On Type I blowup and -regularity criteria of suitable weak solutions to the 3D incompressible MHD equations
Abstract
We study interior -regularity and Type I blowup criteria for suitable weak solutions to the three-dimensional incompressible MHD equations. Our starting point is a direct iteration scheme for the classical Caffarelli--Kohn--Nirenberg scaled energy quantities A,E,C and D, which yields -regularity criteria under smallness assumptions on the velocity field u and boundedness assumptions on the magnetic field b, with the underlying scaling-invariant quantities chosen independently. As an intermediate step, we prove that finiteness of one such scaling-invariant quantity for each of u and b allows only Type I blowup, in the sense that A(u,b;r)+E(u,b;r)+C(u,b;r)+D(p;r)<∞ for small r. This extends Seregin's Type I criteria for the Navier--Stokes equations to the MHD setting and provides a natural point of departure for the analysis of Type II blowup. By interpolation and embedding, we further obtain -regularity criteria and Type I characterisations in terms of general scaled mixed Lebesgue norms for u and b, with independent exponent choices. While we do not aim to sharpen existing mixed-norm -regularity criteria, the present formulation offers a unified and comparatively direct route that is naturally compatible with the Type I framework; in particular, the mixed-norm Type I description does not follow from earlier mixed-norm -regularity proofs by a formal replacement of the smallness parameter.
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