Global exponential stability for the three-dimensional Navier-Stokes equations on hyperbolic space

Abstract

We prove that the three-dimensional incompressible Navier-Stokes equations with the deformation Laplacian on hyperbolic 3-space 3 admit a unique global mild solution for sufficiently small initial data in L3(3), and that this solution decays exponentially to zero. The exponential decay rate is μλ(3), where μ is the kinematic viscosity and λ(3) = 26/9 is the effective spectral gap of the deformation Laplacian in L3. On flat 3, the corresponding Kato-type result gives only algebraic decay. The exponential stability is a macroscopic consequence of the spectral gap provided by negative curvature. We also show that the L2 norm is supercritical on 3 (as on 3), with the obstruction arising from the local ultraviolet scaling of the heat kernel, which is insensitive to global geometry. The boundary between what curvature can and cannot improve is located exactly: the Fujita-Kato integral has a scaling exponent 1/2 - 3/(2p) that depends only on the integrability of the initial data, not on the geometry of the manifold. For p ≥ 3 (the Kato critical space), the integral is bounded and the spectral gap contributes exponential time decay. For p < 3, the integral diverges at t = 0 (and strictly diverges for all t>0 when p 3/2) regardless of the curvature.