English

Garland's method for token graphs

Combinatorics 2023-05-05 v1

Abstract

The kk-th token graph of a graph G=(V,E)G=(V,E) is the graph Fk(G)F_k(G) whose vertices are the kk-subsets of VV and whose edges are all pairs of kk-subsets A,BA,B such that the symmetric difference of AA and BB forms an edge in GG. Let L(G)L(G) be the Laplacian matrix of GG, and Lk(G)L_k(G) be the Laplacian matrix of Fk(G)F_k(G). It was shown by Dalf\'o et al. that for any graph GG on nn vertices and any 0kn/20\leq \ell \leq k \leq \left\lfloor n/2\right\rfloor, the spectrum of L(G)L_{\ell}(G) is contained in that of Lk(G)L_k(G). Here, we continue to study the relation between the spectrum of Lk(G)L_k(G) and that of Lk1(G)L_{k-1}(G). In particular, we show that, for 1kn/21\leq k\leq \left\lfloor n/2\right\rfloor, any eigenvalue λ\lambda of Lk(G)L_k(G) that is not contained in the spectrum of Lk1(G)L_{k-1}(G) satisfies k(λ2(L(G))k+1)λkλn(L(G)), k(\lambda_2(L(G))-k+1)\leq \lambda \leq k\lambda_n(L(G)), where λ2(L(G))\lambda_2(L(G)) is the second smallest eigenvalue of L(G)L(G) (a.k.a. the algebraic connectivity of GG), and λn(L(G))\lambda_n(L(G)) is its largest eigenvalue. Our proof relies on an adaptation of Garland's method, originally developed for the study of high-dimensional Laplacians of simplicial complexes.

Keywords

Cite

@article{arxiv.2305.02406,
  title  = {Garland's method for token graphs},
  author = {Alan Lew},
  journal= {arXiv preprint arXiv:2305.02406},
  year   = {2023}
}
R2 v1 2026-06-28T10:25:01.821Z