Existence of homogeneous Euler flows of degree -α [-2,0]

Abstract

We consider (-α)-homogeneous solutions to the stationary incompressible Euler equations in R3\0\ for α≥ 0 and in R3 for α<0. Shvydkoy (2018) demonstrated the nonexistence of (-1)-homogeneous solutions and (-α)-homogeneous solutions in the range 0≤ α≤ 2 for the Beltrami and axisymmetric flows. The nonexistence result of the Beltrami (-α)-homogeneous solutions holds for all α<1. We show the nonexistence of axisymmetric (-α)-homogeneous solutions without swirls for -2≤ α<0. The main result of this study is the existence of axisymmetric (-α)-homogeneous solutions in the complementary range α∈ R [0,2]. More specifically, we show the existence of axisymmetric Beltrami (-α)-homogeneous solutions for α∈ R [0,2] and axisymmetric (-α)-homogeneous solutions with a nonconstant Bernoulli function for α∈ R [-2,2]. This is the first existence result on (-α)-homogeneous solutions with no explicit forms. For 2<α<3, constructed (-α)-homogeneous solutions provide new examples of the Beltrami/Euler flows in R3\0\ whose level sets of the proportionality factor/Bernoulli surfaces are nested surfaces created by the rotation of the sign ``∞".