On an Angle-Averaged Neumann-to-Dirichlet Map for Thin Filaments

IF 2.6 1区数学 Q1 MATHEMATICS, APPLIED Archive for Rational Mechanics and Analysis Pub Date : 2024-12-20 DOI:10.1007/s00205-024-02079-4

Laurel Ohm

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Abstract

We consider the Laplace equation in the exterior of a thin filament in \(\mathbb {R}^3\) and perform a detailed decomposition of a notion of slender body Neumann-to-Dirichlet (NtD) and Dirichlet-to-Neumann (DtN) maps along the filament surface. The decomposition is motivated by a filament evolution equation in Stokes flow for which the Laplace setting serves as an important toy problem. Given a general curved, closed filament with constant radius \(\varepsilon >0\), we show that both the slender body DtN and NtD maps may be decomposed into the corresponding operator about a straight, periodic filament plus lower order remainders. For the straight filament, both the slender body NtD and DtN maps are given by explicit Fourier multipliers and it is straightforward to compute their mapping properties. The remainder terms are lower order in the sense that they are small with respect to \(\varepsilon \) or smoother. While the strategy here is meant to serve as a blueprint for the Stokes setting, the Laplace problem may be of independent interest.

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细细丝的角平均neumann - dirichlet映射

我们考虑了\(\mathbb {R}^3\)中细灯丝外部的拉普拉斯方程，并对沿灯丝表面的细长体Neumann-to-Dirichlet （NtD）和Dirichlet-to-Neumann （DtN）映射的概念进行了详细的分解。分解是由斯托克斯流中的细丝演化方程驱动的，其中拉普拉斯设定是一个重要的玩具问题。给定一个半径为\(\varepsilon >0\)的一般弯曲闭合灯丝，我们证明了细长体DtN和NtD映射都可以分解为关于一个直周期灯丝加上低阶余数的相应算子。对于直丝，细长体的NtD和DtN映射都是由显式傅里叶乘子给出的，计算它们的映射性质很简单。其余的项是低阶的，因为它们相对于\(\varepsilon \)较小或者更平滑。虽然这里的策略是作为Stokes设置的蓝图，拉普拉斯问题可能是独立的兴趣。

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来源期刊

Archive for Rational Mechanics and Analysis 物理-力学

CiteScore

5.10

自引率

8.00%

发文量

审稿时长

4-8 weeks

期刊介绍： The Archive for Rational Mechanics and Analysis nourishes the discipline of mechanics as a deductive, mathematical science in the classical tradition and promotes analysis, particularly in the context of application. Its purpose is to give rapid and full publication to research of exceptional moment, depth and permanence.