Green’s function of heat equation for heterogeneous media in 3-D

IF 2.1 2区数学 Q1 MATHEMATICS

Communications in Partial Differential Equations Pub Date : 2022-09-08 DOI:10.1080/03605302.2022.2116717

C. Cheng, Tai-Ping Liu, Shih-Hsien Yu

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Abstract

Abstract The purpose of the present paper is to study the structure of Green’s function for heat equation in several spatial dimensions and with rough heat conductivity coefficient. We take the heat conductivity coefficient to be of bounded variation in the x direction and study the dispersion in the (y, z) direction. The goal is to understand the coupling of dissipation across rough heat conductivity and the multi-dimensional dispersion in the Green’s function A series of exponential functions of path integral with coefficients over a field of complex analytic functions around imaginary axis are formulated in the Laplace and Fourier transforms variables. The Green’s function in the transformed variables is written as the sum of these integrals over random paths. The integral over a random path is rearranged through the reflection property over a variation of heat conductivity coefficient and become a simple form in terms of path phase and amplitude. The complex analytic and combinatorics method is then used to yield a precise pointwise structure of the Green’s function in the physical domain

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三维非均匀介质热方程的格林函数

摘要本文的目的是研究具有粗糙导热系数的热方程在几个空间维度上的格林函数的结构。我们假定导热系数在x方向上具有有界变化，并研究了在（y，z）方向上的色散。目标是理解格林函数中粗糙导热率耗散和多维色散的耦合。在拉普拉斯和傅立叶变换变量中，在虚轴周围的复解析函数场上，一系列具有系数的路径积分指数函数被公式化。变换变量中的格林函数被写成随机路径上这些积分的和。随机路径上的积分通过导热系数变化上的反射特性重新排列，并成为路径相位和振幅的简单形式。然后使用复分析和组合学方法在物理域中产生格林函数的精确逐点结构

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 in Partial Differential Equations 数学-数学

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： This journal aims to publish high quality papers concerning any theoretical aspect of partial differential equations, as well as its applications to other areas of mathematics. Suitability of any paper is at the discretion of the editors. We seek to present the most significant advances in this central field to a wide readership which includes researchers and graduate students in mathematics and the more mathematical aspects of physics and engineering.