On the Maxwell-Bloch system in the sharp-line limit without solitons

IF 3.1 1区 数学 Q1 MATHEMATICS
Sitai Li, Peter D. Miller
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引用次数: 8

Abstract

We study the (characteristic) Cauchy problem for the Maxwell-Bloch equations of light-matter interaction via asymptotics, under assumptions that prevent the generation of solitons. Our analysis clarifies some features of the sense in which physically-motivated initial-boundary conditions are satisfied. In particular, we present a proper Riemann-Hilbert problem that generates the unique causal solution to the Cauchy problem, that is, the solution vanishes outside of the light cone. Inside the light cone, we relate the leading-order asymptotics to self-similar solutions that satisfy a system of ordinary differential equations related to the Painlevé-III (PIII) equation. We identify these solutions and show that they are related to a family of PIII solutions recently discovered in connection with several limiting processes involving the focusing nonlinear Schrödinger equation. We fully explain a resulting boundary layer phenomenon in which, even for smooth initial data (an incident pulse), the solution makes a sudden transition over an infinitesimally small propagation distance. At a formal level, this phenomenon has been described by other authors in terms of the PIII self-similar solutions. We make this observation precise and for the first time we relate the PIII self-similar solutions to the Cauchy problem. Our analysis of the asymptotic behavior satisfied by the optical field and medium density matrix reveals slow decay of the optical field in one direction that is actually inconsistent with the simplest version of scattering theory. Our results identify a precise generic condition on an optical pulse incident on an initially-unstable medium sufficient for the pulse to stimulate the decay of the medium to its stable state.

无孤子的直线极限下麦克斯韦-布洛赫系统
在防止产生孤子的假设下,我们通过渐近研究了光物质相互作用的Maxwell - Bloch方程的(特征)Cauchy问题。我们的分析阐明了满足物理驱动的初始边界条件的意义上的一些特征。特别地,我们提出了一个适当的黎曼-希尔伯特问题,该问题产生柯西问题的唯一因果解,即解在光锥外消失。在光锥内,我们将首阶渐近解与一类与painlevev - III (PIII)方程相关的常微分方程组的自相似解联系起来。我们确定了这些解,并表明它们与最近在涉及聚焦非线性Schrödinger方程的几个极限过程中发现的PIII解族有关。我们充分解释了一种边界层现象,在这种现象中,即使对于平滑的初始数据(入射脉冲),解也会在无限小的传播距离上发生突然转变。在正式层面上,这一现象已经被其他作者用PIII自相似解来描述。我们使这一观察精确,并首次将PIII自相似解与柯西问题联系起来。我们对光场和中密度矩阵所满足的渐近行为的分析揭示了光场在一个方向上的缓慢衰减,这实际上与最简单的散射理论不一致。我们的结果确定了光脉冲入射到初始不稳定介质上的一个精确的一般条件,足以使脉冲刺激介质衰减到稳定状态。
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
CiteScore
6.70
自引率
3.30%
发文量
59
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.
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