Self-consistent modeling of photoionization and the Kerr effect in bulk solids

J. Gulley, T. Lanier
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引用次数: 2

Abstract

In calculations of ultrafast laser-induced ionization the treatment of fundamental mechanisms such as photoionization and the Kerr effect are treated in isolation using monochromatic perturbative approaches. Such approaches are often questionable for pulses of ultrashort duration and multi-chromatic spectra. In this work we address this issue by solving the quantum optical Bloch equations in a 3D quasi-momentum space and show how to couple this model to ultrashort pulse propagation in dielectrics. This approach self-consistently couples a quantum calculation of the photoionization yield, the photoionization current, and the current from free-carriers with the traditional Kerr effect (self-focusing and self phase modulation) without resort to a perturbative treatment. The material band structure is taken in the tight binding limit and is periodic in the crystal momentum space. As this model makes no assumption about the pulse spectrum, we examine the laser-material interaction of strongly chirped pulses and multi-color multi-pulse schemes of laser-induced material modification. These results are compared to those predicted by standard treatments, such as the Keldysh model of photoionization, for pulses of ultrashort duration.
大块固体中光电离和克尔效应的自洽模型
在超快激光诱导电离的计算中,光电离和克尔效应等基本机制的处理是用单色微扰方法单独处理的。对于超短持续时间和多色光谱的脉冲,这种方法往往值得怀疑。在这项工作中,我们通过在三维准动量空间中求解量子光学布洛赫方程来解决这个问题,并展示了如何将该模型耦合到介电介质中的超短脉冲传播。这种方法自一致地耦合了光离产率、光离电流和自由载流子电流的量子计算,并具有传统的克尔效应(自聚焦和自相位调制),而不需要采用微扰处理。材料带结构在紧密结合极限内,在晶体动量空间内具有周期性。由于该模型没有对脉冲谱进行假设,我们研究了强啁啾脉冲和激光诱导材料改性的多色多脉冲方案的激光与材料的相互作用。这些结果与标准处理方法(如Keldysh光电离模型)对超短持续时间脉冲的预测结果进行了比较。
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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