The time fractional stochastic partial differential equations with non-local operator on Rd
Abstract
This paper establishes a comprehensive well-posedness and regularity theory for time-fractional stochastic partial differential equations on Rd driven by mixed Wiener--L\'evy noises. The equations feature a Caputo time derivative ∂tα (0<α<1) and a spatial nonlocal operator φ() generated by a subordinate Brownian motion, leading to a doubly nonlocal structure. For the case p 2, we prove the existence, uniqueness, and sharp Sobolev regularity of weak solutions in the scale of φ-Sobolev spaces Hpφ,γ+2(T). Our approach combines harmonic analysis techniques (Fefferman--Stein theorem, Littlewood--Paley theory) with stochastic analysis to handle the combined Wiener and L\'evy noise terms. In the special case of cylindrical Wiener noise, a dimensional constraint d < 20(2 - (2σ2 - 2/p)+/α) is obtained.~For the low-regularity case 1 p 2, where maximal function estimates fail, we construct unique local mild solutions in Lp(Rd) for equations driven by pure-jump L\'evy space-time white noise, using stochastic truncation and fixed-point arguments. The results unify and extend previous theories by simultaneously incorporating time-space nonlocality and jump-type randomness.
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