多脉冲超快激光与铜相互作用的分子动力学研究

IF 2.8 3区 工程技术 Q2 ENGINEERING, MANUFACTURING
C. Yin, S. Zhang, Y.W. Dong, Q. Ye, Q. Li
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引用次数: 4

摘要

超快激光以其极小的脉冲宽度和极高的峰值能量在激光加工中具有不可否认的优势。而超快激光与固体材料的相互作用是一个极不平衡的过程,材料在极短的时间内发生相变甚至烧蚀。这是由压力波引起的热弹性效应和材料晶格的过热熔化的耦合作用。为了进一步探讨超快激光与金属材料的作用机理,采用双温度耦合模型与分子动力学方法模拟了铜与激光能量的相互作用。首先,再现了单脉冲激光与铜膜的相互作用,利用计算得到的双温曲线和可视化的原子快照研究了激光参数对烧蚀结果的影响。然后,通过改变原子体系的尺寸,得到了烧蚀深度随激光通量的函数曲线。本文计算了多脉冲激光与铜的相互作用。得到了双脉冲和多脉冲激光辐照后铜膜的双温曲线和温度曲线。并对影响培养效果的因素进行了分析。通过计算多脉冲激光作用下的烧蚀深度,进一步探讨了孵育效应对烧蚀结果的影响。最后,通过超短激光加工实验,建立了更为精确的激光加工金属数值模型,为航空涡轮叶片气膜孔的超快激光加工提供了新的计算方法和理论依据,对激光加工具有一定的实际指导意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecular-dynamics study of multi-pulsed ultrafast laser interaction with copper
Ultrafast laser has an undeniable advantage in laser processing due to its extremely small pulse width and high peak energy. While the interaction of ultrafast laser and solid materials is an extremely non-equilibrium process in which the material undergoes phase transformation and even ablation in an extremely short time range. This is the coupling of the thermos elastic effect caused by the pressure wave and the superheated melting of the material lattice. To further explore the mechanism of the action of ultrafast laser and metal materials, the two-temperature model coupling with molecular dynamics method was used to simulate the interaction of the copper and laser energy. Firstly, the interaction of single-pulsed laser and copper film was reproduced, and the calculated two-temperature curve and the visualized atomic snapshots were used to investigate the influence of laser parameters on the ablation result. Then, by changing the size of the atomic system, the curve of ablation depth as a function of laser fluence was obtained. In this paper, the interaction of multi-pulsed laser and copper was calculated. Two-temperature curve and temperature contour of copper film after the irradiation of double-pulsed and multi-pulsed laser were obtained. And the factors which can make a difference to the incubation effect were analyzed. By calculating the ablation depth under the action of multi-pulsed laser, the influence of the incubation effect on ablation results was further explored. Finally, a more accurate numerical model of laser machining metal is established and verified by an ultra-short laser processing experiment, which provides a new calculation method and theoretical basis for ultra-fast laser machining of air film holes in aviation turbine blades, and has certain practical guiding significance for laser machining.
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来源期刊
Advances in Production Engineering & Management
Advances in Production Engineering & Management ENGINEERING, MANUFACTURINGMATERIALS SCIENC-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
5.90
自引率
22.20%
发文量
19
期刊介绍: Advances in Production Engineering & Management (APEM journal) is an interdisciplinary international academic journal published quarterly. The main goal of the APEM journal is to present original, high quality, theoretical and application-oriented research developments in all areas of production engineering and production management to a broad audience of academics and practitioners. In order to bridge the gap between theory and practice, applications based on advanced theory and case studies are particularly welcome. For theoretical papers, their originality and research contributions are the main factors in the evaluation process. General approaches, formalisms, algorithms or techniques should be illustrated with significant applications that demonstrate their applicability to real-world problems. Please note the APEM journal is not intended especially for studying problems in the finance, economics, business, and bank sectors even though the methodology in the paper is quality/project management oriented. Therefore, the papers should include a substantial level of engineering issues in the field of manufacturing engineering.
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