Potential Singularity of the Axisymmetric Euler Equations with Cα Initial Vorticity for A Large Range of α
Abstract
We provide numerical evidence for a potential finite-time self-similar singularity of the 3D axisymmetric Euler equations with no swirl and with Cα initial vorticity for a large range of α. We employ a highly effective adaptive mesh method to resolve the potential singularity sufficiently close to the potential blow-up time. Resolution study shows that our numerical method is at least second-order accurate. Scaling analysis and the dynamic rescaling method are presented to quantitatively study the scaling properties of the potential singularity. We demonstrate that this potential blow-up is stable with respect to the perturbation of initial data. Our numerical study shows that the 3D axisymmetric Euler equations with our initial data develop finite-time blow-up when the H\"older exponent α is smaller than some critical value α*, which has the potential to be 1/3. We also study the n-dimensional axisymmetric Euler equations with no swirl, and observe that the critical H\"older exponent α* is close to 1-2n. Compared with Elgindi's blow-up result in a similar setting elgindi2021finite, our potential blow-up scenario has a different H\"older continuity property in the initial data and the scaling properties of the two initial data are also quite different. We also propose a relatively simple one-dimensional model and numerically verify its approximation to the n-dimensional axisymmetric Euler equations. This one-dimensional model sheds useful light to our understanding of the blow-up mechanism for the n-dimensional Euler equations.
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