On rough Calder\'on solutions to the Navier-Stokes equations and applications to the singular set
Abstract
In 1934, Leray proved the existence of global-in-time weak solutions to the Navier-Stokes equations for any divergence-free initial data in L2. In the 1980s, Giga and Kato independently showed that there exist global-in-time mild solutions corresponding to small enough critical L3(R3) initial data. In 1990, Calder\'on filled the gap to show that there exist global-in-time weak solutions for all supercritical initial data in Lp for 2< p<3 by utilising a splitting argument, blending the constructions of Leray and Giga-Kato. In this paper, we utilise a "Calder\'on-like" splitting to show the global-in-time existence of weak solutions to the Navier-Stokes equations corresponding to supercritical Besov space initial data u0 ∈ Bsq,∞ where q>2 and -1+2q<s< (-1+3q,0 ), which fills a similar gap between Leray and known mild solution theory in the Besov space setting. We also use the Calder\'on-like splitting to investigate the structure of the singular set under a Type-I blow-up assumption in the Besov space setting, which is considerably rougher than in previous works.
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