Même avant mon départ pour La Thuile (Italie), les résultats des Rencontres de Moriond remplissaient déjà les fils d’actualités. La session de cette année sur l’interaction électrofaible, du 15 au 22 mars, a débuté avec la première « mesure mondiale » de la masse du quark top, basée sur la combinaison des mesures publiées jusqu’à présent par les expériences Tevatron et LHC. La semaine s’est poursuivie avec un résultat spectaculaire de CMS sur la largeur du Higgs.

Même si elle approche de son 50^e anniversaire, la conférence de Moriond est restée à l’avant-garde. Malgré le nombre croissant de conférences incontournables en physique des hautes énergies, Moriond garde une place de choix dans la communauté, pour des raisons en partie historiques : cette conférence existe depuis 1966 et elle s’est imposée comme l’endroit où les théoriciens et les expérimentateurs viennent pour voir et être vus. Regardons maintenant ce que les expériences du LHC nous ont réservé cette année…

Nouveaux résultats­­­

Cette année, le clou du spectacle à Moriond a bien entendu été l’annonce de la meilleure limite à ce jour pour la largeur du Higgs, à < 17 MeV avec 95 % de confiance, présentée aux deux sessions de Moriond par l’expérience CMS. La nouvelle mesure, obtenue par une nouvelle méthode d’analyse basée sur les désintégrations du Higgs en deux particules Z, est environ 200 fois plus précise que les précédentes. Les discussions sur cette limite ont porté principalement sur la nouvelle méthode utilisée pour l’analyse. Quelles hypothèses étaient nécessaires ? La même technique pouvait-elle être appliquée à un Higgs se désintégrant en deux bosons W ? Comment cette nouvelle largeur allait-elle influencer les modèles théoriques pour la nouvelle physique ? Nous le découvrirons sans doute à Moriond l’année prochaine…

L’annonce du premier résultat mondial conjoint pour la masse du quark top a aussi suscité un grand enthousiasme. Ce résultat, qui met en commun les données du Tevatron et du LHC, constitue la meilleure valeur jusqu’ici, au niveau mondial, à 173,34 ± 0,76 GeV/c². Avant que l’effervescence ne soit retombée à la session de QCD de Moriond, CMS a annoncé un nouveau résultat préliminaire fondé sur l’ensemble des données collectées à 7 et 8 TeV. Ce résultat est à lui seul d’une précision qui rivalise avec celle de la moyenne mondiale, ce qui démontre clairement que nous n’avons pas encore atteint la plus grande précision possible pour la masse du quark top.

Ce graphique montre les quatre mesures de la masse du quark top publiées respectivement par les collaborations ATLAS, CDF, CMS et D0, ainsi que la mesure la plus précise à ce jour obtenue grâce à l’analyse conjointe.

D’autres nouveautés concernant le quark top, entre autres les nouvelles mesures précises de son spin et de sa polarisation issues du LHC, ainsi que les nouveaux résultats d’ATLAS pour la section efficace du quark top isolé dans le canal de désintégration t, ont été présentés par Kate Shaw le mardi 25 mars. La période II du LHC permettra d’approfondir encore notre compréhension du sujet.

Une mesure fondamentale et délicate permettant d’explorer la nature de la brisure de la symétrie électrofaible portée par le mécanisme de Brout-Englert-Higgs est celle de la diffusion de deux bosons vecteurs massifs. Cet événement est rare, mais en l’absence du boson de Higgs sa fréquence augmenterait fortement avec l’énergie de la collision, jusqu’à enfreindre les lois de la physique. Un indice de la collision d’un boson vecteur de force électrofaible a été détecté pour la première fois par ATLAS dans des événements impliquant deux leptons de même charge et deux jets présentant une grande différence de rapidité.

S’appuyant sur l’augmentation du volume de données et une meilleure analyse de celles-ci, les expériences du LHC s’attaquent à des états finaux multi-particules rares et difficiles qui font intervenir le boson de Higgs. ATLAS en a présenté un excellent exemple, avec un nouveau résultat dans la recherche de la production d’un Higgs associé à deux quarks top et se désintégrant en une paire de quarks b. Avec une limite prévue de 2,6 fois la prédiction du Modèle standard pour ce seul canal et une intensité de signal relative observée de 1,7 ± 1,4, la future exploitation à haute énergie du LHC, avec laquelle la fréquence de cet événement augmentera, suscite de grands espoirs.

Dans le même temps, dans le monde des saveurs lourdes, l’expérience LHCb a présenté des analyses supplémentaires de l’état exotique X(3872). L’expérience a confirmé de manière non ambiguë que ses nombres quantiques J^pc sont 1⁺⁺ et a mis en évidence sa désintégration en ψ(2S)γ.

L’étude du plasma de quarks et de gluons se poursuit dans l’expérience ALICE, et les discussions ont porté surtout sur les résultats de l’exploitation du LHC en mode proton-plomb (p-Pb). En particulier, la « double crête » nouvellement observée dans les collisions p-Pb est étudiée en détail, et des analyses du pic de ses jets, de sa distribution de masse et de sa dépendance à la charge ont été présentées.

Nouvelles explorations

Grâce à notre nouvelle compréhension du boson de Higgs, le LHC est entré dans l’ère de la physique du Higgs de précision. Notre connaissance des propriétés du Higgs – par exemple les mesures de son spin et de sa largeur – s’est améliorée, et les mesures précises des interactions et des désintégrations du Higgs ont elles aussi bien progressé. Des résultats relatifs à la recherche d’une physique au-delà du Modèle standard ont également été présentés, et les expériences du LHC continuent de s’investir intensément dans la recherche de la supersymétrie.

En ce qui concerne le secteur de Higgs, de nombreux chercheurs espèrent trouver les cousins supersymétriques du Higgs et des bosons électrofaibles, appelés neutralinos et charginos, par l’intermédiaire de processus électrofaibles. ATLAS a présenté deux nouveaux articles résumant de multiples recherches en quête de ces particules. L’absence d’un signal significatif a été utilisée pour définir des limites d’exclusion pour les charginos et les neutralinos, soit 700 GeV – s’ils se désintègrent via des partenaires supersymétriques intermédiaires de leptons – et 420 GeV – quand ils se désintègrent seulement via des bosons du Modèle standard.

Par ailleurs, pour la première fois, une recherche du mode électrofaible le plus difficile à observer, produisant une paire de charginos qui se désintègrent en bosons W, a été entreprise par ATLAS. Ce mode ressemble à celui de la production de paires de W du Modèle standard, dont le taux mesuré actuellement paraît légèrement plus élevé que prévu.

Dans ce contexte, CMS a présenté de nouveaux résultats dans la recherche de la production d’une paire électrofaible de higgsinos via leur désintégration en un Higgs (à 125 GeV) et un gravitino de masse presque nulle. L’état final montre une signature caractéristique de jets de quatre quarks b, compatible avec une cinématique de double désintégration du Higgs. Un léger excès du nombre d’événements candidats signifie que l’expérience ne peut pas exclure un signal de higgsino. On établit des limites supérieures de l’intensité du signal d’environ deux fois la prédiction théorique pour des masses du higgsino comprises entre 350 et 450 GeV.

Dans plusieurs scénarios de supersymétrie, les charginos peuvent être métastables et ils pourraient potentiellement être détectés sous la forme de particules à durée de vie longue. CMS a présenté une recherche innovante de particules génériques chargées à durée de vie longue, effectuées en cartographiant l’efficacité de détection en fonction de la cinématique de la particule et de la perte d’énergie dans le trajectographe. Cette étude permet non seulement d’établir des limites strictes pour divers modèles supersymétriques qui prédisent une durée de vie du chargino (c*tau) supérieure à 50 cm mais elle fournit également un puissant outil à la communauté des théoriciens pour tester de manière indépendante les nouveaux modèles prédisant des particules chargées à durée de vie longue.

Afin d’être aussi général que possible dans la recherche de la supersymétrie, CMS a également présenté les résultats de nouvelles recherches, dans lesquelles un grand sous-ensemble des paramètres de la supersymétrie, tels que les masses du gluino et du squark, sont testés pour vérifier leur compatibilité statistique avec différentes mesures expérimentales. Cela a permis d’établir une carte des probabilités dans un espace à 19 dimensions. Cette carte montre notamment que les modèles prédisant des masses inférieures à 1,2 TeV pour le gluino et inférieures à 700 GeV pour le sbottom et le stop sont fortement défavorisés.

… mais pas de nouvelle physique

Malgré toute ces recherches minutieuses, ce qu’on a le plus entendu à Moriond, c’était: « pas d’excès observé » – « cohérent avec le Modèle standard ». Tous les espoirs reposent maintenant sur la prochaine exploitation du LHC, à 13 TeV. Si vous souhaitez en savoir davantage sur les perspectives ouvertes par la deuxième exploitation du LHC, consultez l’article suivant du Bulletin du CERN: “La vie est belle à 13 TeV“.

En plus des divers résultats des expériences du LHC qui ont été présentés, des nouvelles ont aussi été rapportées à Moriond par les expériences du Tevatron, de BICEP, de RHIC et d’autres expériences. Pour en savoir plus, consultez les sites internet de la conférence, Moriond EW et Moriond QCD.

A diabolical psychologist brings a mathematician in for an experiment. The mathematician is seated in a chair on a track leading to a bed on which there is an extremely attractive person of the appropriate gender, completely naked. The psychologist explains “This person will do absolutely anything you want, subject to one condition: every five minutes, we will move your chair across one-half of the distance separating you.”

The mathematician explodes in outrage. “What! It’ll take an infinite time to get there. This is torture!” They storm out.

The next experimental subject is a physicist, who sits in the chair and gets the same explanation. “Awesome!” says the physicist. “Let’s get started!”

The psychologist is taken aback. “You do realize that you’ll never get all the way there, right?”

“Oh, sure,” says the physicist, “but I’ll get close enough for all practical purposes.”

This week’s episode of Cosmos went from the whopping huge to the very small, working their way down from tardigrades to nuclei. This was front-loaded with a bunch of biochem content, and only got around to physics and astrophysics much later.

As always, the visuals were spectacular, particularly the animated microscopic organisms. I was a little puzzled, though, by the decision to go from a quasi-photographic rendition of plant cells and orgnelles to a visualized metaphorical machine representing the action of photosynthesis. I mean, it was nice animation, and all, but kind of jarring after all the very literal stuff that came before it.

There was less historical content in this one, which is probably to the good. There was a slightly overdone bit about Darwin predicting the existence of long-tongued insects to pollinate particular species of orchid (which is mentioned in the Origin but not given especially heavy emphasis). And there was the obligatory call-back to the ancient Greek atomists, where they deserve credit for not just starting with Democritus, but going back to Thales a century or so earlier. The Greek cartoons got in the obligatory anti-religion message, and suffered from the usual problem that the ideas of the atomist Greeks were not actually all that similar to the modern concept of atoms. It wouldn’t be the Cosmos reboot without some annoyingly ahistorical content.

The “Keanu whoa” moment for the week was the claim that we never really touch anything, since the electromagnetic repulsion between molecules making up solid objects means there’s always a microscopic space between even objects that appear to be in contact. Which is true enough, but mostly just reminds me of the joke at the top of this post.

I was mostly okay with the discussion of atoms and nuclei; it could’ve used more quantum-mechanical content, but I suspect they think they got that out of the way last week. I will note that it’s not really hot enough in the core of the Sun (according to our best models) for protons to be moving fast enough to directly come in contact and fuse– you can calculate the necessary temperature for the distance of closest approach of two positive charges to be on the scale of a nucleus, and it’s around 15,000,000,000 K. The actual temperature of the Sun is more like 10,000,000 K. But quantum mechanics allows a tiny probability for one proton to tunnel through to the other, and allows fusion to proceed. That, to my mind, is more awesome than the “We never really touch anything”stuff, but then, I’m a physicist.

The last bit was about neutrinos, both as an element of observational astrophysics– shoutout to an animated supernova 1987a, but as usual none of the actual photos of the supernova outshining everything else– and as a possible probe of the early universe through the relic neutrinos created in the Big Bang. This was illustrated with a Wolfgang Pauli hologram, but next to no detail about Pauli himself, which I found a little disappointing because he’s an entertaining figure. Fun trivia: his famous prediction of the existence of the neutrino as a desperate remedy for the problem of beta decay (the explanation of which was a little garbled, but whatever) was via a letter sent to a conference that he was skipping because he wanted to attend a ball in Zurich. So much for the image of the antisocial physicist…

Anyway, a mostly good episode. The gaps in the science were either biological things that I didn’t notice, or subtle-ish points of physics that nobody else will notice. I could’ve done with less “matter is empty space!” and more quantum physics (or a discussion of Rutherford, because I never get tired of Rutherford), but I’m probably in a small minority there.

My first physics class wasn’t really a class at all. One of my 8th grade teachers noticed me carrying a copy of Kip Thorne’s Black Holes and Time Warps, and invited me to join a free-form book discussion group on physics and math that he was holding with a few older students. His name was Art — and we called him by his first name because I was attending, for want of a concise term that’s more precise, a “hippie” school. It had written evaluations instead of grades and as few tests as possible; it spent class time on student governance; and teachers could spend time on things like, well, discussing books with a few students without worrying about whether it was in the curriculum or on the tests. Art, who sadly passed some years ago, was perhaps best known for organizing the student cafe and its end-of-year trip, but he gave me a really great opportunity. I don’t remember learning anything too specific about physics from the book, or from the discussion group, but I remember being inspired by how wonderful and crazy the universe is.

My second physics class was combined physics and math, with Dan and Lewis. The idea was to put both subjects in context, and we spent a lot of time on working through how to approach problems that we didn’t know an equation for. The price of this was less time to learn the full breadth subjects; I didn’t really learn any electromagnetism in high school, for example.

When I switched to a new high school in 11th grade, the pace changed. There were a lot more things to learn, and a lot more tests. I memorized elements and compounds and reactions for chemistry. I learned calculus and studied a bit more physics on the side. In college, where the physics classes were broad and in depth at the same time, I needed to learn things fast and solve tricky problems too. By now, of course, I’ve learned all the physics I need to know — which is largely knowing who to ask or which books to look in for the things I need but don’t remember.

There are a lot of ways to run schools and to run classes. I really value knowledge, and I think it’s crucial in certain parts of your education to really buckle down and learn the facts and details. I’ve also seen the tremendous worth of taking the time to think about how you solve problems and why they’re interesting to solve in the first place. I’m not a high school teacher, so I don’t think I can tell the professionals how to balance all of those goods, which do sometimes conflict. What I’m sure of, though, is that enthusiasm, attention, and hard work from teachers is a key to success no matter what is being taught. The success of every physicist you will ever see on Quantum Diaries is built on the shoulders of the many people who took the time to teach and inspire them when they were young.

1st April 2014. The LHC is currently in shutdown in preparation for the next physics run in 2015. However the record breaking accelerator is danger is falling far behind schedule as the engineers struggle with technical difficulties 100m below ground level.

The LHC tunnels house the 27km long particle accelerator in carefully controlled conditions. When the beams circulate they must be kept colder than anywhere else in the solar system, and with a vacuum more empty the voids of outer space. Any disruption to the cryogenic cooling systems or the vacuum systems can place serious strain on the operations timetable, and engineers have found signs of severe damage.

Scientists patrol the LHC, inspecting the damaged areas.

The first indications of problems were identified coming from Sector 7 between areas F and H. Cryogenics expert, Francis Urquhart said “My team noticed dents in the service pipes about 50cm from the floor. There was also a deposit of white fibrous foreign matter on some of the cable trays.” The pipes were replaced, but the damage returned the following day, and small black aromatic samples were found piled on the floor. These were sent for analysis and after chemical tests confirmed that they contained no liquid Helium, and that radiometry found they posed no ionisation risk, they were finally identified as Ovis aries depositions.

Ovis aries are found throughout the CERN site, so on-site contamination could not be ruled out. It is currently thought that the specimens entered the Super Proton Synchrotron (SPS) accelerator and proceeded from the SPS to the LHC, leaving deposits as they went. The expert in charge, Gabriella Oak, could not be reached for comment, but is said to be left feeling “rather sheepish”.

Elsewhere on the ring there was another breach of the security protocols as several specimens of Bovinae were found in the ring. The Bovinae are common in Switzerland and it due to their size, must have entered via one of the service elevators. All access points and elevators at the LHC are carefully controlled using biometry and retinal scans, making unauthorised entry virtually impossible. Upon being asked whether the Bovinae had been seen scanning their retinae at the security checkpoints, Francis Urquhart replied “You might very well think that. I could not possibly comment.” While evidence of such actions cannot be found CCTV footage, there have been signs of chewed cud found on the floor, and Bovinae deposits, which are significantly larger than the Ovis deposits, owing to the difference in size.

The retinal scans at the LHC are designed exclusively for human use. A search of the biometric record database show at least one individual (R Wiggum) with unusual retinae, affiliated to “Bovine University”.

It is not known exactly how much fauna is currently in the LHC tunnels, although it is thought to be at least 25 different specimens. They can be identified by the bells they carry around their necks, which can sound like klaxons when they charge. Until the fauna have been cleared, essential repair work is extremely difficult. “I was repairing some damage caused by a passing cow” said Stanford PhD student Cecilia, “when I thought I heard the low oxygen klaxon. By the time I realised it was just two sheep I had already put on my safety mask and pulled the alarm to evacuate the tunnels.” She then commented “It took us three hours to get access to the tunnels again, and the noises and lights had caused the animals to panic, creating even more damage to clean up.”

This is not the first time a complex of tunnels has been overrun by farm animals. In the early 90s the London Underground was found to be infested with horses, which turned into a longterm problem and took many years to resolve.

Current estimates on the delay to the schedule range from a few weeks to almost a decade. Head of ATLAS operations, Dr Remy Beauregard Hadley, comments “I can’t believe all this has happened. They talk about Bovinae deposits delaying the turn on, and I think it’s just a load of bullshit!”

read more

Nearly a decade ago, blogging was young, and its place in the academic world wasn’t clear. Back in 2005, I wrote about an anonymous article in the Chronicle of Higher Education, a so-called “advice” column admonishing academic job seekers to avoid blogging, mostly because it let the hiring committee find out things that had nothing whatever to do with their academic job, and reject them on those (inappropriate) grounds.

I thought things had changed. Many academics have blogs, and indeed many institutions encourage it (here at Imperial, there’s a College-wide list of blogs written by people at all levels, and I’ve helped teach a course on blogging for young academics). More generally, outreach has become an important component of academic life (that is, it’s at least necessary to pay it lip service when applying for funding or promotions) and blogging is usually seen as a useful way to reach a wide audience outside of one’s field.

So I was distressed to see the lament — from an academic blogger — “Want an academic job? Hold your tongue”. Things haven’t changed as much as I thought:

… [A senior academic said that] the blog, while it was to be commended for its forthright tone, was so informal and laced with profanity that the professor could not help but hold the blog against the potential faculty member…. It was the consensus that aspiring young scientists should steer clear of such activities.

Depending on the content of the blog in question, this seems somewhere between a disregard for academic freedom and a judgment of the candidate on completely irrelevant grounds. Of course, it is natural to want the personalities of our colleagues to mesh well with our own, and almost impossible to completely ignore supposedly extraneous information. But we are hiring for academic jobs, and what should matter are research and teaching ability.

Of course, I’ve been lucky: I already had a permanent job when I started blogging, and I work in the UK system which doesn’t have a tenure review process. And I admit this blog has steered clear of truly controversial topics (depending on what you think of Bayesian probability, at least).

Lars Bildsten (KITP) was in town and gave two talks today. In the first, he talked about super-luminous supernovae, and how they might be powered by the spin-down of the degenerate remnant, when spin-down times and diffusion times become comparable. In the second, he talked about making precise inferences about giant stars from Kepler and COROT photometry. The photometry shows normal modes and mode splittings, which are sensitive to the run of density in the giants; this in turn constrains what fraction of the star has burned to helium. There is a lot of interesting unexplained phenomenology related to the spin of the stellar core, which remains a puzzle. There was much more in the talk as well, but one thing that caught my interest is that some of the modes are exceedingly high in quality factor or coherence. That is, giants look like very good clocks. A discussion broke out at the end about whether or not we could use these clocks to constrain, detect, or measure gravitational radiation. Each star is much worse than a radio pulsar, but there are far, far more of them available for use. Airplane project!

In a low-research day, at lunch, Kilian Walsh pitched to Fadely and me a project to infer galaxy host halo masses from galaxy positions and redshifts. We discussed some of the issues and previous work. I am out of the loop, so I don't know the current literature. But I am sure there is interesting work that can be done, and it would be fun to combine galaxy kinematic information with weak lensing, strong lensing, x-ray, and SZ effect data.

One of the weird quirks of Union college, where I teach, is that the hockey teams compete in the NCAA’s Division I, something that doesn’t usually happen for a school with only 2200 students. That might seem like a ridiculously terrible idea, but last night, it worked surprisingly well: Union beat perennial hockey power Minnesota for the NCAA National Championship. It was an amazing game

I’m not going to pretend like I’m a huge fan– Kate and I watched on tv, the only hockey I’ve watched all season– and I’m certainly not going to use first-person pronouns to talk about it (I really hate that…). I had nothing to do with this– I’m fairly sure I’ve never even had any current hockey players in class. This is all theirs, the product of lots of hard work.

But this is a huge deal for all the students. We even got a few glimpses of some physics majors on ESPN– two of them, including one of my research students, play in the pep band. Pretty much all of them will remember this forever as one of the biggest things to happen in their time in college. And that’s worth celebrating and acknowledging.

So congratulations to the hockey team, some of whom celebrated in the most 2014 way imaginable, as seen in the “featured image” up top. The guys in hockey gear are Matt Bodie, Shayne Gostisbehere, and Daniel Carr, three of Union’s standout players– Gostisbehere in particular played an amazing game, and was trending on Twitter at one point, which is a miracle given his surname. The dude in the suit taking the selfie is ESPN’s John Buccigross (the resulting photo is here). This isn’t a you-kids-get-your-selfies-off-my-lawn thing, by the way– I think it’s pretty funny, and kind of awesome.

2014, ladies and gentlemen, and the Union College Dutchmen, NCAA Division I National Champions.

The other night I dreamed I was going into a coffeeshop and Seth Rogen was sitting at an outside table eating a salad.  He was wearing a jeans jacket and his skin was sort of bad.  I have always admired Rogen’s work so I screwed up my courage, went up to his table and said

“Are you…”

And he said, “Yes, I am… having the chef’s salad.  You should try it, it’s great.”

And I sort of stood there and goggled and then he was like, “Yeah, no, yes, I’m Seth Rogen.”

I feel proud of my unconscious mind for producing what I actually consider a reasonably Seth Rogen-style gag!

A frightening fraction of my open tabs are some of Bee’s posts at Backreaction – so to save my browsers, I dump them here for further future perusal:

Are irreproducible scientific results okay and just business as usual?

Shut up and let me think

Should the Nobel Prize be given to collaborations and institution?

Women in Science, Again?

Science Martketing needs Consumer Feedback

Does Modern Science Discourage Creativity?

The comeback of massive gravity?

Can Planck Stars Exist?

Book review: “The Theoretical Minimum – Quantum Mechanics” By Susskind and Friedman

Do we live in a hologram? Really??

Hmm:
yes, yes, no,
yes, yes, maybe,
no, no, yes,
maybe, yes, yes!

If I lost count, this could be really embarrassing…

In times past we have lovingly tracked the proposal frenzy as the near annual Hubble Space Telescope proposal deadline approaches.

As was noted by Julianne several years ago, and confirmed over the last half dozen cycles, the shape of the curve of number of submitted proposals as a function of time until the deadline is nearly invariant.
Interestingly, the total number of proposals also does not change much, some dips and spikes with the loss and availability of instruments, but the total is near stationary and some measure of the statistical saturation of the ability of astronomers to put together coherent proposals in a finite time.

Anyway, here is this year’s lot, culled from a small sample of fb posts:

Same-same…

@astronomolly kept it real on twitter in the run up

Notes on Academic Blogging – Crooked Timber pines for the Good Old days

Old School Blogging – seeing a pattern here…

Want an Academic job? Hold your tongue

Is it Journalism or just a prepackage press release – Sunlight Foundation’s Churnalism tool.

So I’ve written an article about the above question for PBS’s website—a sort of tl;dr version of my 2005 survey paper NP-Complete Problems and Physical Reality, but updated with new material about the simulation of quantum field theories and about AdS/CFT.  Go over there, read the article (it’s free), then come back here to talk about it if you like.  Thanks so much to Kate Becker for commissioning the article.

In other news, there’s a profile of me at MIT News (called “The Complexonaut”) that some people might find amusing.

Oh, and anyone who thinks the main reason to care about quantum computing is that, if our civilization ever manages to surmount the profound scientific and technological obstacles to building a scalable quantum computer, then that little padlock icon on your web browser would no longer represent ironclad security?  Ha ha.  Yeah, it turns out that, besides factoring integers, you can also break OpenSSL by (for example) exploiting a memory bug in C.  The main reason to care about quantum computing is, and has always been, science.

I spent a while at the group meeting of applied mathematician Leslie Greengard (NYU, Simons Foundation), telling the group how cosmology is done, and then how it might be done if we had some awesome math foo. In part we got on to how you could make a non-parametric kernel function for a Gaussian Process for the matter density field at late times, given that you need to stay non-negative definite. Oh wait, I mean positive semi-definite. Oh the things you learn! Anyway, it turns out that this is not really a solved problem and possibly a project was born. Hope so! I would love to recreate our discovery of the baryon acoustic feature with proper inference. At the group meeting, Foreman-Mackey and I had an "aha moment" about Ambikasaran et al's method for solving and taking the determinants of kernel matrices (Siva Ambikasaran (NYU) was in attendance), and then spent the post-group-meeting lunch in part quizzing Mike O'Neil (NYU) about how to structure our code to work fast in the three-dimensional case (the cosmology case).

Guest post by Bruce Bartlett

The following is the greatest math talk I’ve ever watched!

• Etienne Ghys (with pictures and videos by Jos Leys), Knots and Dynamics, ICM Madrid 2006. [See below the fold for some links.]

I wasn’t actually at the ICM; I watched the online version a few years ago, and the story has haunted me ever since. Simon and I have been playing around with some of this stuff, so let me share some of my enthusiasm for it!

The story I want to tell here is how, via modular flow of lattices in the plane, certain matrices in $\SL(2,\mathbb{Z})$ give rise to knots in the 3-sphere less a trefoil knot. Despite possibly sounding quite scary, this can be easily explained in an elementary yet elegant fashion.

As promised above, here are some links related to Ghys’ ICM talk.

• Video — watch this now!
• Slides — the (ungarbled) slides for the talk
• Web version with animations — a great summary
• Article — the accompanying article with details
• More pictures — from Jos Leys’s webpage
• More animations — from Jos Leys’s webpage
• Article by Dana Lyons — a great summary with historical context and interviews

I’m going to focus on the last third of the talk — the modular flow on the space of lattices. That’s what produced the beautiful picture above (credit for this and other similar pics below goes to Jos Leys; the animation is Simon’s.)

Lattices in the plane

For us, a lattice is a discrete subgroup of $\mathbb{C}$. There are three types: the zero lattice, the degenerate lattices, and the nondegenerate lattices:

Given a lattice $L$ and an integer $n \geq 4$ we can calculate a number — the Eisenstein series of the lattice: $$G_{n}(L) = \sum _{\omega \in L, \omega \neq 0} \frac{1}{\omega ^{n}}.$$ We need $n \geq 3$ for this sum to converge. For, roughly speaking, we can rearrange it as a sum over $r$ of the lattice points on the boundary of a square of radius $r$. The number of lattice points on this boundary scales with $r$, so we end up computing something like $\sum _{r \geq 0} \frac{r}{r^{n}}$ and so we need $n \geq 3$ to make the sum converge.

Note that $G_{n}(L)$ = 0 for $n$ odd since every term $\omega$ is cancelled by the opposite term $-\omega$. So, the first two nontrivial Eisenstein series are $G_{4}$ and $G_{6}$. We can use them to put `Eisenstein coordinates’ on the space of lattices.

Theorem: The map $$\begin{aligned} \{ \text{lattices} \} &\rightarrow \mathbb{C}^{2} \\ L & \mapsto (G_{4} (L), \, G_{6}(L)) \end{aligned}$$ is a bijection.

The nicest proof is in Serre’s A Course in Arithmetic, p. 89. It is a beautiful application of the Cauchy residue theorem, using the fact that $G_{4}$ and $G_{6}$ define modular forms on the upper half plane $H$. (Usually, number theorists set up their lattices so that they have basis vectors $1$ and $\tau$ where $\tau \in H$. But I want to avoid this ‘upper half plane’ picture as far as possible, since it breaks symmetry and mystifies the geometry. The whole point of the Ghys picture is that not breaking the symmetry reveals a beautiful hidden geometry! Of course, sometimes you need the ‘upper half plane’ picture, like in the proof of the above result.)

Lemma: The degenerate lattices are the ones satisfying $20 G_{4}^{3} - 49G_{6}^{2} = 0$.

Let’s prove one direction of this lemma — that the degenerate lattices do indeed satisfy this equation. To see this, we need to perform a computation. Let’s calculate $G_{4}$ and $G_{6}$ of the lattice $\mathbb{Z} \subset \mathbb{C}$. Well, $$G_{4}(\mathbb{Z}) = \sum _{n \neq 0} \frac{1}{n^{4}} = 2 \zeta (4) = 2 \frac{\pi ^{4}}{90}$$ where we have cheated and looked up the answer on Wikipedia! Similarly, $G_{6}(\mathbb{Z}) = 2 \frac{\pi ^{6}}{945}$.

So we see that $20 G_{4}(\mathbb{Z})^{3} - 49 G_{6}(\mathbb{Z})^{2} = 0$. Now, every degenerate lattice is of the form $t \mathbb{Z}$ where $t \in \mathbb{C}$. Also, if we transform the lattice via $L \mapsto t L$, then $G_{4} \mapsto t^{-4} G_{4}$ and $G_{6} \mapsto t^{-6} G_{6}$. So the equation remains true for all the degenerate lattices, and we are done.

Corollary: The space of nondegenerate lattices in the plane of unit area is homeomorphic to the complement of the trefoil in $S^{3}$.

The point is that given a lattice $L$ of unit area, we can scale it $L \mapsto \lambda L$, $\lambda \in \mathbb{R}^{+}$ until $(G_{4}(L), G_{6}(L))$ lies on the 3-sphere $S^{3} = \{ (z,w) : |z|^{2} + |w|^{2} = 1\} \subset \mathbb{C}^{2}$. And the equation $20 z^{3} - 49 w^{2} = 0$ intersected with $S^{3}$ cuts out a trefoil knot… because it is “something cubed plus something squared equals zero”. And the lemma above says that the nondegenerate lattices are precisely the ones which do not satisfy this equation, i.e. they represent the complement of this trefoil.

Since we have not divided out by rotations, but only by scaling, we have arrived at a 3-dimensional picture which is very different to the 2-dimensional moduli space (upper half-plane divided by $\SL(2,\mathbb{Z})$) picture familiar to a number theorist.

The modular flow

There is an intriguing flow on the space of lattices of unit area, called the modular flow. Think of $L$ as sitting in $\mathbb{R}^{2}$, and then act on $\mathbb{R}^{2}$ via the transformation $$\left ( \begin{array}{cc} e^{t} & 0 \\ 0 & e^{-t} \end{array} \right ),$$ dragging the lattice $L$ along for the ride. (This isn’t just some formula we pulled out the blue — geometrically this is the ‘geodesic flow on the unit tangent bundle of the modular orbifold’.)

We are looking for periodic orbits of this flow.

“Impossible!” you say. “The points of the lattice go off to infinity!” Indeed they do… but disregard the individual points. The lattice itself can ‘click’ back into its original position:

How are we to find such periodic orbits? Start with an integer matrix $$A = \left ( \begin{array}{cc} a & b \\ c & d \end{array}\right ) \in \SL(2, \mathbb{Z})$$ and assume $A$ is hyperbolic, which simply means $|a + d| \geq 2$. Under these conditions, we can diagonalize $A$ over the reals, so we can find a real matrix $P$ such that $$P A P^{-1} = \pm \left ( \begin{array}{cc} e^{t} & 0 \\ 0 & e^{-t} \end{array} \right )$$ for some $t \in \mathbb{R}$. Now set $L \coloneqq P(\mathbb{Z}^{2})$. We claim that $L$ is a periodic orbit of period $t$. Indeed: $$\begin{aligned} L_{t} &= \left ( \begin{array}{cc} e^{t} & 0 \\ 0 & e^{-t} \end{array} \right ) P (\mathbb{Z}^{2}) \\ &= \pm PA (\mathbb{Z}^{2}) \\ &= \pm P (\mathbb{Z}^{2}) \\ &= L. \end{aligned}$$ We have just proved one direction of the following.

Theorem: The periodic orbits of the modular flow are in bijection with the conjugacy classes of hyperbolic elements in $\SL(2, \mathbb{Z})$.

These periodic orbits produce fascinating knots in the complement of the trefoil! In fact, they link with the trefoil (the locus of degenerate lattices) in fascinating ways. Here are two examples, starting with different matrices $A \in \SL(2, \mathbb{Z})$.

The trefoil is the fixed orange curve, while the periodic orbits are the red and green curves respectively.

Ghys proved the following two remarkable facts about these modular knots.

• The linking number of a modular knot with the trefoil of degenerate lattices equals the Rademacher function of the corresponding matrix in $\SL(2, \mathbb{Z})$ (the change in phase of the Dedekind eta function).
• The knots occuring in the modular flow are the same as those occuring in the Lorenz equations!

Who would have thought that lattices in the plane could tell the weather!!

I must say I have thought about many aspects of these closed geodesics, but it had never crossed my mind to ask which knots are produced. – Peter Sarnak

Lots of good stuff happening in math blogging!

• Matt Baker is blogging!  Lately:  an appreciation of Robert Coleman, and Riemann-Roch for graphs.
• Frank Calegari is blogging!  Actually he’s been blogging for a while but there’s tons of good stuff on here lately.  Two recent posts that tie in closely with my own interests:  The congruence subgroup property for thin groups, and The thick diagonal, in which Frank’s student Vlad Serban solves a puzzle I asked about, and much more besides.  Also, Cheeseboard still wins.
• Adriana Salerno is blogging!  Mostly about the profession and specifically the situation of young researchers in math.  I like this post about collaborator visits because my old friend Leila Schneps, who taught me about the fundamental group, guest-stars in it!
• And just so it’s not all number theorists:  Afonso Bandeira is blogging!  I don’t even know this guy, but he’s writing tons of interesting stuff about problems in what I like to call “applied pure math,” questions about geometry of large sets and classification and convex relaxation and embeddings of metric spaces and etc. and etc.

Nina Otter is a master’s student in mathematics at ETH Zürich who has just gotten into the PhD program at Oxford. She and I are writing a paper on operads and the tree of life.

Anyone who knows about operads knows that they’re related to trees. But I’m hoping someone has proved some precise theorems about this relationship, so that we don’t have to.

By operad I’ll always mean a symmetric topological operad. Such a thing has an underlying ‘symmetric collection’, which in turn has an underlying ‘collection’. A collection is just a sequence of topological spaces $O_n$ for $n \ge 0$. In a symmetric collection, each space $O_n$ has an action of the symmetric group $S_n$.

I’m hoping that someone has already proved something like this:

Conjecture 1. The free operad on the terminal symmetric collection has, as its space of $n$-ary operations, the set of rooted trees having some of their leaves labelled $\{1, \dots, n\}$.

Conjecture 2. The free operad on the terminal collection has, as its space of $n$-ary operations, the set of planar rooted trees having some of their leaves labelled $\{1, \dots, n\}$.

Calling them ‘conjectures’ makes it sound like they might be hard — but they’re not supposed to be hard. If they’re right, they should be easy and in some sense well-known! But there are various slightly different concepts of ‘rooted tree’ and ‘rooted planar tree’, and we have to get the details right to make these conjectures true. For example, a graph theorist might draw a rooted planar tree like this:

while an operad theorist might draw it like this:

If the conjectures are right, we can use them to define the concepts of ‘rooted tree’ and ‘rooted planar tree’, thus side-stepping these details. And having purely operad-theoretic definitions of ‘tree’ and ‘rooted tree’ would make it a lot easier to use these concepts in operad theory. That’s what I want to do, ultimately. But proving these conjectures, and of course providing the precise definitions of ‘rooted tree’ and ‘rooted planar tree’ that make them true, would still be very nice.

And it would be even nicer if someone had already done this. So please provide references… and/or correct mistakes in the following stuff!

Rooted Trees

Definition. For any natural number $n = 0, 1, 2, \dots$, an $n$-tree is a quadruple $T=(V,E,s,t)$ where:

• $V$ is a finite set whose elements are called internal vertices;
• $E$ is a finite non-empty set whose elements are called edges;
• $s: E \to V\sqcup \{1,\dots, n\}$ and $t: E \to V \sqcup\{0\}$ are maps sending any edge to its source and target, respectively.

Given $u,v\in V \sqcup\{0\} \sqcup \{1,\dots, n\}$, we write $u \stackrel{e}{\longrightarrow} v$ if $e\in E$ is an edge such that $s(e)=u$ and $t(e)=v$.

This data is required to satisfy the following conditions:

• $s : E \to V\sqcup \{1,\dots, n\}$ is a bijection;
• there exists exactly one $e\in E$ such that $t(e)=0$;
• for any $v \in V\sqcup\{1,\dots , n\}$ there exists a directed edge path from $v$ to $0$: that is, a sequence of edges $e_0, \dots, e_n$ and vertices $v_1 , \dots , v_n$ such that $$v \stackrel{e_0}{\longrightarrow} v_1 , \; v_1 \stackrel{e_1}{\longrightarrow} v_2, \; \dots, \; v_n \stackrel{e_n}{\longrightarrow} 0 .$$

So the idea is that our tree has $V \sqcup\{0\} \sqcup \{1,\dots, n\}$ as its set of vertices. There could be lots of leaves, but we’ve labelled some of them by numbers $1, \dots, n$. In our pictures, the source of each edge is at its top, while the target is at bottom.

There is a root, called $0$, but also a ‘pre-root’: the unique vertex with an edge going from it to $0$. I’m not sure I like this last bit, and we might be able to eliminate this redundancy, but it’s built into the operad theorist’s picture here:

It might be a purely esthetic issue. Like everything else, it gets a bit more scary when we consider degenerate special cases.

I’m hoping there’s an operad $Tree$ whose set of $n$-ary operations, $Tree_n$, consists of isomorphism classes of $n$-trees as defined above. I’m hoping someone has already proved this. And I hope someone has characterized this operad $Tree$ in a more algebraic way, as follows.

Definition. A symmetric collection $C$ consists of topological spaces $\{C_n\}_{n \ge 0}$ together with a continuous action of the symmetric group $S_n$ on each space $C_n$. A morphism of symmetric collections $f : C \to C'$ consists of an $S_n$-equivariant continuous map $f_n : C_n \to C'_n$ for each $n \ge 0$. Symmetric collections and morphisms between them form a category ${STop}$.

(More concisely, if we denote the groupoid of sets of the $\{1, \dots, n\}$ and bijections between these as $S$, then $STop$ is the category of functors from $S$ to $Top$.)

There is a forgetful functor from operads to symmetric collections

$$U : Op \to STop$$

with a left adjoint

$$F: STop \to Op$$

assigning to each symmetric collection the operad freely generated by it.

Definition. Let $Comm$ be the terminal operad: that is, the operad, unique up to isomorphism, such that $Comm_n$ is a 1-element set for each $n \ge 0$.

The algebras of $\Comm$ are commutative topological monoids.

Conjecture 1. There is a unique isomorphism of operads

$$\phi : F (U (Comm)) \stackrel{\sim}{\longrightarrow} Tree$$

that for each $n \ge 0$ sends the unique $n$-ary operation in $Comm$ to the corolla with $n$ leaves: that is, the isomorphism class of $n$-trees with no internal vertices.

(When I say “the unique $n$-ary operation in $Comm$”, but treating it as an operation in $F(U(Comm))$, I’m using the fact that the unique operation in $\Comm_n$ gives an element in $U(\Comm)_n$, and thus an operation in $F(U(\Comm))_n$.)

Planar Rooted Trees

And there should be a similar result relating planar rooted trees to collections without symmetric group actions!

Definition. A planar $n$-tree is an $n$-tree in which each internal vertex $v$ is equipped with a linear order on the set of its children, i.e. the set $t^{-1}(v)$.

I’m hoping someone has constructed an operad $PTree$ whose set of $n$-ary operations, $PTree_n$, consists of isomorphism classes of planar $n$-trees. And I hope someone has characterized this operad $PTree$ as follows:

Definition. A collection $C$ consists of topological spaces $\{C_n\}_{n \ge 0}$. A morphism of collections $f :C \to C'$ consists of a continuous map $f_n : C_n \to C'_n$ for each $n \ge 0$. Collections and morphisms between them form a category $\mathbb{N}Top$.

(If we denote the category with natural numbers as objects and only identity morphisms between as $\mathbb{N}$, then $\mathbb{N}Top$ is the category of functors from $\mathbb{N}$ to $Top$.)

There is a forgetful functor

$$\Upsilon : Op \to \mathbb{N}Top$$

with a left adjoint

$$\Phi : \mathbb{N}Top \to Op$$

assigning to each collection the operad freely generated by it. This left adjoint is the composite

$$\mathbb{N}Top \stackrel{G}{\longrightarrow} STop \stackrel{F}{\longrightarrow} Op$$

where the first functor freely creates a symmetric collection $G(C)$ from a collection $C$ by setting $G(C)_n = S_n \times C_n$, and the second freely generates an operad from a symmetric collection, as described above.

Conjecture 2. There is a unique isomorphism of operads

$$\psi : \Phi(\Upsilon (Comm)) \stackrel{\sim}{\longrightarrow} PTree$$

that for each $n \ge 0$ sends the unique $n$-ary operation in $Comm$ to the corolla with $n$ leaves ordered so that $1 &lt; \cdots &lt; n$.

Have you seen a proof of this stuff???

As the academic year winds to a close, scientists’ thoughts turn towards all of the warm-weather travel ahead (in order to avoid thinking about exam marking). Mostly, that means attending scientific conferences, like the upcoming IAU Symposium, Statistical Challenges in 21st Century Cosmology in Lisbon next month, and (for me and my collaborators) the usual series of meetings to prepare for the 2014 release of Planck data. But there are also opportunities for us to interact with people outside of our technical fields: public lectures and festivals.

Next month, parallel to the famous Hay Festival of Literature & the Arts, the town of Hay-on-Wye also hosts How The Light Gets In, concentrating on the also-important disciplines of philosophy and music, with a strong strand of science thrown in. This year, along with comic book writer Warren Ellis, cringe-inducing politicians like Michael Howard and George Galloway, ubiquitous semi-intellectuals like Joan Bakewell, there will be quite a few scientists, with a skew towards the crowd-friendly and controversial. I’m not sure that I want to hear Rupert Sheldrake talk about the efficacy of science and the scientific method, although it might be interesting to hear Julian Barbour, Huw Price, and Lee Smolin talk about the arrow of time. Some of the descriptions are inscrutable enough to pique my interest: Nancy Cartwright and George Ellis will discuss “Ultimate Proof” — I can’t quite figure out if that means physics or epistemology. Perhaps similarly, chemist Peter Atkins will ask “Can science explain all of existence” (and apparently answer in the affirmative). Closer to my own wheelhouse, Roger Penrose, Laura Mersini-Houghton, and John Ellis will discuss whether it is “just possible the Big Bang will turn out to be a mistake”. Penrose was and is one of the smartest people to work out the consequences of Einstein’s general theory of relativity, though in the last few years his cosmological musings have proven to be, well, just plain wrong — but, as I said, controversial and crowd-pleasing… (Disclosure: someone from the festival called me up and asked me to write about it here.)

Alas, I’ll likely be in Lisbon, instead of Hay. But if you want to hear me speak, you can make your way up North to Grantham, where Isaac Newton was educated, for this year’s Gravity Fields festival in late September. The line-up isn’t set yet, but I’ll be there, as will my fellow astronomers Chris Lintott and Catherine Heymans and particle physicist Val Gibson, alongside musicians, dancers, and lots of opportunities to explore the wilds of Lincolnshire. Or if you want to see me before then (and prefer to stay in London), you can come to Imperial for my much-delayed Inaugural Professorial Lecture on May 21, details TBC…

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I spoke with Kathryn Johnston's group by phone for a long time at midday, about the meeting last week at Oxford. I opined that "the competition" is going to stick with integrable orbits for a while, so we can occupy the niche of more general potentials and orbit families. We discussed at some length the disagreement between Sanders (Oxford) and Bovy about how and why streams are different from orbits. Towards the end of that meeting, we discussed Price-Whelan's PhD projects, which he wants to include a balance of theory and real-data inference. I argued strongly that Price-Whelan should follow the Branimir Sesar (MPIA) "plan" which is to fit all the known streams and use those fits to figure out what observations are most crucial to do next. Plus maybe some theory.

In the afternoon, Foreman-Mackey and I discussed figures and content for his "gamma-Earth" paper (not "eta-Earth" but "gamma-Earth"). We decided to choose a fiducial model, work that through completely, and show all the other things we know as adjustments to that fiducial model. We also discussed how to show everything on one big figure (which would be great, for talks and the paper). Foreman-Mackey told me that the Tremaine papers on planet occurrence get the likelihood function for the variable-rate Poisson problem correct (including overall normalization); our only "advances" relative to the Tremaine papers are that we have a more flexible functional form for the rate function and its prior, and we fully account for the observational uncertainties (which basically no-one knows how to do at this point).

There’s a lot of panic going around on the internet today, about something called the Heartbleed bug. I’ve gotten questions, so I’m giving answers.

I’ve heard lots of hype. Is this really a big deal?

Damn right it is!

It’s pretty hard to wrap your head around just how bad this actually is. It’s probably even more of a big deal that the hype has made it out to be!

This bug affects around 90% of all sites on the internet that use secure connections. Seriously: if you’re using the internet, you’re affected by this. It doesn’t matter how reputable or secure the sites you connect to have been in the past: the majority of them are probably vulnerable to this, and some number of them have, in all likelihood, been compromised! Pretty much any website running on linux or netbst, using Apache or NGINX as its webserver is vulnerable. That means just about every major site on the net.

The problem is a bug in a commonly used version of SSL/TLS. So, before I explain what the bug is, I’ll run through a quick background.

What is SSL/TLS?

When you’re using the internet in the simplest mode, you’re using a simple set of communication protocols called TCP/IP. In basic TCP/IP protocols, when you connect to another computer on the network, the data that gets sent back and forth is not encrypted or obscured – it’s just sent in the clear. That means that it’s easy for anyone who’s on the same network cable as you to look at your connection, and see the data.

For lots of things, that’s fine. For example, if you want to read this blog, there’s nothing confidential about it. Everyone who reads the blog sees the same content. No one is going to see anything private.

But for a lot of other things, that’s not true. You probably don’t want someone to be able to see your email. You definitely don’t want anyone else to be able to see the credit card number you use to order things from Amazon!

To protect communications, there’s another protocol called SSL, the Secure Sockets Layer. When you connect to another site that’s got a URL starting with https:, the two computers establish an encrypted connection. Once an SSL connection is established between two computers, all communication between them is encrypted.

Actually, on most modern systems, you’re not really using SSL. You’re using a successor to the original SSL protocol called TLS, which stands for transport layer security. Pretty much everyone is now using TLS, but many people still just say SSL, and in fact the most commonly used implementation of it is in package called OpenSSL.

So SSL/TLS is the basic protocol that we use on the internet for secure communications. If you use SSL/TLS correctly, then the information that you send and receive can only be accessed by you and the computer that you’re talking to.

Note the qualifier: if you use SSL correctly!

SSL is built on public key cryptography. What that means is that a website identifies itself using a pair of keys. There’s one key, called a public key, that it gives away to everyone; and there’s a second key, called a private key, that it keeps secret. Anything that you encrypt with the public key can only be decrypted using the private key; anything encrypted with the private key can only be decrypted using the public key. That means that if you get a message that can be decrypted using the sites public key, you know that no one except the site could have encrypted it! And if you use the public key to encrypt something, you know that no one except that site will be able to decrypt it.

Public key cryptography is an absolutely brilliant idea. But it relies on the fact that the private key is absolutely private! If anyone else can get a copy of the private key, then all bets are off: you can no longer rely on anything about that key. You couldn’t be sure that messages came from the right source; and you couldn’t be sure that your messages could only be read by an authorized person.

So what’s the bug?

The SSL protocol includes something called a heartbeat. It’s a periodic exchange between the two sides of a connection, to let them know that the other side is still alive and listening on the connection.

One of the options in the heartbeat is an echo request, which is illustrated below. Computer A wants to know if B is listening. So A sends a message to B saying “Here’s X bytes of data. Send them back to me.” Then A waits. If it gets a message back from B containing the same X bytes of data, it knows B was listening. That’s all there is to it: the heartbeat is just a simple way to check that the other side is actually listening to what you say.

The bug is really, really simple. The attacker sends a heartbeat message saying “I’m gonna send you a chunk of data containing 64000 bytes”, but then the data only contains one byte.

If the code worked correctly, it would say “Oops, invalid request: you said you were going to send me 64000 bytes of data, but you only sent me one!” But what the buggy version of SSL does is send you that 1 byte, plus 63,999 bytes of whatever happens to be in memory next to wherever it saved the byte..

You can’t choose what data you’re going to get in response. It’ll just be a bunch of whatever happened to be in memory. But you can do it repeatedly, and get lots of different memory chunks. If you know how the SSL implementation works, you can scan those memory chunks, and look for particular data structures – like private keys, or cookies. Given a lot of time, and the ability to connect multiple times and send multiple heartbeat requests each time you connect, you can gather a lot of data. Most of it will be crap, but some of it will be the valuable stuff.

To make matters worse, the heartbeat is treated as something very low-level which happens very frequently, and which doesn’t transfer meaningful data. So the implementation doesn’t log heartbeats at all. So there’s no way of even identifying which connections to a server have been exploiting this. So a site that’s running one of the buggy versions of OpenSSL has no way of knowing whether or not they’ve been the target of this attack!

See what I mean about it being a big deal?

Why is it so widespread?

When I’ve written about security in the past, one of the things that I’ve said repeatedly is: if you’re thinking about writing your own implementation of a security protocol, STOP. Don’t do it! There are a thousand ways that you can make a tiny, trivial mistake which completely compromises the security of your code. It’s not a matter of whether you’re smart or not; it’s just a simple statement of fact. If you try to do it, you will screw something up. There are just so many subtle ways to get things wrong: it takes a whole team of experts to even have a chance to get it right.

Most engineers who build stuff for the internet understand that, and don’t write their own cryptosystems or cryptographic protocols. What they do is use a common, well-known, public system. They know the system was implemented by experts; they know that there are a lot of responsible, smart people who are doing their best to find and fix any problems that crop up.

Imagine that you’re an engineer picking an implementation of SSL. You know that you want as many people trying to find problems as possible. So which one will you choose? The one that most people are using! Because that’s the one that has the most people working to make sure it doesn’t have any problems, or to fix any problems that get found as quickly as possible.

The most widely used version of SSL is an open-source software package called OpenSSL. And that’s exactly where the most bug is: in OpenSSL.

How can it be fixed?

Normally, something like this would be bad. But you’d be able to just update the implementation to a new version without the bug, and that would be the end of the problem. But this case is pretty much the worst possible case: fixing the implementation doesn’t entirely fix the problem. Because even after you’ve fixed the SSL implementation, if someone got hold of your private key, they still have it. And there’s no way to know if anyone stole your key!

To fix this, then, you need to do much more than just update the SSL implementation. You need to cancel all of your keys, and replace them new ones, and you need to get everyone who has a copy of your public key to throw it away and stop using it.

So basically, at the moment, every keypair for nearly every major website in the world that was valid yesterday can no longer be trusted.

Chaotic Awesome is a webseries hosted by Chloe Dykstra and Michele Morrow, generally focused on all things geeky, such as gaming and technology. But the good influence of correspondent Christina Ochoa ensures that there is also a healthy dose of real science on the show. It was a perfect venue for Jennifer Ouellette — science writer extraordinaire, as well as beloved spouse of your humble blogger — to talk about her latest masterwork, Me, Myself, and Why: Searching for the Science of Self.

Jennifer’s book runs the gamut from the role of genes in forming personality to the nature of consciousness as an emergent phenomenon. But it also fits very naturally into a discussion of gaming, since our brains tend to identify very strongly with avatars that represent us in virtual spaces. (My favorite example is Jaron Lanier’s virtual lobster — the homuncular body map inside our brain is flexible enough to “grow new limbs” when an avatar takes a dramatically non-human form.) And just for fun for the sake of scientific research, Jennifer and her husband tried out some psychoactive substances that affect the self/other boundary in a profound way. I’m mostly a theorist, myself, but willing to collect data when it’s absolutely necessary.

It was the summer of 2008. I was 22 years old, and it was my second week working in the crude oil and natural gas options pit at the New York Mercantile Exchange (NYMEX.) My head was throbbing after two consecutive weeks of disorientation. It was like being born into a new world, but without the neuroplasticity of a young human. And then the crowd erupted. “Yeeeehawwww. YeEEEeeHaaaWWWWW. Go get ‘em cowboy.”

It seemed that everyone on the sprawling trading floor had started playing Wild Wild West and I had no idea why. After at least thirty seconds, the hollers started to move across the trading floor. They moved away 100 meters or so and then doubled back towards me. After a few meters, he finally got it, and I’m sure he learned a life lesson. Don’t be the biggest jerk in a room filled with traders, and especially, never wear triple-popped pastel-colored Lacoste shirts. This young aspiring trader had been “spurred.”

In other words, someone had made paper spurs out of trading receipts and taped them to his shoes. Go get ‘em cowboy.

I was one academic quarter away from finishing a master’s degree in statistics at Stanford University and I had accepted a full time job working in the algorithmic trading group at DRW Trading. I was doing a summer internship before finishing my degree, and after three months of working in the algorithmic trading group in Chicago, I had volunteered to work at the NYMEX. Most ‘algo’ traders didn’t want this job, because it was far-removed from our mental mathematical monasteries, but I knew I would learn a tremendous amount, so I jumped at the opportunity. And by learn, I mean, get ripped calves and triceps, because my job was to stand in place for seven straight hours updating our mathematical models on a bulky tablet PC as trades occurred.

I have no vested interests in the world of high-frequency trading (HFT). I’m currently a PhD student in the quantum information group at Caltech and I have no intentions of returning to finance. I found the work enjoyable, but not as thrilling as thinking about the beginning of the universe (what else is?) However, I do feel like the current discussion about HFT is lop-sided and I’m hoping that I can broaden the perspective by telling a few short stories.

What are the main attacks against HFT? Three of them include the evilness of: front-running markets, making money out of nothing, and instability. It’s easy to point to extreme examples of algorithmic traders abusing markets, and they regularly do, but my argument is that HFT has simply computerized age-old tactics. In this process, these tactics have become more benign and markets more stable.

Front-running markets: large oil producing nations, such as Mexico, often want to hedge their exposure to changing market prices. They do this by purchasing options. This allows them to lock in a minimum sale price, for a fee of a few dollars per barrel. During my time at the NYMEX, I distinctly remember a broker shouting into the pit: “what’s the price on DEC9 puts.” A trader doesn’t want to give away whether they want to buy or sell, because if the other traders know, then they can artificially move the price. In this particular case, this broker was known to sometimes implement parts of Mexico’s oil hedge. The other traders in the pit suspected this was a trade for Mexico because of his anxious tone, some recent geopolitical news, and the expiration date of these options.

Some confident traders took a risk and faded the market. They ended up making between $1-2 million dollars from these trades, relative to what the fair price was at that moment. I mention relative to the fair price, because Mexico ultimately received the better end of this trade. The price of oil dropped in 2009, and Mexico executed its options enabling it to sell its oil at a higher than market price. Mexico spent $1.5 billion to hedge its oil exposure in 2009.

This was an example of humans anticipating the direction of a trade and capturing millions of dollars in profit as a result. It really is profit as long as the traders can redistribute their exposure at the ‘fair’ market price before markets move too far. The analogous strategy in HFT is called “front-running the market” which was highlighted in the New York Times’ recent article “the wolf hunters of Wall Street.” The HFT version involves analyzing the prices on dozens of exchanges simultaneously, and once an order is published in the order book of one exchange, then using this demand to adjust its orders on the other exchanges. This needs to be done within a few microseconds in order to be successful. This is the computerized version of anticipating demand and fading prices accordingly. These tactics as I described them are in a grey area, but they rapidly become illegal.

Making money from nothing: arbitrage opportunities have existed for as long as humans have been trading. I’m sure an ancient trader received quite the rush when he realized for the first time that he could buy gold in one marketplace and then sell it in another, for a profit. This is only worth the trader’s efforts if he makes a profit after all expenses have been taken into consideration. One of the simplest examples in modern terms is called triangle arbitrage, and it usually involves three pairs of currencies. Currency pairs are ratios; such as USD/AUD, which tells you, how many Australian dollars you receive for one US dollar. Imagine that there is a moment in time when the product of ratios is 1.01. Then, a trader can take her USD, buy AUD, then use her AUD to buy CAD, and then use her CAD to buy USD. As long as the underlying prices didn’t change while she carried out these three trades, she would capture one cent of profit per trade.

After a few trades like this, the prices will equilibrate and the ratio will be restored to one. This is an example of “making money out of nothing.” Clever people have been trading on arbitrage since ancient times and it is a fundamental source of liquidity. It guarantees that the price you pay in Sydney is the same as the price you pay in New York. It also means that if you’re willing to overpay by a penny per share, then you’re guaranteed a computer will find this opportunity and your order will be filled immediately. The main difference now is that once a computer has been programmed to look for a certain type of arbitrage, then the human mind can no longer compete. This is one of the original arenas where the term “high-frequency” was used. Whoever has the fastest machines, is the one who will capture the profit.

Instability: I believe that the arguments against HFT of this type have the most credibility. The concern here is that exceptional leverage creates opportunity for catastrophe. Imaginations ran wild after the Flash Crash of 2010, and even if imaginations outstripped reality, we learned much about the potential instabilities of HFT. A few questions were posed, and we are still debating the answers. What happens if market makers stop trading in unison? What happens if a programming error leads to billions of dollars in mistaken trades? Do feedback loops between algo strategies lead to artificial prices? These are reasonable questions, which are grounded in examples, and future regulation coupled with monitoring should add stability where it’s feasible.

The culture in wealth driven industries today is appalling. However, it’s no worse in HFT than in finance more broadly and many other industries. It’s important that we dissociate our disgust in a broad culture of greed from debates about the merit of HFT. Black boxes are easy targets for blame because they don’t defend themselves. But that doesn’t mean they aren’t useful when implemented properly.

Are we better off with HFT? I’d argue a resounding yes. The primary function of markets is to allocate capital efficiently. Three of the strongest measures of the efficacy of markets lie in “bid-ask” spreads, volume and volatility. If spreads are low and volume is high, then participants are essentially guaranteed access to capital at as close to the “fair price” as possible. There is huge academic literature on how HFT has impacted spreads and volume but the majority of it indicates that spreads have lowered and volume has increased. However, as alluded to above, all of these points are subtle–but in my opinion, it’s clear that HFT has increased the efficiency of markets (it turns out that computers can sometimes be helpful.) Estimates of HFT’s impact on volatility haven’t been nearly as favorable but I’d also argue these studies are more debatable. Basically, correlation is not causation, and it just so happens that our rapidly developing world is probably more volatile than the pre-HFT world of the last Millennia.

We could regulate away HFT, but we wouldn’t be able to get rid of the underlying problems people point to unless we got rid of markets altogether. As with any new industry, there are aspects of HFT that should be better monitored and regulated, but we should have level-heads and diverse data points as we continue this discussion. As with most important problems, I believe the ultimate solution here lies in educating the public. Or in other words, this is my plug for Python classes for all children!!

I promise that I’ll repent by writing something that involves actual quantum things within the next two weeks!

In a low-research day, I saw two absolutely excellent seminars. The first was Alexander Rush (MIT, Columbia) talking about methods for finding the optimal parsing or syntactical structure for a natural-language sentence using lagrangian relaxation. The point is that the number of parsings is combinatorially large, so you have to do clever things to find good ones. He also looked at machine translation, which is a very related problem. At the end of his talk he discussed extraction of structured information from unstructured text, which might be applicable to the scientific literature.

Over lunch, Sergei Dubovsky (NYU) spoke about massive graviton theories and the recent BICEP2 results. He started by explaining that there are non-pathological gravity modifications in which the graviton is massive in its tensor effects, but doesn't get messed up in its scalar and vector effects. This means you have no change to the "force law" as it were (nor the black-hole solutions nor the cosmological world model) but you modify gravitational radiation. He then said two amazing things: The first is that the BICEP2 result, if it holds up, will put the strongest ever bound on the graviton mass, because it means that gravitational radiation propagated a significant fraction of a Hubble length. The second is that the BICEP2 data are better fit by a model with a tiny but nonzero graviton mass than by the standard massless theory. That's insane! But of course early days and much skepticism about the data, let alone the theory. Great talks today!

To me the very purpose of research is making science increasingly harder. If you don’t want to improve on predictive power, what’s the point of science to begin with? The social sciences are soft mainly because data that quantifies the behavior of social, political, and economic systems is hard to come by: it’s huge amounts, difficult to obtain and even more difficult to handle. Historically, these research areas therefore worked with narratives relating plausible causal relations. Needless to say, as computing power skyrockets, increasingly larger data sets can be handled. So the social sciences are finally on the track to become useful. Or so you’d think if you’re a physicist.

1. People are too difficult. You can’t predict them.
   
   Humans are made of a many elementary particles and even though you don’t have to know the exact motion of every single one of these particles, a person still has an awful lot of degrees of freedom and needs to be described by a lot of parameters. That’s a complicated way of saying people can do more things than electrons, and it isn’t always clear exactly why they do what they do.
   
   That is correct of course, but this objection fails to take into account that not all possible courses of action are always relevant. If it was true that people have too many possible ways to act to gather any useful knowledge about their behavior our world would be entirely dysfunctional. Our societies work only because people are to a large degree predictable.
   
   If you go shopping you expect certain behaviors of other people. You expect them to be dressed, you expect them to walk forwards, you expect them to read labels and put things into a cart. There, I’ve made a prediction about human behavior! Yawn, you say, I could have told you that. Sure you could, because making predictions about other people’s behavior is pretty much what we do all day. Modeling social systems is just a scientific version of this.
   
   This objection that people are just too complicated is also weak because, as a matter of fact, humans can and have been modeled with quite simple systems. This is particularly effective in situations when intuitive reaction trumps conscious deliberation. Existing examples are traffic flows or the density of crowds when they have to pass through narrow passages.
   
   So, yes, people are difficult and they can do strange things, more things than any model can presently capture. But modeling a system is always an oversimplification. The only way to find out whether that simplification works is to actually test it with data.
   
   
2. People have free will. You cannot predict what they will do.
   
   To begin with it is highly questionable that people have free will. But leaving this aside for a moment, this objection confuses the predictability of individual behavior with the statistical trend of large numbers of people. Maybe you don’t feel like going to work tomorrow, but most people will go. Maybe you like to take walks in the pouring rain, but most people don’t. The existence of free will is in no conflict with discovering correlations between certain types of behavior or preferences in groups. It’s the same difference that doesn’t allow you to tell when your children will speak the first word or make the first step, but that almost certainly by the age of three they’ll have mastered it.
   
   
3. People can understand the models and this knowledge makes predictions useless.
   
   This objection always stuns me. If that was true, why then isn’t obesity cured by telling people it will remain a problem? Why are the highways still clogged at 5pm if I predict they will be clogged? Why will people drink more beer if it’s free even though they know it’s free to make them drink more? Because the fact that a prediction exists in most cases doesn’t constitute any good reason to change behavior. I can predict that you will almost certainly still be alive when you finish reading this blogpost because I know this prediction is exceedingly unlikely to make you want to prove it wrong.
   
   Yes, there are cases when people’s knowledge of a prediction changes their behavior – self-fulfilling prophecies are the best-known examples of this. But this is the exception rather than the rule. In an earlier blogpost, I referred to this as societal fixed points. These are configurations in which the backreaction of the model into the system does not change the prediction. The simplest example is a model whose predictions few people know or care about.
   
   
4. Effects don’t scale and don’t transfer.
   
   This objection is the most subtle one. It posits that the social sciences aren’t really sciences until you can do and reproduce the outcome of “experiments”, which may be designed or naturally occurring. The typical social experiment that lends itself to analysis will be in relatively small and well-controlled communities (say, testing the implementation of a new policy). But then you have to extrapolate from this how the results will be in larger and potentially very different communities. Increasing the size of the system might bring in entirely new effects that you didn’t even know of (doesn’t scale), and there are a lot of cultural variables that your experimental outcome might have depended on that you didn’t know of and thus cannot adjust for (doesn’t transfer). As a consequence, repeating the experiment elsewhere will not reproduce the outcome.
   
   Indeed, this is likely to happen and I think it is the major challenge in this type of research. For complex relations it will take a long time to identify the relevant environmental parameters and to learn how to account for their variation. The more parameters there are and the more relevant they are, the less the predictive value of a model will be. If there are too many parameters that have to be accounted for it basically means doing experiments is the only thing we can ever do. It seems plausible to me, even likely, that there are types of social behavior that fall into this category, and that will leave us with questions that we just cannot answer.
   
   However, whether or not a certain trend can or cannot be modeled we will only know by trying. We know that there are cases where it can be done. Geoffry West’s city theory I find a beautiful example where quite simple laws can be found in the midst of all these cultural and contextual differences.

Running around these days, doing some linear combination of actual work and talking about things. (Sometimes the talking leads to actual work, so it’s not a total loss.) If you happen to be in a sciencey kind of mood when I’m in your vicinity, feel free to come to a talk and say hi!

• Today, if you happen to be in Walla Walla, Washington, I’ll be giving the Brattain lecture at Whitman College, on the Higgs boson and the hunt therefor.
• Next week I’ll be in Austin, TX. On Thursday April 17, I’ll be speaking in the Distinguished Lecture Series, once again on the marvels of the Higgs.
• In May I’ll be headed to the Big Apple twice. The first time will be on May 7 for an Intelligence Squared Debate. The subject will be “Is There Life After Death?” I’ll be saying no, and Steven Novella will be along there with me; our opponents will be Eben Alexander and Raymond Moody.
• Then back home for a bit, and then back to NYC again, for the World Science Festival. I’ll be participating in a few events there between May 29 and 31, although precise spatio-temporal locations have yet to be completely determined. One will be about “Science and Story,” one will be a screening of Particle Fever, and one will be a book event.
• I won’t even have a chance to return home from NYC before jetting to the UK for the Cheltenham Science Festival. Once again, participating in a few different events, all on June 3/4: something on Science and Hollywood, something on the Higgs, and something on the arrow of time. Check local listings!
• A chance I will be in Oxford right after Cheltenham, but nothing’s settled yet.
• That’s it. Looking forward to a glorious summer full of real productivity.

Guest post by Sean Moss

In this post I shall discuss the paper “On a Topological Topos” by Peter Johnstone. The basic problem is that algebraic topology needs a “convenient category of spaces” in which to work: the category $\mathcal{T}$ of topological spaces has few good categorical properties beyond having all small limits and colimits. Ideally we would like a subcategory, containing most spaces of interest, which is at least cartesian closed, so that there is a useful notion of function space for any pair of objects. A popular choice for a “convenient category” is the full subcategory of $\mathcal{T}$ consisting of compactly-generated spaces. Another approach is to weaken the notion of topological space, i.e. to embed $\mathcal{T}$ into a larger category, hopefully with better categorical properties.

A topos is a category with enough good properties (including cartesian closedness) that it acts like the category of sets. Thus a topos acts like a mathematical universe with ‘sets’, ‘functions’ and its own internal logic for manipulating them. It is exciting to think that if a “convenient topos of spaces” could be found, then its logical aspects could be applied to the study of its objects. The set-like nature of toposes might make it seem unlikely that this can happen. For instance, every topos is balanced, but the category of topological spaces is famously not. However, sheaves (the objects in Grothendieck toposes) originate from geometry and already behave somewhat like generalized spaces.

I shall begin by elaborating on this observation about Grothendieck toposes, and briefly examine some previous attempts at a “topological topos”. I shall explore the idea of replacing open sets with convergent sequences and see how this leads us to Johnstone’s topos. Finally I shall describe how Johnstone’s topos is a good setting for homotopy theory.

I would to thank Emily Riehl for organizing the Kan Extension Seminar and for much useful feedback. Thanks go also to the other seminar participants for being a constant source of interesting perspectives, and to Peter Johnstone, for his advice and for writing this incredible paper.

Are there toposes of spaces?

We shall need to be flexible about what we mean by “space”. For the rest of this post I shall try to use the term “topological space” in a strict technical sense (a set of points plus specified open sets), whereas “space” will be a nebulous concept. The idea is that spaces have existence regardless of having been implemented as a topological space or not, and may naturally have more (or perhaps less) structure. Topology merely forms one setting for their rigorous study. In topology we can only detect the topological properties of spaces. For example, $\mathbb{R}$ and $(0,1)$ are isomorphic as topological spaces, but they are far from being the same space: consider how different their implementations as, say, metric spaces are. Some spaces are naturally considered as having algebraic or smooth structure. The type of question one wishes to ask about a space will bear upon the type of object as which it should be implemented.

An extremely important class of toposes consists of the Grothendieck toposes, which are categories of sheaves on a site. A site is a small category together with a Grothendieck coverage (also known as a Grothendieck topology). Informally, the Grothendieck coverage tells us how some objects can be “covered” by maps coming out of other objects. In the special case where the site is a topological space, the objects are open sets and the coverage tells us that an open set is covered by the inclusions of any family of open sets whose union is all of that open set. A sheaf on a site is then a contravariant $\mathrm{Set}$-valued functor on the underlying category (a presheaf) which satisfies a “unique patching” condition with respect to each covering sieve.

In the following two senses, a Grothendieck topos always behaves like a category of spaces:

(A) One way to describe the properties of a space is to consider the maps into that space. This is the idea behind the homotopy groups, where we consider (homotopy classes of) maps from the $n$-sphere into a space. Given a small category $\mathcal{C}$, each object is determined by knowing all the arrows into it and how these arrows “restrict” along other arrows, i.e. precisely the data of the representable presheaf. A non-representable presheaf can be viewed as a generalized object of $\mathcal{C}$, which is testable by the ‘classical’ objects of $\mathcal{C}$: it is described entirely by what the maps into it from objects of $\mathcal{C}$ ought to be. If we have in mind that $\mathcal{C}$ is some category of spaces, with some sense in which some spaces are covered by families of maps out of other spaces, (i.e. we have a Grothendieck coverage), then we should be able to patch maps into these generalized spaces together. So the topos of sheaves on this site is a setting in which we may be able to implement certain spaces, if we wish to study their properties testable by objects of $\mathcal{C}$.

(B) The category of presheaves on a small category $\mathcal{C}$ is its free cocompletion. Intuitively, it is the category of objects obtained by formally gluing together objects of $\mathcal{C}$. The use of the word “gluing” is itself a spatial metaphor. CW-complexes are built out of gluing together cells - simplicial sets are instructions for carrying out this gluing. Manifolds are built from gluing together open subsets of Euclidean space. Purely formal ‘gluing’ is not quite sufficient: the Yoneda embedding of $\mathcal{C}$ into its presheaves typically does not preserve any colimits already in $\mathcal{C}$. But if $\mathcal{C}$ is a category of spaces, its objects are not neutral with respect to each other: there may be a suitable Grothendieck coverage on $\mathcal{C}$ which tells us how some objects can cover others. The topos of sheaves is then the category of objects obtained by formally gluing objects of $\mathcal{C}$ in a way that respects these coverings. This is strongly connected with the preservation of colimits by the embedding of $\mathcal{C}$ into the sheaves. Colimits in the presheaf topos are constructed pointwise; to get the sheaf colimit one applies the reflection into the category of sheaves (“sheafification”) to the presheaf colimit. The more covers imposed on $\mathcal{C}$, the more work is done by the sheafification, so the closer we end up to the original colimit.

Are there toposes in topology?

It is far from clear that we can choose a site for which the space-like behaviour of sheaves accords with the usual topological intuition. If we want to use a topological topos for homotopy theory, then ideally it should contain objects that we can recognize as the CW-complexes, and we should be able to construct them via more or less the usual colimits.

Attempt 1: The “gros topos” of Giraud

The idea is to take sheaves on the ‘site’ of topological spaces, where covers are given by families of open inclusions of subspaces whose union is the whole space. We do not automatically get a topos unless the site is small, so instead take some small, full subcategory $\mathcal{C}$ of $\mathcal{T}$, which is closed under open subspaces. The gros topos is the topos of sheaves for this site.

The Yoneda embedding exhibits $\mathcal{C}$ as a subcategory, and in fact we can ‘embed’ $\mathcal{T}$ via the functor $X \mapsto \hom_\mathcal{T}(-,X)$, this will be full and faithful on a fairly large subcategory. By (B) one may like to consider the gros topos as the category of spaces glued together from objects of $\mathcal{C}$. This turns out not to be useful, since the site does not have enough covers for colimits to agree with those in $\mathcal{T}$. Moreover the site is so large that calculations are difficult.

Attempt 2: Lawvere’s topos

We use observation (A). Motivated by the use of paths in homotopy theory, we take $M$ to be the full subcategory of $\mathcal{T}$ whose only object is the closed unit interval $I$. So $M$ is the monoid of continuous endomorphisms of $I$. Lawvere’s topos $\mathcal{L}$ is the topos of sheaves on $M$ with respect to the canonical Grothendieck coverage (the largest Grothendieck coverage on $M$ for which $\hom_M(-,I)$ is a sheaf).

Then an object $X$ of $\mathcal{L}$ is a set $X(I)$ of paths, together with, for any continuous $\gamma\colon I \to I$, a reparametrization map $X(\gamma) \colon X(I) \to X(I)$, where this assignment is functorial. The points of such a space are given by natural transformations $1 \to X$, i.e. ‘constant paths’ or paths which are fixed by every reparametrization. We can see which point a path visits at time $t$ by reparametrizing that path by the constant map $I \to I$ with value $t$. A word of caution: a given object in $\mathcal{L}$ may have distinct paths which agree on points for all time.

This site is much easier to calculate with than the gros site (once we have a handle on the canonical coverage). Again there is a functor $P \colon \mathcal{T} \to \mathcal{L}$ given by $X \mapsto \hom_\mathcal{T}(I,X)$, which is full and faithful on a fairly large subcategory (including CW-complexes). However, it is still the case that the site could do with more covers: the functor $P$ does not preserve all the colimits used to build up CW-complexes. By observation (B), an object of $\mathcal{L}$ is obtained by gluing together copies of the unit interval $I$, so it is possible to construct the circle $S^1$ out of copies of $I$, but we cannot do this in the usual way. The coequalizer of $I$ by its endpoints in $\mathcal{L}$ is not $S^1$, but a “signet-ring”: it is a circle with a ‘lump’, through which a path can cross only if waits there for non-zero time. We cannot solve this problem by adding in more covers, because the coverage is already canonical (adding in more covers will evict the representable $\hom_\mathcal{T}(-,I)$ from the topos).

The key idea in Johnstone’s topos is to replace paths with convergent sequences. Given a topological space $X$, a convergent sequence in $X$ is a function from $a \colon \mathbb{N}\cup\{\infty\} \to X$ such that whenever $U \subseteq X$ is an open set containing $a_\infty$, then there exists an $N$ such that $a_n \in U$ for all $n \gt N$. The convergent sequences are precisely the continuous maps out of $\mathbb{N}\cup\{\infty\}$ when we give it the topology that makes it the one-point compactification of the discrete space $\mathbb{N}$ - we denote this topological space by $\mathbb{N}^+$.

Convergent sequences as primitive

It is a basic theorem in general topology that, given a function $f\colon X \to Y$ between topological spaces, if it is continuous then it preserves convergent sequences. The converse is not true for general topological spaces, but it is true whenever $Y$ is a sequential space. Given a topological space $X$, A set $U \subseteq X$ is sequentially open if for any convergent sequence $(a_n)$, with $a_\infty \in U$, $(a_n)$ is eventually in $U$. (Clearly any open subset is sequentially open.) A topological space is then said to be sequential if all of its sequentially open sets are open. The sequential spaces include all first-countable spaces and in fact they can be characterized as the topological quotients of metrizable spaces, so they certainly include all CW-complexes.

The notion of convergent sequence is arguably more intuitive than that of open set. For example, each convergent sequence gives you concrete data about the nearness of some family of points to another point, whereas open sets only give you such data when the topology (or at least a neighbourhood basis) is considered as a whole. It would be compelling to define a continuous function as one that preserves convergent sequences. This motivates the study of subsequential spaces.

A subsequential space consists of a set $X$ (of points) and family of “convergent sequences”: a specified subset of the set of functions $\mathbb{N}\cup\{\infty\} \to X$, such that:

1. for every point $x \in X$, the constant sequence $(x)$ converges to $x$;
2. if $(x_n)$ converges to $x$, then so does every subsequence of $(x_n)$;
3. if $(x_n)$ is a sequence and $x$ is a point such that every subsequence of $(x_n)$ contains a (sub)subsequence converging to $x$, then $(x_n)$ converges to $x$.

The third axiom is the general form of intertwining two or more sequences with the same limit or changing a finite initial segment of a sequence. Note that there is no ‘Hausdorff‘-style condition on the convergent sequences: a sequence may converge to more than one limit. A continuous map between subsequential spaces $X \to Y$ is a function from the points of $X$ to the points of $Y$ that preserves convergence of sequences.

The axioms above are all true of the set of convergent sequences which arise from a topology on a set. In fact, this process gives a full and faithful embedding of sequential spaces into subsequential spaces. Thus sequential spaces live inside both topological and subsequential spaces. They are coreflective in the former and reflective in the latter: given a topological space $X$, its sequentially open sets constitute a new (finer) topology; given a subsequential space $Y$, we can consider the “sequentially open” sets with respect to its convergent sequences, and then take all convergent sequences in the resulting (sequential) topological space. Observe that the sense of the adjunction in each case comes from the fact that we either throw in more open sets - so there is a natural map $(X)_\text{seq} \to X$, or throw in more convergent sequences - so there is a natural map $Y \to (Y)_\text{seq}$.

In the following I shall denote the category of sequential spaces by $\mathcal{F}$ and that of subsequential spaces by $\mathcal{F}'$.

Johnstone’s topos

Let $\Sigma$ be the full subcategory of $\mathcal{T}$ on the objects $1$ (the singleton space) and $\mathbb{N}^+$ (the one-point compactification of the discrete space of natural numbers). The arrows in this category can be described without topology as well: as functions, the maps $\mathbb{N}^+ \to \mathbb{N}^+$ are the eventually constant ones and the ones that “tend to infinity”.

Given an infinite subset $T \subseteq \mathbb{N}$, let $f_T$ denote the unique order-preserving injection $\mathbb{N}^+ \to \mathbb{N}^+$ whose image is $T \cup \{\infty\}$. One can check that there is a Grothendieck coverage $J$ on $\Sigma$ where $1$ is covered by only the maximal sieve, and where $\mathbb{N}^+$ is covered by any sieve $R$ such that:

1. $R$ contains all of the points $n \colon 1 \to \mathbb{N}^+$, $n \in \mathbb{N}^+$.
2. For any infinite subset $T \subseteq \mathbb{N}$ there exists an infinite subset $T' \subseteq T$ such that $f_{T'} \in R$.

The topos $\mathcal{E}$ is then defined to be $\mathrm{Sh}(\Sigma,J)$.

The objects in our topos are a slight generalization of subsequential space. If $X \in \mathcal{E}$, then $X(1)$ is its set of points, and $X(\mathbb{N}^+)$ is its set of convergent sequences. Each point $n \colon 1 \to \mathbb{N}^+$ induces a ‘projection map’ $X(n)\colon X(\mathbb{N}^+) \to X(1)$, giving you the point of the sequence at time $n$. The unique map $\mathbb{N}^+ \to 1$ induces a map $X(1) \to X(\mathbb{N}^+)$, which sends each point to a canonical choice of constant sequence. Note that there may be more than one convergent sequence with the same points, thus it may be helpful to think of $X(\mathbb{N}^+)$ as the set of proofs of convergence for sequences.

Clearly we can embed $\mathcal{F}'$, the subsequential spaces, into $\mathcal{E}$: the points are the same, and the convergence proofs are just the convergent sequences. The first two axioms are satisfied because of the equations that hold in $\Sigma$. The third axiom is encoded into the coverage. Conversely, any object $X$ of $\mathcal{E}$ for which the projection maps $X(n)\colon X(\mathbb{N}^+) \to X(1)$, $n \in \mathbb{N}^+$ are jointly injective is isomorphic to one coming from a subsequential space. There is a functor $H \colon \mathcal{T} \to \mathcal{E}$ sending $X \mapsto \hom_\mathcal{T}(-,X)$, and it is indeed sheaf-valued since it is equal to the composite of the coreflection $\mathcal{T} \to \mathcal{F}$ with the inclusions $\mathcal{F} \to \mathcal{F}' \to \mathcal{E}$. In fact, the Grothendieck coverage defining $\mathcal{E}$ is canonical, so it is the largest for which this functor is well-defined.

We can use observation (B) to think of $\mathcal{E}$ as all spaces constructed from gluing sequences together. It is just about possible that we could have motivated the construction of $\mathcal{E}$ this way: classically, any sequential space $X$ is the quotient in $\mathcal{T}$ of a metrizable space, which may be taken to be a disjoint union of copies of $\mathbb{N}^+$ - one for every convergent sequence in $X$. Compare this with the canonical representation of a presheaf as a colimit of representables (one for each of its elements).

Colimits

It turns out that $\mathcal{F}'$ is the subcategory of $\neg\neg$-separated objects in $\mathcal{E}$, hence it is a reflective subcategory. $\mathcal{F}$ is reflective in $\mathcal{F}'$, hence it is also reflective in $\mathcal{E}$. In particular, all limits in $\mathcal{F}$ are preserved by the inclusion into $\mathcal{E}$. Take some caution, however, since products do not agree with those in $\mathcal{T}$: one has to take the sequential coreflection of the topological product. This is only a minor issue; having to modify the product arises in other “convenient categories” such as compactly-generated spaces.

The colimits in $\mathcal{F}$ do agree with those in $\mathcal{T}$ because it is a coreflective subcategory. Surprisingly, the inclusion $\mathcal{F} \to \mathcal{E}$ preserves many of these colimits.

Theorem Let $X$ be a sequential space, and $\{U_\alpha \mid \alpha \in A\}$ an open cover of $X$. Then the obvious colimit diagram in $\mathcal{F}$: $$\begin{matrix} U_\alpha\cap U_\beta & \rightarrow & U_\alpha & & \\ & \searrow & & \searrow & \\ U_\beta \cap U_\gamma & \rightarrow & U_\beta & \rightarrow & X \\ \vdots & \searrow & & \nearrow & \\ & & U_\gamma & & \\ & & \vdots & & \end{matrix}$$ is preserved by the embedding $\mathcal{F} \to \mathcal{E}$.

Proof The recipe for this sort of theorem is: take the colimit in presheaves, show that the comparison map is monic, then show that it is $J$-dense, for then it will exhibit $X$ as the colimit upon reflecting into the topos $\mathcal{E}$. The colimit $L$ in presheaves is calculated “objectwise”, so $L$ has the same points of $X$, but only those convergent sequences which are entirely within some $U_\alpha$ (hence the comparison map $L \to X$ is monic). To sheafify, we need to add in all those sequences $x \in X(\mathbb{N}^+)$ which are locally in $L$, i.e. for which the sieve $$\{f \colon ? \to \mathbb{N}^+ \mid X(f)(x) \in L(?) \}$$ in $\Sigma$ is $J$-covering. For any $x \in X(\mathbb{N}^+)$, this sieve clearly contains all the points $1 \to \mathbb{N}^+$. But $x$ must also be eventually within one of the $U_\alpha$, so the second condition for the covering sieves is also satisfied. $\square$

There are several other colimit preservation results one can talk about (with similar proofs to the above). The amazing consequence of these is that the colimits used to construct CW-complexes are all preserved by the embedding $\mathcal{F} \to \mathcal{E}$. Thus classical homotopy theory embeds into $\mathcal{E}$ and we have successfully found a topos of spaces which agrees with the classical theory.

Geometric realization

Let $\Delta$ be the category of non-zero finite ordinals and order-preserving maps. Then objects of the presheaf category $[\Delta^\mathrm{op},\mathrm{Set}]$ are known as simplicial sets.

Theorem $[\Delta^\mathrm{op},\mathrm{Set}]$ is the classifying topos for intervals in $\mathrm{Set}$-toposes.

The closed unit interval $[0,1]$ is sequential and is in fact an interval (a totally ordered object with distinct top and bottom elements). Thus it corresponds to a geometric morphism $\mathcal{E} \to [\Delta^\mathrm{op},\mathrm{Set}]$ (an adjunction $(f^\star \dashv f_\star)$ with $f^\star$ left-exact).

Theorem If $S \in [\Delta^\mathrm{op},\mathrm{Set}]$ is a simplicial set, then $f^\star(S)$ is its geometric realization, considered as a sequential space and hence as an object of $\mathcal{E}$. If $X \in \mathcal{E}$ is a sequential space, then $f_\star(E)$ is its singular complex.

The usual geometric realization is not left-exact if considered to take values in $\mathcal{T}$, one must choose a “convenient subcategory” first, and then there is some work to do in proving it. Here the left-exactness just arises out of the general theory of geometric morphisms. Should we wish to do so, the above method allows us to replace $[0,1]$ with any other object that the internal logic of $\mathcal{E}$ sees as an interval to get a different realization of simplicial sets.

The above is far from a complete survey of “On a Topological Topos”, which contains several more results of interest relating to $\mathcal{E}$ and captures the elegance of using the site $\Sigma$ for calculation - I thoroughly recommend taking a look if you know some topos theory. We have seen enough though to understand that for many spaces the sequential properties align with the topological properties. Unfortunately, $\mathcal{E}$ is yet to receive the attention it deserves.

It’s been a quiet couple of weeks on the blog, something which often indicates that it’s been anything but quiet off the blog. Such was indeed the case recently.

For one thing, I was in Canada last week. I had been kindly invited to give two talks at the University of Western Ontario, one of Canada’s leading universities for science. One of the talks, the annual Nerenberg lecture (in memory of Professor Morton Nerenberg) is intended for the general public, so I presented a lecture on The 2013 Nobel Prize: The 50-Year Quest for the Higgs Boson. While I have given a talk on this subject before (an older version is on-line) I felt some revisions would be useful. The other talk was for members of the applied mathematics department, which hosts a diverse group of academics. Unlike a typical colloquium for a physics department, where I can assume that the vast majority of the audience has had university-level quantum mechanics, this talk required me to adjust my presentation for a much broader scientific audience than usual.  I followed, to an extent, my website’s series on Fields and Particles and on How the Higgs Field Works, both of which require first-year university math and physics, but nothing more. Preparation of the two talks, along with travel, occupied most of my free time over recent days, so I haven’t been able to write, or even respond to readers’ questions, unfortunately.

I also dropped in at Canada’s Perimeter Institute on Friday, when it was hosting a small but intense one-day workshop on the recent potentially huge discovery by the BICEP2 experiment of what appears to be a signature of gravitational waves from the early universe. This offered me an opportunity to hear some of the world’s leading experts talking about the recent measurement and its potential implications (if it is correct, and if the simplest interpretation of it is correct). Alternative explanations of the experiment’s results were also mentioned. Also, there was a lot of discussion about the future, both the short-term and the long-term. Quite a few measurements will be made in the next six to twelve months that will shed further light on the BICEP2 measurement, and on its moderate conflict with the simplest interpretation of certain data from the Planck satellite.  Further down the line, a very important step will be to reduce the amount of B-mode polarization that arises from the gravitational lensing of E-mode polarization, a method called “delensing”; this will make it easier to observe the B-mode polarization from gravitational waves (which is what we’re interested in) even at rather small angular scales (high “multipoles”).   Looking much further ahead, we will be hearing a lot of discussion about huge new space-based gravitational wave detectors such as BBO [Big Bang Observatory].  (Actually the individual detectors are quite small, but they are spaced at great distances.) These can potentially measure gravitational waves whose wavelength is comparable to the size of the Earth’s orbit or even larger, which is still much smaller than those apparently detected by BICEP2 in the polarization of the cosmic microwave background. Anyway, assuming what BICEP2 has really done is discover gravitational waves from the very early universe, this subject now a very exciting future and there is lots to do, to discuss and to plan.

I wish I could promise to provide a blog post summarizing carefully what I learned at the conference. But unfortunately, that brings me to the other reason blogging has been slow. While I was away, I learned that the funding situation for science in the United States is even worse than I expected. Suffice it to say that this presents a crisis that will interfere with blogging work, at least for a while.

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