The Fourier transform on harmonic manifolds of purely exponential volume growth

Abstract

Let X be a complete, simply connected harmonic manifold of purely exponential volume growth. This class contains all non-flat harmonic manifolds of non-positive curvature and, in particular all known examples of harmonic manifolds except for the flat spaces. Denote by h > 0 the mean curvature of horospheres in X, and set = h/2. Fixing a basepoint o ∈ X, for ∈ ∂ X, denote by B the Busemann function at such that B(o) = 0. then for λ ∈ the function e(iλ - )B is an eigenfunction of the Laplace-Beltrami operator with eigenvalue -(λ2 + 2). For a function f on X, we define the Fourier transform of f by f(λ, ) := ∫X f(x) e(-iλ - )B(x) dvol(x) for all λ ∈ , ∈ ∂ X for which the integral converges. We prove a Fourier inversion formula f(x) = C0 ∫0∞ ∫∂ X f(λ, ) e(iλ - )B(x) dλo() |c(λ)|-2 dλ for f ∈ C∞c(X), where c is a certain function on R - \0\, λo is the visibility measure on ∂ X with respect to the basepoint o ∈ X and C0 > 0 is a constant. We also prove a Plancherel theorem, and a version of the Kunze-Stein phenomenon.