物理学家对Kummer方程和合流超几何函数解的指导

IF 0.9 4区 物理与天体物理 Q4 PHYSICS, CONDENSED MATTER Condensed Matter Physics Pub Date : 2021-11-08 DOI:10.5488/CMP.25.33203
W. N. Mathews, M. A. Esrick, Z. Teoh, J. Freericks
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引用次数: 10

摘要

合流超几何方程,又称Kummer方程,是物理、化学和工程中最重要的微分方程之一。它的两个幂级数解是Kummer函数M(a,b,z),通常被称为第一类的合流超几何函数,M≡z1-bM(1+a-b, 2-b,z),其中a和b是出现在微分方程中的参数。第三种函数,Tricomi函数,U(A,b,z),有时被称为第二类超几何合流函数,也是通常使用的超几何合流方程的解。与一般程序相反,在寻找合流超几何方程的两个线性无关解时,必须考虑所有这三个函数(以及更多)。在某些情况下,当a b和a - b是整数时,其中一个函数没有定义,或者其中两个函数不是线性无关的,或者微分方程的一个线性无关解不同于这三个函数。这些特殊情况中的许多正好对应于解决物理问题所需的情况。尽管有权威的参考资料,如NIST数字函数库,但这导致了如何处理超几何方程的重大混乱。在这里,我们仔细地描述了人们必须考虑的所有不同情况,以及合流超几何方程的两个线性无关解的显式公式。正确求解合流超几何方程的步骤以方便的表格形式总结。作为一个例子,我们用这些溶液来研究氢原子的束缚态,纠正了教科书上的标准处理。我们还简要地考虑了截止库仑势。我们希望本指南能帮助物理学家正确地解决涉及超几何微分方程的问题。
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A physicist's guide to the solution of Kummer's equation and confluent hypergeometric functions
The confluent hypergeometric equation, also known as Kummer's equation, is one of the most important differential equations in physics, chemistry, and engineering. Its two power series solutions are the Kummer function, M(a,b,z), often referred to as the confluent hypergeometric function of the first kind, and M ≡ z1-bM(1+a-b, 2-b,z), where a and b are parameters that appear in the differential equation. A third function, the Tricomi function, U(a,b,z), sometimes referred to as the confluent hypergeometric function of the second kind, is also a solution of the confluent hypergeometric equation that is routinely used. Contrary to common procedure, all three of these functions (and more) must be considered in a search for the two linearly independent solutions of the confluent hypergeometric equation. There are situations, when a, b, and a - b are integers, where one of these functions is not defined, or two of the functions are not linearly independent, or one of the linearly independent solutions of the differential equation is different from these three functions. Many of these special cases correspond precisely to cases needed to solve problems in physics. This leads to significant confusion about how to work with confluent hypergeometric equations, in spite of authoritative references such as the NIST Digital Library of Mathematical Functions. Here, we carefully describe all of the different cases one has to consider and what the explicit formulas are for the two linearly independent solutions of the confluent hypergeometric equation. The procedure to properly solve the confluent hypergeometric equation is summarized in a convenient table. As an example, we use these solutions to study the bound states of the hydrogenic atom, correcting the standard treatment in textbooks. We also briefly consider the cutoff Coulomb potential. We hope that this guide will aid physicists to properly solve problems that involve the confluent hypergeometric differential equation.
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来源期刊
Condensed Matter Physics
Condensed Matter Physics 物理-物理:凝聚态物理
CiteScore
1.10
自引率
16.70%
发文量
17
审稿时长
1 months
期刊介绍: Condensed Matter Physics contains original and review articles in the field of statistical mechanics and thermodynamics of equilibrium and nonequilibrium processes, relativistic mechanics of interacting particle systems.The main attention is paid to physics of solid, liquid and amorphous systems, phase equilibria and phase transitions, thermal, structural, electric, magnetic and optical properties of condensed matter. Condensed Matter Physics is published quarterly.
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