A wavelet-inspired $L^3$-based convex integration framework for the Euler equations
Abstract
In this work, we develop a wavelet-inspired, -based convex integration framework for constructing weak solutions to the three-dimensional incompressible Euler equations. The main innovations include a new multi-scale building block, which we call an intermittent Mikado bundle; a wavelet-inspired inductive set-up which includes assumptions on spatial and temporal support, in addition to and pointwise estimates for Eulerian and Lagrangian derivatives; and sharp decoupling lemmas, inverse divergence estimates, and space-frequency localization technology which is well-adapted to functions satisfying estimates for other than , , or . We develop these tools in the context of the Euler-Reynolds system, enabling us to give both a new proof of the intermittent Onsager theorem (An Intermittent Onsager Theorem, Inventiones Mathematicae, (2023), 233) in this paper, and a proof of the -based strong Onsager conjecture in a companion paper (arXiv:2305.18509).
Cite
@article{arxiv.2305.18142,
title = {A wavelet-inspired $L^3$-based convex integration framework for the Euler equations},
author = {Vikram Giri and Hyunju Kwon and Matthew Novack},
journal= {arXiv preprint arXiv:2305.18142},
year = {2023}
}
Comments
funding acknowledgements updated, typos corrected