Formation of nanoparticles by short and ultra-short laser pulses

High-Power Laser Ablation Pub Date : 2008-05-08 DOI:10.1117/12.782711

K. Gouriet, T. Itina, S. Noël, J. Hermann, M. Sentis, L. Zhigilei

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引用次数: 2

Abstract

The main objective of this study is to explain the experimental observations. To simulate material ablation, plume formation and its evolution, we developed a combined molecular dynamics (MD) and direct simulation Monte Carlo (DSMC) computational study of laser ablation plume evolution. The first process of the material ablation is described by the MD method. The expansion of the ejected plume is modelled by the DSMC method. To better understand the formation and the evolution of nanoparticles present in the plume, we first used separate MD simulations to analyse the evolution of a cluster in the presence of background gas with different properties (density, temperature). In particular, we examine evaporation and growth reactions of a cluster with different size and initial temperature. As a result of MD calculations, we determinate the influence of the background gas parameters on the nanoparticles. The reactions rates such as evaporation/condensation, which are obtained by MD simulations, are directly transferred to the DSMC part of our combined model. Finally, several calculations performed by using MD-DSMC model demonstrate both plume dynamics and longer-time cluster evolution. Calculations results are compared with experimental findings.

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短和超短激光脉冲形成纳米粒子

本研究的主要目的是解释实验观察结果。为了模拟物质烧蚀、羽流形成及其演化过程，采用分子动力学(MD)和直接模拟蒙特卡罗(DSMC)相结合的方法对激光烧蚀羽流演化过程进行了计算研究。用MD方法描述了材料烧蚀的第一个过程。用DSMC方法模拟了喷发羽流的膨胀过程。为了更好地理解羽流中纳米颗粒的形成和演化，我们首先使用单独的MD模拟来分析具有不同性质(密度、温度)的背景气体存在下星团的演化。特别地，我们研究了不同尺寸和初始温度的团簇的蒸发和生长反应。通过MD计算，我们确定了背景气体参数对纳米粒子的影响。由MD模拟得到的蒸发/冷凝等反应速率直接传递到组合模型的DSMC部分。最后，利用MD-DSMC模型进行了一些计算，证明了羽流动力学和较长时间的簇演化。计算结果与实验结果进行了比较。

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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High-Power Laser Ablation

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