First variation of flat traces on negatively curved surfaces

Abstract

For a closed negatively curved surface (X,g) the flat trace of the geodesic Koopman operators Vgτ f=f Ggτ is the periodic orbit distribution \[ Tr Vg(τ)=ΣγLγ\#(I-Pγ)\,δ(τ-Lγ), τ>0, \] supported on the length spectrum and weighted by the linearized Poincar\'e maps Pγ. For a smooth family of negatively curved metrics gt we compute the first variation ∂t0\,Tr Vgt as a distribution. At an isolated length the leading singularity is a multiple of δ'(τ-), and its coefficient is an explicit linear functional of the length variations Lγm of the closed geodesics with Lγm=. This transport coefficient forces the marked lengths to be locally constant along any deformation with constant flat trace. As an application, if Tr Vgt=Tr Vg0 for all t then gt is isometric to g0 for all t. Together with Sunada-type constructions of non isometric pairs with equal flat traces, this shows that the flat trace is globally non-unique yet locally complete along smooth families.