Strong local nondeterminism for stochastic time-fractional slow and fast diffusion equations

Abstract

We study a class of stochastic time-fractional equations on Rd driven by a centered Gaussian noise, involving a Caputo time derivative of order β>0, a fractional (power) Laplacian of order α>0, and a Riemann-Liouville time integral of order γ0 acting on the noise. The noise is fractional in time (index H) and Riesz-type in space (index ). We derive sharp Dalang-type necessary and sufficient conditions for the existence of a random field solution across almost full parameter range (α,β,γ;H,). Under the Dalang-type conditions, we prove sharp variance bounds for temporal and spatial increments, as well as strong local nondeterminism in time in several regimes (two-sided version for β=1 and for parts of the case β=2; one-sided version for 0<β<2) and strong local nondeterminism in space for the whole range of parameters. As applications, we derive exact uniform and local moduli of continuity, Chung-type laws of the iterated logarithm, and quantitative bounds on small ball probabilities. Along the way, we obtain sharp asymptotics for the fundamental solution kernels at 0 and ∞, which may be of independent interest.