Partition density, star arboricity, and sums of Laplacian eigenvalues of graphs
Abstract
Let G=(V,E) be a graph on n vertices, and let λ1(L(G)) ·s λn-1(L(G)) λn(L(G))=0 be the eigenvalues of its Laplacian matrix L(G). Brouwer conjectured that for every 1 k n, Σi=1k λi(L(G)) |E|+k+12. Here, we prove the following weak version of Brouwer's conjecture: For every 1≤ k ≤ n, \[ Σi=1k λi(L(G)) ≤ |E|+k2+15kk+65k. \] For a graph G=(V,E), we define its partition density (G) as the maximum, over all subgraphs H of G, of the ratio between the number of edges of H and the number of vertices in the largest connected component of H. Our argument relies on the study of the structure of the graphs G satisfying (G)< k. In particular, using a result of Alon, McDiarmid and Reed, we show that every such graph can be decomposed into at most k+ 15k+65 edge-disjoint star forests (that is, forests whose connected components are all isomorphic to stars). In addition, we show that for every graph G=(V,E) and every 1 k |V|, \[ Σi=1k λi(L(G)) ≤ |E|+k· (G) + k2, \] where (G) is the maximum size of a matching in G.
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