Distance Laplacian eigenvalues of graphs and chromatic and independence number

Abstract

For a connected graph G of order n, let Diag(Tr) be the diagonal matrix of vertex transmissions and D(G) be the distance matrix of G. The distance Laplacian matrix of G is defined as DL(G)=Diag(Tr)-D(G) and the eigenvalues of DL(G) are called the distance Laplacian eigenvalues of G. Let ∂1L(G)≥ ∂2L(G)≥ … ≥ ∂nL(G) be the distance Laplacian eigenvalues of G. Given an interval I, let mDL (G) I (or simply mDL I) be the number of distance Laplacian eigenvalues of G which lie in the interval I. For a prescribed interval I, we determine mDL I in terms of independence number α(G), chromatic number , number of pendant vertices and diameter d of the graph G. In particular, we prove that mDL(G) [n,n+2)≤ -1, ~mDL(G) [n,n+α(G))≤ n-α(G) and we show that the inequalities are sharp. We also show that mDL (G )( n,n+n)≤ n- n-CG+1 , where CG is the number of components in G, and discuss some cases where the bound is best possible. In addition, we prove that mDL (G )[n,n+p)≤ n-p, where p≥ 1 is the number of pendant vertices. Also, we characterize graphs of diameter d≤ 2 which satisfy mDL(G) (2n-1,2n )= α(G)-1=n2-1. At the end, we propose some problems of interest.