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On a Type I singularity condition in terms of the pressure for the Euler equations in $\mathbb R^3$ (2012.11948v1)

Published 22 Dec 2020 in math.AP

Abstract: We prove a blow up criterion in terms of the Hessian of the pressure of smooth solutions $u\in C([0, T); W{2,q} (\mathbb R3))$, $q>3$ of the incompressible Euler equations. We show that a blow up at $t=T$ happens only if $$\int_0 T \int_0 t \left{\int_0 s |D2 p (\tau)|{L\infty} d\tau \exp \left( \int{s} t \int_0 {\s} |D2 p (\tau)|{L\infty} d\tau d\s \right) \right}dsdt \, = +\infty.$$ As consequences of this criterion we show that there is no blow up at $t=T$ if $ |D2 p(t)|{L\infty} \le \frac {c}{(T-t)2}$ with $c<1$ as $t\nearrow T$. Under the additional assumption of $\int_0 T |u(t)|_{L\infty (B(x_0, \rho))} dt <+\infty$, we obtain localized versions of these results.

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