On Arnold-type stability theorems for the Euler equation on a sphere
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In this paper, we establish three Arnold-type stability theorems for steady or rotating solutions of the incompressible Euler equation on a sphere. Specifically, we prove that if the stream function of a flow solves a semilinear elliptic equation with a monotone nonlinearity, then, under appropriate conditions, the flow is stable or orbitally stable in the Lyapunov sense. In particular, our theorems apply to degree-2 Rossby-Haurwitz waves. These results are achieved via a variational approach, with the key ingredient being to show that the flows under consideration satisfy the conditions of two Burton-type stability criteria which are established in this paper. As byproducts, we obtain some sharp rigidity results for solutions of semilinear elliptic equations on a sphere.
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Growth of vorticity gradient for the Euler equation on the sphere
Vorticity gradients for the Euler equation on the sphere are bounded above by double-exponential growth in time, with this rate achieved by explicit symmetric constructions.
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