基于大型激光装置的材料塑性变形行为微介观研究进展  被引量：1

作　　者：王倩男 胡建波[1] Wang Qiannan;Hu Jianbo(State Key Laboratory for Shock Wave and Detonation Physics,Institute of Fluid Physics,CAEP,Mianyang 621900,China)

机构地区：[1]中国工程物理研究院流体物理研究所,冲击波与爆轰物理国家重点实验室,四川绵阳621900

出　　处：《强激光与粒子束》2020年第11期112-120,共9页High Power Laser and Particle Beams

基　　金：科学挑战专题项目(TZ2018001);中物院创新发展基金培育项目(PY2020007);冲击波物理与爆轰物理实验室装备预研基金项目(6142A0301010117)。

摘　　要：微介观尺度下材料结构的实时演化行为是决定其动态力学性能的关键因素。大型激光装置作为集加载和诊断能力为一体的综合实验平台,为高温、高压、高应变率等极端条件下材料动态力学性能的微介观尺度研究提供了重要支撑。随着激光功率密度和脉冲整形能力的不断提升,实验所能探索的压力(10^1~10^3 GPa)及应变率(10^6~10^10 s^−1)范围不断突破;而利用激光打靶产生的高亮X射线脉冲作为探测源,建立动态衍射和成像技术,可以实现高空间和时间分辨率下材料塑性变形机制的实时原位研究。简要介绍了基于大型激光装置的原位微介观实验技术及其在材料塑性变形行为研究中的应用,系统梳理了近二十年来具有代表性的研究成果,阐明了相关研究对推动材料动态响应多尺度物理建模的重要价值。The dynamic response of materials is strongly dependent on the temporal evolution of microstructures.As a comprehensive experimental platform integrating dynamic loading and in-situ diagnostic capability,large-scale laser facilities provide technical support to investigate micro-mesoscopic behaviors of materials under extreme conditions of high temperature,high pressure,and high strain rate.The use of high-power pulsed lasers to explore the response of materials under the pressure of tens of GPa up to several TPa,the time duration of nanoseconds,and the strain rate of 10^6−10^10 s^−1 is revealing novel mechanisms of plastic deformation and therefore strength evolution.This unique experimental tool,aided by advanced diagnostics,analysis,and characterization,including X-ray diffraction,absorption and imaging,allows us to make real-time observation on these new regimes with high spatial and temporal resolution.In this paper,we review the progress within the last 20 years in micromesoscopic dynamic probing techniques,based on large-scale laser facilities,and their applications in the study of dynamic plasticity and strength.At the end,we discuss the significance of these works to promote the multiscale modeling of the dynamic response of materials.

关 键 词：动态强度 塑性机制 微介观 动态X射线衍射 大型激光装置 

分 类 号：O347.3[理学—固体力学]