The Klein-Gordon equation, the Hilbert transform, and dynamics of Gauss-type maps

Abstract

A pair (,), where ⊂R2 is a locally rectifiable curve and ⊂R2 is a Heisenberg uniqueness pair if an absolutely continuous (with respect to arc length) finite complex-valued Borel measure supported on whose Fourier transform vanishes on necessarily is the zero measure. Recently, it was shown by Hedenmalm and Montes that if is the hyperbola x1x2=M2/(4π2), where M>0 is the mass, and is the lattice-cross (αZ×\0\) (\0\×βZ), where α,β are positive reals, then (,) is a Heisenberg uniqueness pair if and only if αβ M24π2. The Fourier transform of a measure supported on a hyperbola solves the one-dimensional Klein-Gordon equation, so the theorem supplies very thin uniqueness sets for a class of solutions to this equation. The case of the semi-axis R+ as well as the holomorphic counterpart remained open. In this work, we completely solve these two problems. As for the semi-axis, we show that the restriction to R+ of the above exponential system spans a weak-star dense subspace of L∞(R+) if and only if 0<αβ<4, based on dynamics of Gauss-type maps. This has an interpretation in terms of dynamical unique continuation. As for the holomorphic counterpart, we show that the above exponential system with m,n0 spans a weak-star dense subspace of H∞+(R) if and only if 0<αβ1. To obtain this result, we need to develop new harmonic analysis tools for the dynamics of Gauss-type maps, related to the Hilbert transform. Some details are deferred to a separate publication.