Diffraction of electromagnetic pulses in a single-resonance Lorentz model dielectric

Pure and Applied Optics: Journal of The European Optical Society Part A Pub Date : 1998-09-01 DOI:10.1088/0963-9659/7/5/016

J. Solhaug, J. Stamnes, K. Oughstun

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引用次数: 5

Abstract

We study the behaviour of a plane-wave delta-function pulse that is diffracted at an edge in a dispersive medium. In particular, we show that the edge-diffraction process by itself is dispersive and adds to the dispersion induced by the medium in such a way as to completely change the behaviour of the Brillouin precursor. The dispersion associated with edge diffraction manifests itself through the appearance of a new algebraic singularity near the origin. Since the Sommerfeld precursor field is due to asymptotic contributions from saddle points that always stay far from the origin, the character of this field is not changed by the new singularity induced by edge diffraction. The Brillouin precursor field, however, is due to asymptotic contributions from saddle points that are close to the origin, and therefore the new singularity changes its behaviour dramatically. Numerical illustrations of the evolution of the edge-diffracted pulse are given and the behaviour of the Brillouin precursor field is explained both mathematically and physically.

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单共振洛伦兹模型电介质中电磁脉冲的衍射

我们研究了色散介质中在边缘处衍射的平面波δ函数脉冲的行为。特别地，我们证明了边缘衍射过程本身是色散的，并且增加了介质引起的色散，从而完全改变了布里渊前驱体的行为。与边缘衍射有关的色散表现为在原点附近出现一个新的代数奇点。由于Sommerfeld前驱场是由远离原点的鞍点的渐近贡献引起的，因此边缘衍射引起的新奇点不会改变该场的性质。然而，布里渊前驱场是由于接近原点的鞍点的渐近贡献，因此新的奇点极大地改变了它的行为。给出了边缘衍射脉冲演化的数值说明，并从数学和物理上解释了布里渊前驱场的行为。

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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Pure and Applied Optics: Journal of The European Optical Society Part A

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