Rectifiability, finite Hausdorff measure, and compactness for non‐minimizing Bernoulli free boundaries

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Dennis Kriventsov, Georg S. Weiss
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引用次数: 0

Abstract

While there are numerous results on minimizers or stable solutions of the Bernoulli problem proving regularity of the free boundary and analyzing singularities, much less is known about critical points of the corresponding energy. Saddle points of the energy (or of closely related energies) and solutions of the corresponding time‐dependent problem occur naturally in applied problems such as water waves and combustion theory. For such critical points —which can be obtained as limits of classical solutions or limits of a singular perturbation problem—it has been open since (Weiss, 2003) whether the singular set can be large and what equation the measure satisfies, except for the case of two dimensions. In the present result we use recent techniques such as a frequency formula for the Bernoulli problem as well as the celebrated Naber–Valtorta procedure to answer this more than 20 year old question in an affirmative way: For a closed class we call variational solutions of the Bernoulli problem, we show that the topological free boundary (including degenerate singular points , at which as ) is countably ‐rectifiable and has locally finite ‐measure, and we identify the measure completely. This gives a more precise characterization of the free boundary of in arbitrary dimension than was previously available even in dimension two. We also show that limits of (not necessarily minimizing) classical solutions as well as limits of critical points of a singularly perturbed energy are variational solutions, so that the result above applies directly to all of them.
非最小化伯努利自由边界的可整性、有限豪斯多夫度量和紧凑性
关于伯努利问题的最小值或稳定解,有许多结果证明了自由边界的正则性并分析了奇异点,但对相应能量的临界点却知之甚少。能量(或密切相关的能量)的鞍点和相应的随时间变化问题的解自然出现在水波和燃烧理论等应用问题中。对于这类临界点--可以作为经典解的极限或奇异扰动问题的极限获得--奇异集是否可以很大以及该度量满足什么方程,自(Weiss,2003 年)以来一直是个未知数,二维情况除外。在本成果中,我们利用伯努利问题的频率公式以及著名的纳伯-瓦尔托塔程序等最新技术,以肯定的方式回答了这个已有 20 多年历史的问题:对于我们称之为伯努利问题变分解的一个封闭类别,我们证明了拓扑自由边界(包括退化奇异点,在此为 )是可数可校正的,并具有局部有限度量,而且我们完全确定了度量。这给出了任意维度下自由边界的更精确表征,甚至比以前在二维下的表征更精确。我们还证明了经典解(不一定是最小化解)的极限以及奇异扰动能量临界点的极限都是变分解,因此上述结果直接适用于所有这些解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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