Stranding $\mathfrak{sl}_n$ webs
Abstract
Webs are a kind of planar, directed, edge-labeled graph that encode invariant vectors for quantum representations of . The theory of webs developed organically for , where they are also known as noncrossing matchings and the Temperley-Lieb algebra, before being formalized by Kuperberg for and as the morphisms in a diagrammatic categorification of quantum representations called the spider category. Various models extend webs to . Only Cautis-Kamnitzer-Morrison prove a full set of relations for their webs, though Fontaine's webs are better adapted to computations, more graph-theoretically natural, and directly generalize webs for and . This paper formalizes the theory of Fontaine's webs, proving the existence of a deep and powerful global structure on these webs called strandings. We do three key things: 1) give a state-sum formula to construct (-invariant) web vectors from the orientation of strandings on Fontaine's webs; 2) list and prove a complete set of relations, connecting strandings to the local data of binary labelings that are well-established in the literature; and 3) provide applications and examples of how strandings facilitate computations.
Keywords
Cite
@article{arxiv.2510.12035,
title = {Stranding $\mathfrak{sl}_n$ webs},
author = {Heather M. Russell and Julianna Tymoczko},
journal= {arXiv preprint arXiv:2510.12035},
year = {2025}
}
Comments
48 pages, 33 figures