A relative trace formula for obstacle scattering

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Florian Hanisch, A. Strohmaier, Alden Waters
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引用次数: 9

Abstract

We consider the case of scattering of several obstacles in $\mathbb{R}^d$ for $d \geq 2$. Then the absolutely continuous part of the Laplace operator $\Delta$ with Dirichlet boundary conditions and the free Laplace operator $\Delta_0$ are unitarily equivalent. For suitable functions that decay sufficiently fast we have that the difference $g(\Delta)-g(\Delta_0)$ is a trace-class operator and its trace is described by the Krein spectral shift function. In this paper we study the contribution to the trace (and hence the Krein spectral shift function) that arises from assembling several obstacles relative to a setting where the obstacles are completely separated. In the case of two obstacles we consider the Laplace operators $\Delta_1$ and $\Delta_2$ obtained by imposing Dirichlet boundary conditions only on one of the objects. Our main result in this case states that then $g(\Delta) - g(\Delta_1) - g(\Delta_2) + g(\Delta_0)$ is a trace class operator for a much larger class of functions (including functions of polynomial growth) and that this trace may still be computed by a modification of the Birman-Krein formula. In case $g(x)=x^\frac{1}{2}$ the relative trace has a physical meaning as the vacuum energy of the massless scalar field and is expressible as an integral involving boundary layer operators. Such integrals have been derived in the physics literature using non-rigorous path integral derivations and our formula provides both a rigorous justification as well as a generalisation.
障碍物散射的相对轨迹公式
我们考虑几个障碍物散射的情况 $\mathbb{R}^d$ 为了 $d \geq 2$. 然后是拉普拉斯算子的绝对连续部分 $\Delta$ 用Dirichlet边界条件和自由拉普拉斯算子 $\Delta_0$ 都是一元等价的。对于衰减足够快的合适函数,我们有这个区别 $g(\Delta)-g(\Delta_0)$ 是一个迹类算子,其迹由Krein谱移函数描述。在本文中,我们研究了相对于障碍物完全分离的设置组装几个障碍物而产生的对迹(以及因此产生的Krein谱移函数)的贡献。在有两个障碍物的情况下,我们考虑拉普拉斯算子 $\Delta_1$ 和 $\Delta_2$ 通过只对其中一个对象施加狄利克雷边界条件而得到。在这种情况下,我们的主要结果表明,那么 $g(\Delta) - g(\Delta_1) - g(\Delta_2) + g(\Delta_0)$ 是更大的函数类(包括多项式增长的函数)的跟踪类算子,并且该跟踪仍然可以通过对Birman-Krein公式的修改来计算。以防万一 $g(x)=x^\frac{1}{2}$ 相对迹线作为无质量标量场的真空能具有物理意义,可表示为涉及边界层算符的积分。这样的积分已经在物理文献中使用非严格路径积分推导得到,我们的公式提供了严格的证明以及推广。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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