On adjacency operators of locally finite graphs

Abstract

A graph is called locally finite if, for each vertex v of , the set (v) of all neighbors of v in is finite. For any locally finite graph with vertex set V() and for any field F, let FV() be the vector space over F of all functions V() F (with natural componentwise operations) and let A( alg),F be the linear operator FV() FV() defined by (A( alg),F(f))(v) = Σu ∈ (v)f(u) for all f ∈ FV(), v ∈ V(). In the case of finite graph the mapping A( alg),F is the well known operator defined by the adjacency matrix of (over F), and the theory of eigenvalues and eigenfunctions of such operator is a well-developed (at least in the case F = C) part of the theory of finite graphs. In this paper we develope a theory of eigenvalues and eigenfunctions of A( alg),F for arbitrary infinite locally finite graphs (although a few results may be of interest for finite graphs) and fields F with a special emphasis on the case when is connected with uniformly bounded vertex degrees and F = C. By the author opinion, previous attempts in this direction were not quite satisfactory since were limited by consideration of rather special eigenfunctions and corresponding eigenvalues.