Shock Formation for Compressible Euler Equations on S2

Abstract

In this paper, we prove the finite-time shock formation for the compressible Euler equations on the two-dimensional sphere S2. In contrast to the flat Euclidean case R2, the geometry of S2 imposes new difficulties, and the fluid dynamics are affected by the curved background. To overcome these challenges, we modify the existing modulation method and employ a set of carefully constructed, time-dependent coordinates that precisely track the shock formation on S2. In particular, we first perform a time-dependent rotation of S2, then apply the stereographic projection to the sphere, straighten the steepening shock front, and finally construct shock-adapted coordinates. In the shock-adapted coordinates, the compressible Euler equations on S2 can be recast into a form suitable for self-similar analysis. Within this framework, we implement a detailed bootstrap argument and establish global well-posedness for the self-similar system. After transferring these results back to the original physical system, we thereby demonstrate the finite-time shock formation on S2.

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