+1,$ this additional result implies that these two summands have different dimensions, namely $n(n+1)$ and $n(n-1),$ respectively. Their total dimension is $2n^2,$ as we already knew! We knew it because this is the number of electron states in the shell with principal quantum number $n.$

So, a bit more than half the electron states in the nth shell are positive eigenvectors of the Dirac operator on the 3-sphere, while a bit fewer than half are negative eigenvectors. Weird but true!

For an explicit basis of eigenvectors of the Dirac operator on $S^3,$ see:

• Fabio Di Cosmo and Alessandro Zampini, Some notes on Dirac operators on the $S^2$ and $S^3$ spheres.