Localized quantitative estimates and potential blow-up rates for the Navier-Stokes equations (2209.15627v1)

Abstract: We show that if $v$ is a smooth suitable weak solution to the Navier-Stokes equations on $B(0,4)\times (0,T_)$, that possesses a singular point $(x_0,T_)\in B(0,4)\times {T_}$, then for all $\delta>0$ sufficiently small one necessarily has $$\lim\sup_{t\uparrow T_} \frac{|v(\cdot,t)|{L^{3}(B(x_0,\delta))}}{\Big(\log\log\log\Big(\frac{1}{(T*-t)^{\frac{1}{4}}}\Big)\Big)^{\frac{1}{1129}}}=\infty.$$ This local result improves upon the corresponding global result recently established by Tao. The proof is based upon a quantification of Escauriaza, Seregin and \v{S}verak's qualitative local result. In order to prove the required localized quantitative estimates, we show that in certain settings one can quantify a qualitative truncation/localization procedure introduced by Neustupa and Penel. After performing the quantitative truncation procedure, the remainder of the proof hinges on a physical space analogue of Tao's breakthrough strategy, established by Prange and the author.