Determining the bandgap dependence of nonlinear absorption and laser induced damage threshold through numerical simulation and experiment

Laser Damage Pub Date : 2023-11-24 DOI:10.1117/12.2685160
Joshua McCauley, Xiaochuan Ji, M. Jupé, Jinlong Zhang, Andreas Wienke, Detlev Ristau
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Abstract

Nonlinear absorption is mainly governed by mechanisms involving excitation processes of electrons. Typically, two phenomena are considered when discussing nonlinear absorption; the multiphoton absorption where multiple photons interact directly with a single electron, and tunnel ionization, where the high electric field results in a shifting of the bandgap allowing an electron to tunnel into the conduction band. Electrons in the conduction band can be accelerated through the absorption of further photons until they obtain enough energy to excite further electrons to the conduction band, leading to runaway absorption and finally damage of the sample. By laser calorimetric measurement of the nonlinear absorption, it is expected that the laser damage threshold can be predicted without damaging the optic. Before accurate predictions can be made, the process must be thoroughly characterized and understood. The nonlinear behavior of the absorption was demonstrated with potential increases in absorption of an order of magnitude. Initial results show a noticeable impact of contaminants, though a nonlinear response is still observed.
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通过数值模拟和实验确定非线性吸收和激光诱导损伤阈值的带隙依赖性
非线性吸收主要受电子激发过程机制的制约。在讨论非线性吸收时,通常会考虑两种现象:一种是多光子吸收,即多个光子直接与单个电子相互作用;另一种是隧道电离,即高电场导致带隙移动,使电子以隧道方式进入传导带。导带中的电子可以通过吸收更多的光子而加速,直到获得足够的能量来激发更多的电子进入导带,从而导致吸收失控,最终损坏样品。通过对非线性吸收进行激光量热测量,有望在不损坏光学器件的情况下预测激光损坏阈值。在进行准确预测之前,必须对这一过程进行彻底的表征和理解。吸收的非线性行为得到了证实,吸收可能会增加一个数量级。初步结果表明,尽管仍可观察到非线性响应,但污染物的影响非常明显。
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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