{"id":208912,"date":"2025-10-08T11:01:18","date_gmt":"2025-10-08T11:01:18","guid":{"rendered":"https:\/\/www.newsbeep.com\/us\/208912\/"},"modified":"2025-10-08T11:01:18","modified_gmt":"2025-10-08T11:01:18","slug":"origami-patterns-solve-a-major-physics-riddle","status":"publish","type":"post","link":"https:\/\/www.newsbeep.com\/us\/208912\/","title":{"rendered":"Origami Patterns Solve a Major Physics Riddle"},"content":{"rendered":"

The amplituhedron is a geometric shape with an almost mystical quality<\/a>: Compute its volume, and you get the answer to a central calculation in physics about how particles interact.<\/p>\n

Now, a young mathematician at Cornell University named Pavel (Pasha) Galashin<\/a> has found that the amplituhedron is also mysteriously connected to another completely unrelated subject: origami, the art of paper folding. In a proof posted in October 2024<\/a>, he showed that patterns that arise in origami can be translated into a set of points that together form the amplituhedron. Somehow, the way paper folds and the way particles collide produce the same geometric shape.<\/p>\n

\u201cPasha has done some brilliant work related to the amplituhedron before,\u201d said Nima Arkani-Hamed<\/a>, a physicist at the Institute for Advanced Study who introduced the amplituhedron<\/a> in 2013 with his graduate student at the time, Jaroslav Trnka<\/a>. \u201cBut this is next-level stuff for me.\u201d<\/p>\n

By drawing on this new link to origami, Galashin was also able to resolve an open conjecture about the amplituhedron, one that physicists had long assumed to be true but hadn\u2019t been able to rigorously prove: that the shape really can be cut up into simpler building blocks that correspond to the calculations physicists want to make. In other words, the pieces of the amplituhedron really do fit together the way they\u2019re supposed to.<\/p>\n

The result doesn\u2019t just build a bridge between two seemingly disparate areas of study. Galashin and other mathematicians are already exploring what else that bridge can tell them. They\u2019re using it to better understand the amplituhedron \u2014 and to answer other questions in a far broader range of settings.<\/p>\n

Explosive Computations<\/p>\n

Physicists want to predict what will happen when fundamental particles interact. Say two subatomic particles called gluons collide. They might bounce off each other unchanged, or transform into a set of four gluons, or do something else entirely. Each outcome occurs with a certain probability, which is represented by a mathematical expression called a scattering amplitude.<\/p>\n

\"\" <\/p>\n

Feynman diagrams are used to calculate the likelihood that a particle collision will result in a certain outcome.<\/p>\n

Mark Belan\/Quanta Magazine<\/p>\n

For decades, physicists calculated scattering amplitudes in one of two ways. The first used Feynman diagrams<\/a>, squiggly-line drawings that describe how particles move and interact. Each diagram represents a mathematical computation; by adding together the computations corresponding to different Feynman diagrams, you can calculate a given scattering amplitude. But as the number of particles in a collision increases, the number of Feynman diagrams you need grows explosively<\/a>. Things quickly get out of hand: Computing the scattering amplitudes of relatively simple events can require adding thousands or even millions of terms.<\/p>\n

The second method, introduced in the early 2000s, is called Britto-Cachazo-Feng-Witten (BCFW) recursion. It breaks up complex particle interactions into smaller, simpler interactions that are easier to study. You can calculate amplitudes for these simpler interactions and keep track of them using collections of vertices and edges called graphs. These graphs tell you how to stitch the simpler interactions back together in order to compute the scattering amplitude of the original collision.<\/p>\n

\"\" <\/p>\n

These graphs keep track of complicated BCFW recursion formulas.<\/p>\n

BCFW recursion requires less work than Feynman diagrams. Instead of adding up millions of terms, you might only need to add up hundreds. But both methods have the same problem: The final answer is often much simpler than the extensive computations it takes to get there, with many terms canceling out in the end.<\/p>\n

Then, in 2013, Arkani-Hamed and Trnka made a surprising discovery: that the complicated math of particle collisions is actually geometry in disguise.<\/p>\n

Saved by Geometry <\/p>\n

In the early 2000s, Alexander Postnikov<\/a>, a mathematician at the Massachusetts Institute of Technology, was studying a geometric object known as the positive Grassmannian.<\/p>\n

The positive Grassmannian, which has been a subject of mathematical interest since the 1930s, is built in a highly abstract way. First, take an n-dimensional space and consider all the planes of some given, smaller dimension that live inside it. For example, inside the three-dimensional space we inhabit, you can find infinitely many flat two-dimensional planes that spread out in every direction.<\/p>\n

Each plane \u2014 essentially a slice of the larger n-dimensional space \u2014 can be defined by an array of numbers called a matrix. You can compute certain values from this matrix, called minors, that tell you about properties of the plane.<\/p>\n

\"Young <\/p>\n

Pavel Galashin developed a connection between origami and particle physics.<\/p>\n

Courtesy of Pavel Galashin<\/p>\n

Now consider only those planes in your space whose minors are all positive. The collection of all such special \u201cpositive\u201d planes gives you a complicated geometric space \u2014 the positive Grassmannian.<\/p>\n

To understand the positive Grassmannian\u2019s rich internal structure, mathematicians divvy it up into different regions, so that each region consists of an assortment of planes that share certain patterns. Postnikov, hoping to make this task easier, came up with a way to keep track of the different regions and how they fit together. He invented what he called plabic (short for \u201cplanar bicolored\u201d) graphs \u2014 networks of black and white vertices connected by edges, drawn so that no edges cross. Each plabic graph captured one region of the positive Grassmannian, giving mathematicians a visual language for what would otherwise be defined by dense algebraic formulas.<\/p>\n

Nearly a decade after Postnikov introduced his plabic graphs, Arkani-Hamed and Trnka were trying to calculate the scattering amplitudes of various particle collisions. As they grappled with their BCFW recursion formulas, they noticed something uncanny. The graphs they were using to keep track of their calculations looked just like Postnikov\u2019s plabic graphs. Curious, they drove up to MIT to meet him.<\/p>\n

\u201cAt lunch we said, \u2018It\u2019s weird, we\u2019re seeing exactly the same thing,\u2019\u201d Arkani-Hamed recalled.<\/p>\n

They were right. To calculate the scattering amplitude for a collision of n particles, physicists would have to add up many BCFW terms \u2014 and each of those terms corresponded to a region of the positive Grassmannian in n dimensions.<\/p>\n

Arkani-Hamed and Trnka realized that this geometric connection might make it easier to compute scattering amplitudes. Using data about their particle collision \u2014 the momenta of the particles, for instance \u2014 they defined a lower-dimensional shadow of the positive Grassmannian. The total volume of this shadow was equal to the scattering amplitude.<\/p>\n

And so the amplituhedron was born<\/a>.<\/p>\n

\"\" <\/p>\n

An illustration of the amplituhedron corresponding to a particle collision involving eight gluons.<\/p>\n

That was only the beginning of the story. Physicists and mathematicians wanted to confirm, for instance, that the same plabic graphs that defined regions of the positive Grassmannian could also define pieces of the amplituhedron \u2014 and that those pieces would have no gaps or overlaps, perfectly fitting together to encompass the shape\u2019s exact volume. This hope came to be known as the triangulation conjecture: Could the amplituhedron be cleanly triangulated, or subdivided, into simpler building blocks?<\/p>\n

Proving this would cement Arkani-Hamed and Trnka\u2019s vision: that the complicated BCFW formulas that produced a particle collision\u2019s scattering amplitude (albeit inefficiently) could be understood as the sum of the volumes of the amplituhedron\u2019s building blocks.<\/p>\n

This was no easy task. For one thing, from the get-go it was clear there were really two amplituhedra. The first was defined in momentum-twistor coordinates \u2014 a clever mathematical relabeling that made the shape easier to work with because it related naturally to the positive Grassmannian and Postnikov\u2019s plabic graphs. Mathematicians were able to prove the triangulation conjecture<\/a> for this version of the amplituhedron in 2021.<\/p>\n

The other version, known as the momentum amplituhedron, was instead defined directly in terms of the momenta of colliding particles. Physicists cared more about this second version, because it spoke the same language as real particle collisions and scattering experiments. But it was also harder to describe mathematically. As a result, the triangulation conjecture remained wide open.<\/p>\n

If triangulation were to fail for the momentum amplituhedron, then it would mean that the amplituhedron was not the right way to make sense of BCFW formulas for computing scattering amplitudes.<\/p>\n

For more than a decade, the uncertainty lingered \u2014 until the study of paper folds began to suggest a way forward.<\/p>\n

Finding Bigfoot<\/p>\n

Pavel Galashin didn\u2019t set out to study either origami or the amplituhedron. In 2018, as one of Postnikov\u2019s graduate students, he and a colleague had just proved an intriguing link between the positive Grassmannian and the Ising model, which is used to study the behavior of systems like ferromagnets. Galashin was now trying to understand a celebrated proof about the Ising model \u2014 in particular, about special symmetries it exhibited \u2014 in terms of the positive Grassmannian.<\/p>\n

While working through the proof \u2014 a project he intermittently returned to over the next few years \u2014 Galashin encountered a couple of intriguing papers where researchers used other kinds of diagrams to make the geometry more tractable: origami crease patterns. These are diagrams of lines that tell you where to fold paper to make, say, a crane or frog.<\/p>\n

\"\"\"\" <\/p>\n

This crease pattern will produce a swan.<\/p>\n

It might seem strange for origami to crop up here. But over the years, the mathematics of origami has turned out to be surprisingly deep. Problems about origami \u2014 such as whether a given crease pattern will produce a shape that you can flatten without tearing \u2014 are computationally hard to solve. And it\u2019s now known that origami can be used to perform all sorts of computations<\/a>.<\/p>\n

In 2023, while probing what origami was doing in papers about the Ising model, Galashin came across a question that caught his attention. Say you only have information about a crease pattern\u2019s outer boundary \u2014 the border of the paper, which the creases divide into various line segments. In particular, say you only have information about how those line segments are situated in space before and after folding. Can you always find a complete crease pattern that both satisfies those constraints and produces an origami shape that can flatten properly? Mathematicians had conjectured that the answer was yes, but no one could prove it.<\/p>\n

Galashin found the conjecture striking, because in his usual area of research, which deals with the positive Grassmannian, examining the boundary of an object is a common way to gain information about it.<\/p>\n","protected":false},"excerpt":{"rendered":"The amplituhedron is a geometric shape with an almost mystical quality: Compute its volume, and you get the…\n","protected":false},"author":2,"featured_media":208913,"comment_status":"","ping_status":"","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[49],"tags":[199,79],"class_list":{"0":"post-208912","1":"post","2":"type-post","3":"status-publish","4":"format-standard","5":"has-post-thumbnail","7":"category-physics","8":"tag-physics","9":"tag-science"},"_links":{"self":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/posts\/208912","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/users\/2"}],"replies":[{"embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/comments?post=208912"}],"version-history":[{"count":0,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/posts\/208912\/revisions"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/media\/208913"}],"wp:attachment":[{"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/media?parent=208912"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/categories?post=208912"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/www.newsbeep.com\/us\/wp-json\/wp\/v2\/tags?post=208912"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}