Lattices with lots of congruence energy

Abstract

In 1978, motivated by E. H\"uckel's work in quantum chemistry, I. Gutman introduced the concept of the energy of a finite simple graph G as the sum of the absolute values of the eigenvalues of the adjacency matrix of G. At the time of writing, the MathSciNet search for "Title=(graph energy) AND Review Text=(eigenvalue)" returns 351 publications, most of which going after Gutman's definition. A congruence α of a finite algebra A turns A into a simple graph: we connect x≠ y∈ A by an edge iff (x,y)∈α; we let En(α) be the energy of this graph. We introduce the congruence energy CE(A) of A by CE(A):=Σ\En(α): α∈ Con(A)\. Let LAT(n) and CDA(n) stand for the class of n-element lattices and that of n-element congruence distributive algebras of any type. For a class X, let CE( X):= \CE(A): A∈ X\. We prove the following. (1) For α∈ A, En(α)/2 is the height of α in the equivalence lattice of A. (2) The largest number and the second largest number in CE(LAT(n)) are (n-1)· 2n-1 and, for n≥ 4, (n-1)· 2n-2+2n-3; these numbers are only witnessed by chains and lattices with exactly one two-element antichain, respectively. (3) The largest number in CE(CDA(n)) is also (n-1)· 2n-1, and if CE(A)=(n-1)· 2n-1 for an A∈ CDA(n), then Con(A) is a boolean lattice with size |Con(A)|=2n-1.

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