Uniqueness, regularity, and characteristic flow for a non strictly convex singular variational problem

IF 2.7 1区数学 Q1 MATHEMATICS

Communications on Pure and Applied Mathematics Pub Date : 2025-10-17 DOI:10.1002/cpa.70015

Jean‐François Babadjian, Gilles A. Francfort

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引用次数: 0

Abstract

This work addresses the question of uniqueness and regularity of the minimizers of a convex but not strictly convex integral functional with linear growth in a two‐dimensional setting. The integrand – whose precise form derives directly from the theory of perfect plasticity – behaves quadratically close to the origin and grows linearly once a specific threshold is reached. Thus, in contrast with the only existing literature on uniqueness for functionals with linear growth, that is that which pertains to the generalized least gradient, the integrand is not a norm. We make use of hyperbolic conservation laws hidden in the structure of the problem to tackle uniqueness. Our argument strongly relies on the regularity of a vector field – the Cauchy stress in the terminology of perfect plasticity – which allows us to define characteristic lines and then to employ the method of characteristics. Using the detailed structure of the characteristic landscape evidenced in our preliminary study [5], we show that this vector field is actually continuous, save for possibly two points. The different behaviors of the energy density at zero and at infinity imply an inequality constraint on the Cauchy stress. Under a barrier type convexity assumption on the set where the inequality constraint is saturated, we show that uniqueness holds for pure Dirichlet boundary data devoid of any regularity properties, a stronger result than that of uniqueness for a given trace on the whole boundary since our minimizers can fail to attain the boundary data. We also show a partial regularity result for the minimizer.

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一类非严格凸奇异变分问题的唯一性、规律性和特征流

这项工作解决了在二维环境下具有线性增长的凸而非严格凸积分泛函的最小值的唯一性和正则性问题。被积函数的精确形式直接来源于完美塑性理论，它在原点附近表现为二次型，一旦达到特定阈值就线性增长。因此，与现有的唯一关于线性增长泛函唯一性的文献（即属于广义最小梯度的文献）相反，被积函数不是范数。我们利用隐藏在问题结构中的双曲守恒定律来解决唯一性问题。我们的论证强烈地依赖于向量场的规律性——完全塑性术语中的柯西应力——它允许我们定义特征线，然后使用特征方法。利用我们在初步研究[5]中所证明的特征景观的详细结构，我们表明这个向量场实际上是连续的，除了可能有两点。能量密度在零和无穷远处的不同行为暗示了柯西应力的不平等约束。在不等式约束饱和的集合上的屏障型凸性假设下，我们证明了不具有任何正则性的纯Dirichlet边界数据的唯一性，这一结果比在整个边界上给定轨迹的唯一性更强，因为我们的最小化器无法获得边界数据。我们还展示了最小化器的部分正则性结果。

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

Communications on Pure and Applied Mathematics 数学-数学

CiteScore

6.70

自引率

3.30%

发文量

审稿时长

>12 weeks

期刊介绍： Communications on Pure and Applied Mathematics (ISSN 0010-3640) is published monthly, one volume per year, by John Wiley & Sons, Inc. © 2019. The journal primarily publishes papers originating at or solicited by the Courant Institute of Mathematical Sciences. It features recent developments in applied mathematics, mathematical physics, and mathematical analysis. The topics include partial differential equations, computer science, and applied mathematics. CPAM is devoted to mathematical contributions to the sciences; both theoretical and applied papers, of original or expository type, are included.