Quantitative bounds for bounded solutions to the Navier-Stokes equations in endpoint critical Besov spaces
Abstract
In this paper, we study the quantitative regularity and blowup criteria for classical solutions to the three-dimensional incompressible Navier-Stokes equations in a critical Besov space framework. Specifically, we consider solutions u∈ L∞t(Bp,∞-1+3p) such that |D|-1+3p|u|∈ L∞t (Lp) with 3<p<∞. By deriving refined regularity estimates and substantially improving the strategy in Tao20, we overcome difficulties stemming from the low regularity of the Besov spaces and establish quantitative bounds for such solutions. These bounds are expressed in terms of a triple exponential of \| u (t)\|Bp,∞-1+3p combined with a single exponential of \| |D|-1+3p|u(t)| \|Lp. Consequently, we obtain a new blowup rate which can be interpreted as a coupling of triple logarithm of \| u(t) \|Bp,∞-1+3p and a single logarithm of \| |D|-1+3p|u(t)| \|Lp.
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