Stochastic transport equation with L\'evy noise
Abstract
We study the stochastic transport equation with globally β-H\"older continuous and bounded vector field driven by a non-degenerate pure-jump L\'evy noise of α-stable type. Whereas the deterministic transport equation may lack uniqueness, we prove the existence and pathwise uniqueness of a weak solution in the presence of a multiplicative pure jump noise, assuming α2+β>1. Notably, our results cover the entire range α ∈ (0,2), including the supercritical regime α∈(0,1) where the driving noise exhibits notoriously weak regularization. A key step of our strategy is the development of a sharp C1+δ-diffeomorphism and new regularity results for the Jacobian determinant of the stochastic flow associated to its stochastic characteristic equation. These novel probabilistic results are of independent interest and constitute a substantial component of our work. Our results are the first full generalization of the celebrated paper by Flandoli, Gubinelli, and Priola [Invent. Math. 2010] from the Brownian motion to the pure jump L\'evy noise. To the best of our knowledge, this appears to be the first example of a partial differential equation of fluid dynamics where well-posedness is restored by the influence of a non-degenerate pure-jump noise.
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