Laplacian eigenvalues of independence complexes via additive compound matrices

Abstract

The independence complex of a graph G=(V,E) is the simplicial complex I(G) on vertex set V whose simplices are the independent sets in G. We present new lower bounds on the eigenvalues of the k-dimensional Laplacian Lk(I(G)) in terms of the eigenvalues of the graph Laplacian L(G). As a consequence, we show that for all k≥ 0, the dimension of the k-th reduced homology group (with real coefficients) of I(G) is at most \[ | \ 1≤ i1<·s<ik+1≤ |V| : \, λi1+λi2+·s+λik+1 ≥ |V|\|,\] where λ1≥λ2≥ ·s≥ λ|V|=0 are the eigenvalues of L(G). In particular, if k is the minimal number such that the sum of the k largest eigenvalues of L(G) is at least |V|, then Hi(I(G);R)=0 for all i≤ k-2. This extends previous results by Aharoni, Berger and Meshulam. Our proof relies on a relation between the k-dimensional Laplacian Lk(I(G)) and the (k+1)-th additive compound matrix of L0(I(G)), which is an nk+1×nk+1 matrix whose eigenvalues are all the possible sums of k+1 eigenvalues of the 0-dimensional Laplacian. Our results apply also in the more general setting of vertex-weighted Laplacian matrices.