English

A sharp stability criterion for Euler equations via sparseness

Analysis of PDEs 2026-05-27 v1 Functional Analysis

Abstract

We introduce sparse versions of function spaces that are relevant to characterize the solutions of Euler equations without concentration. The standard Sobolev space H1H^{-1} is given a sparse structure that allows to measure the degree of compactness of embeddings into H1H^{-1} and provides new quantitative general criteria for H1H^{-1}-stability. Indices of sparseness are defined, and function spaces whose indices have prescribed decay are constructed, resulting in an improvement of the classical H1H^{-1}-stability results: sparse stability. The analysis relies on the introduction of sparse Riesz-Morrey-Tadmor spaces, that are characterized via maximal operators and new sparse domination theorems, together with extrapolation techniques. Our methods also yield improvements on recent results on the conservation of energy of physically realizable solutions of 22D-Euler.

Keywords

Cite

@article{arxiv.2310.19659,
  title  = {A sharp stability criterion for Euler equations via sparseness},
  author = {Óscar Domínguez and Mario Milman},
  journal= {arXiv preprint arXiv:2310.19659},
  year   = {2026}
}
R2 v1 2026-06-28T13:06:05.399Z