Eigenvalue Sums of Combinatorial Magnetic Laplacians on Finite Graphs

Abstract

We give a construction of a class of magnetic Laplacian operators on finite directed graphs. We study some general combinatorial and algebraic properties of operators in this class before applying the Harrell-Stubbe Averaged Variational Principle to derive several sharp bounds on sums of eigenvalues of such operators. In particular, among other inequalities, we show that if G is a directed graph on n vertices arising from orienting a connected subgraph of d-regular loopless graph on n vertices, then if θ is any magnetic Laplacian on G, of which the standard combinatorial Laplacian is a special case, and λ0≤ λ1≤ ...≤λn-1 are the eigenvalues of θ, then for k≤ n2, we have \[1kΣj=0k-1λj ≤ d-1.\]