The number of eigenstates: counting function and heat kernel

TL;DR

This paper explores the relationship between the eigenstate counting function and heat kernel, introduces a practical calculation method for N(lambda), and verifies Kac's conjecture for multiply-connected regions.

Contribution

It presents a new expression for N(lambda), a renormalization approach for divergence removal, and extends heat kernel analysis to multiply-connected regions, confirming Kac's conjecture.

Findings

Derived a new expression for N(lambda) suitable for calculations.

Developed a renormalization procedure to handle divergences.

Confirmed Kac's conjecture for multiply-connected regions.

Abstract

The main aim of this paper is twofold: (1) revealing a relation between the counting function N(lambda) (the number of the eigenstates with eigenvalue smaller than a given number) and the heat kernel K(t), which is still an open problem in mathematics, and (2) introducing an approach for the calculation of N(lambda), for there is no effective method for calculating N(lambda) beyond leading order. We suggest a new expression of N(lambda) which is more suitable for practical calculations. A renormalization procedure is constructed for removing the divergences which appear when obtaining N(lambda) from a nonuniformly convergent expansion of K(t). We calculate N(lambda) for D-dimensional boxes, three-dimensional balls, and two-dimensional multiply-connected irregular regions. By the Gauss-Bonnet theorem, we generalize the simply-connected heat kernel to the multiply-connected case; this result proves Kac's conjecture on the two-dimensional multiply-connected heat kernel. The approaches for calculating eigenvalue spectra and state densities from N(lambda) are introduced.