Long time behavior of the half-wave trace and Weyl remainders

Abstract

Given a compact Riemannian manifold (M,g), Chazarain, H\"ormander, Duistermaat, and Guillemin study the half-wave trace HWTM,g(τ) ∈ S'(Rτ). From the asymptotics of the half-wave trace as τ 0, H\"ormander deduces the now standard remainder O(σd-1) = O(λd/2-1/2) in Weyl's law, where d= M. Given a dynamical assumption implying additional local regularity, Duistermaat and Guillemin improve this to o(σd-1). By examining the Tauberian step in the argument, we show how a quantitative version \[N(σ) = Z(σ) + O(σd-1R(σ)-1/2)\] of the Duistermaat-Guillemin result follows under slightly stronger hypotheses, these implying that the (d-1)-fold regularized half-wave trace \[ Dτ 1-d HWTM,g(τ)\] is in L1,1loc(R \0\). Here Z(σ)∈ R[σ] is a polynomial and R(σ):R+ R+ is an (M,g)-dependent nondecreasing function with σ∞ R(σ)=∞, specified in terms of the growth rate of Dτ 1-d τ-1HWTM,g(τ) as measured in L1,1. Per Duistermaat-Guillemin, this hypothesis is implied by geometric conditions that hold ``generically'' for d≥ 3. Thus, we clarify the relation between the error term in Weyl's law and the long time behavior of the half-wave trace.