Extremal chromatic bounds for distance Laplacian eigenvalues

Abstract

For a connected simple graph G on n vertices with chromatic number χ, the distance Laplacian matrix is (G)=diag(G(v1),…,G(vn))-D(G), where D(G) is the distance matrix and G(v)=Σu∈ V(G) dG(u,v) is the transmission. The eigenvalues of (G) are ordered as ∂L1(G) ∂L2(G) ·s ∂Ln(G)=0. Building on the chromatic lower bound ∂L1(G) n+n/χ and subsequent developments, we prove a color-class majorization principle: if (1,…,χ) are the color-class sizes in an optimal χ-coloring with 1·sχ, then the first 1-1 distance Laplacian eigenvalues satisfy ∂Li(G) n+1, for 1 i 1-1. This gives sharp lower bounds on the number of eigenvalues above the chromatic threshold bχ=n+n/χ, thereby refining distribution theorems of [Aouchiche and Hansen, Filomat, 2017] and [Pirzada and Khan LAA, 2021]. We further refine clique/independent-set based multiplicity results by deriving explicit chromatic criteria in terms of neighborhood compression, and we generalize the extremal problem for minimum ∂L1 at fixed chromatic number by characterizing the balanced complete multipartite minimizers. Finally, we present a Ky Fan type result, and complement-component consequences of the majorization principle.