Gain and Loss Fluctuations in Nonlinear Optical Systems

International Meeting on Instabilities and Dynamics of Lasers and Nonlinear Optical Systems Pub Date : 1900-01-01 DOI:10.1364/idlnos.1985.thd3

A. Schenzle

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Abstract

The interaction of light and matter can be described by a set of coupled nonlinear evolution equations for the material and electromagnetic fields. In order to account for the effects of vacuum fluctuations, noise forces which cause spontaneous transitions have to be included. In these macroscopic systems various sources of noise besides fundamental quantum fluctuations exist which are of macroscopic origin. These cause fluctuations of the cavity dissipation as well as of the external pumping power. In the course of an adiabatic elimination procedure, these fluctuations appear as multiplicative noise in the equations of motion (e.g. for the field intensity, due to the nonlinearity of the interaction). While fluctuations of the cavity damping create noise linear in the field intensity, randomness in the pump strength causes fluctuations that depend nonlinearly on the light intensity. In this respect, the noise terms enter the equations of motion quite differently and have to be distinguished from spontaneous emission noise which is independent of the field strength, and is the basis of all traditional laser models.

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非线性光学系统的增益和损耗波动

光与物质的相互作用可以用一组材料与电磁场耦合的非线性演化方程来描述。为了解释真空波动的影响，必须包括引起自发跃迁的噪声力。在这些宏观系统中，除了基本的量子涨落之外，还存在着各种各样的噪声源，它们都是宏观起源的。这些会引起腔体耗散和外部泵浦功率的波动。在绝热消除过程中，这些波动在运动方程中表现为乘法噪声(例如，由于相互作用的非线性，对于场强)。当腔体阻尼的波动产生场强度线性的噪声时，泵浦强度的随机性引起的波动非线性地依赖于光强。在这方面，噪声项进入运动方程的方式非常不同，必须与自发发射噪声区分开来，自发发射噪声与场强无关，是所有传统激光模型的基础。

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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International Meeting on Instabilities and Dynamics of Lasers and Nonlinear Optical Systems

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