Fractional Navier-Stokes Equations with Caputo Derivative Driven by Hermite Noise

Abstract

We study time-fractional stochastic Navier-Stokes equations on a bounded domain of 2 (the restriction to dimension two is essential for the bilinear estimates via Sobolev embeddings) driven by a Hermite process ZHk of order k1 and Hurst parameter H∈(1/2,1). This class of noises generalizes fractional Brownian motion (k=1) and the Rosenblatt process (k=2). We construct the Wiener integral with respect to ZHk and establish sharp Lp estimates via hypercontractivity, explicitly capturing the dependence on k. Using a refined Hilbert-Schmidt estimate for the Mittag-Leffler operator, we prove that the stochastic convolution belongs to H under the condition (1-)+2H>2. A fixed-point argument in a weighted space yields the existence, uniqueness, and H\"older regularity of mild solutions. We also prove a non-central limit theorem linking the solution to discrete approximations.