Theoretical Determination of the Laser Induced Damage Threshold for Ultrashort Pulse Laser Heating of Metal Films

Microelectromechanical Systems (MEMS) Pub Date : 1997-11-16 DOI:10.1115/imece1997-0954

A. Smith, P. Norris, Anthony Lee

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Abstract

Non-equilibrium heating between electrons and the crystalline lattice has been observed in numerous ultrashort pulsed laser applications yielding unexpected temperature profiles. Typically, laser induced damage threshold (LIDT) values for thin metal films are predicted using the melting temperature and the standard heat diffusion equation. A method is presented which accounts for non-equilibrium heating by solving the Parabolic Two Step (PTS) heat conduction model and deriving an analytical expression for the laser power that causes the film temperature to exceed a critical value. This critical temperature is a design parameter dependent on the material properties of the film and often the repetition rate of the source. In non-equilibrium heating, the predicted peak lattice temperature is significantly lower and occurs at some time after the deposition of energy, which can be orders of magnitude greater than the pulse duration. This minimizes the effect of the temporal shape of the pulse and allows for an analytical solution. This solution and an equation which can be used to calculate the thermal damage threshold value for non-equilibrium laser heating are presented.

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超短脉冲激光加热金属薄膜激光致伤阈值的理论确定

在许多超短脉冲激光应用中，观察到电子和晶格之间的非平衡加热产生意想不到的温度分布。通常，激光诱导损伤阈值(LIDT)的金属薄膜的预测使用熔化温度和标准热扩散方程。通过求解抛物线两步(PTS)热传导模型，推导出导致薄膜温度超过临界值的激光功率解析表达式，提出了一种解释非平衡加热的方法。这个临界温度是一个设计参数，取决于薄膜的材料特性和光源的重复频率。在非平衡加热中，预测的晶格峰值温度明显较低，并且发生在能量沉积后的某个时间，其可能比脉冲持续时间大几个数量级。这最大限度地减少了脉冲的时间形状的影响，并允许分析解决。给出了该解和非平衡激光加热热损伤阈值的计算公式。

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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Microelectromechanical Systems (MEMS)

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