On the local existence and blow-up for generalized SQG patches

Abstract

We study patch solutions of a family of transport equations given by a parameter α, 0< α <2, with the cases α =0 and α =1 corresponding to the Euler and the surface quasi-geostrophic equations respectively. In this paper, using several new cancellations, we provide the following new results. First, we prove local well-posedness for H2 patches in the half-space setting for 0<α< 1/3, allowing self-intersection with the fixed boundary. Furthermore, we are able to extend the range of α for which finite time singularities have been shown in KYZ and KRYZ. Second, we establish that patches remain regular for 0<α<2 as long as the arc-chord condition and the regularity of order C1+δ for δ>α/2 are time integrable. This finite-time singularity criterion holds for lower regularity than the regularity shown in numerical simulations in CFMR and ScottDritschel for surface quasi-geostrophic patches, where the curvature of the contour blows up numerically. This is the first proof of a finite-time singularity criterion lower than or equal to the regularity in the numerics. Finally, we also improve results in G and in CCCGW, giving local-wellposedness for patches in H2 for 0<α < 1 and in H3 for 1<α<2.