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Autor principal: Agresti, Antonio
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2602.21981
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author Agresti, Antonio
author_facet Agresti, Antonio
contents For several physically relevant SPDEs, it is known that global weak solutions coexist with local strong ones. Typically, weak-strong uniqueness results are known, and ensure that the global and strong solutions coincide as long as the latter exist. Times at which a weak solution does not coincide with a strong one are called singular times. Determining their fractal dimension is fundamental to capturing the regularity of weak solutions. We define singular times for a wide class of semilinear SPDEs. We show that sets of singular times have fractal dimension (i.e., Hausdorff and/or Minkowski) at most $ 1-\ell\, \mathsf{Exc}$, where $\ell$ and $\mathsf{Exc}$ are the time integrability and the excess of spatial regularity compared to the critical regularity of the energy bound associated with weak solutions, respectively. Moreover, their corresponding $(1-\ell\,\mathsf{Exc} )$-dimensional measure is zero. We formulate and apply our theory to quenched strong Leray-Hopf solutions of 3D Navier-Stokes equations (NSEs) with physically relevant noises, including rough Kraichnan and Lie transport. In particular, we extend the fundamental $1/2$-dimensional bound of Leray and Scheffer on singular times for 3D NSEs to the stochastic setting, and we prove new conditional results under supercritical Serrin's conditions, irrespective of the roughness of the noise. Our framework is new even in the deterministic case, and provides the first partial regularity results for weak solutions to SPDEs with multiplicative noise.
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spellingShingle Fractal dimension of singular times for SPDEs: Energy bounds, criticality, and weak-strong uniqueness
Agresti, Antonio
Probability
Mathematical Physics
Analysis of PDEs
Primary 60H15, Secondary 28A80, 35B65, 35Q30
For several physically relevant SPDEs, it is known that global weak solutions coexist with local strong ones. Typically, weak-strong uniqueness results are known, and ensure that the global and strong solutions coincide as long as the latter exist. Times at which a weak solution does not coincide with a strong one are called singular times. Determining their fractal dimension is fundamental to capturing the regularity of weak solutions. We define singular times for a wide class of semilinear SPDEs. We show that sets of singular times have fractal dimension (i.e., Hausdorff and/or Minkowski) at most $ 1-\ell\, \mathsf{Exc}$, where $\ell$ and $\mathsf{Exc}$ are the time integrability and the excess of spatial regularity compared to the critical regularity of the energy bound associated with weak solutions, respectively. Moreover, their corresponding $(1-\ell\,\mathsf{Exc} )$-dimensional measure is zero. We formulate and apply our theory to quenched strong Leray-Hopf solutions of 3D Navier-Stokes equations (NSEs) with physically relevant noises, including rough Kraichnan and Lie transport. In particular, we extend the fundamental $1/2$-dimensional bound of Leray and Scheffer on singular times for 3D NSEs to the stochastic setting, and we prove new conditional results under supercritical Serrin's conditions, irrespective of the roughness of the noise. Our framework is new even in the deterministic case, and provides the first partial regularity results for weak solutions to SPDEs with multiplicative noise.
title Fractal dimension of singular times for SPDEs: Energy bounds, criticality, and weak-strong uniqueness
topic Probability
Mathematical Physics
Analysis of PDEs
Primary 60H15, Secondary 28A80, 35B65, 35Q30
url https://arxiv.org/abs/2602.21981