Potential Singularity of the Axisymmetric Euler Equations with Cα Initial Vorticity for A Large Range of α. Part II: the N-Dimensional Case

Abstract

In Part II of this sequence to our previous paper for the 3-dimensional Euler equations zhang2022potential, we investigate potential singularity of the n-diemnsional axisymmetric Euler equations with Cα initial vorticity for a large range of α. We use the adaptive mesh method to solve the n-dimensional axisymmetric Euler equations and use the scaling analysis and dynamic rescaling method to examine the potential blow-up and capture its self-similar profile. Our study shows that the n-dimensional axisymmetric Euler equations with our initial data develop finite-time blow-up when the H\"older exponent α<α*, and this upper bound α* can asymptotically approach 1-2n. Moreover, we introduce a stretching parameter δ along the z-direction. Based on a few assumptions inspired by our numerical experiments, we obtain α*=1-2n by studying the limiting case of δ → 0. For the general case, we propose a relatively simple one-dimensional model and numerically verify its approximation to the n-dimensional Euler equations. This one-dimensional model sheds useful light to our understanding of the blowup mechanism for the n-dimensional Euler equations. As shown in zhang2022potential, the scaling behavior and regularity properties of our initial data are quite different from those of the initial data considered by Elgindi in elgindi2021finite.

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