大型激光装置驱动高压状态方程实验技术的发展与拓展

Development and expansion of high-pressure equation-of-state experimental techniques on large laser facilities

  • 摘要: 状态方程是描述材料在极端条件下热力学响应的基础,在激光聚变、高能量密度物理、行星内部物质及冲击动力学等研究中具有重要意义。大型激光装置凭借高功率密度、短脉冲和强加载能力,已成为获取超高压状态方程数据的重要平台。激光驱动状态方程实验的发展,经历了由高精度冲击雨贡纽测量向复杂初始状态调控、低熵压缩路径设计以及宽域热力学区域探测的逐步拓展。早期工作主要围绕冲击雨贡纽高压问题,系统解决了激光束匀滑、冲击波平面性与稳定传播、X射线预热抑制、阻抗匹配靶设计、标准材料应用及误差分析等关键技术问题,建立了大型激光装置开展高精度状态方程实验的基础能力。在此基础上,近年来相关研究进一步扩展到粉末、低温液氘等复杂初始状态样品,发展了适用于激光驱动条件的微型靶研制与初始态精密表征方法;同时,依托高质量加载和精密速度诊断能力,准等熵压缩与静—动结合加载等新型实验路径得到实现,使激光平台的状态方程研究由单一冲击路径向宽域、多路径协同测量发展。本文围绕大型激光装置上的高压状态方程实验技术主线,综述其从冲击雨贡纽基础能力建设到初始状态改变、准等熵压缩及静—动结合加载的发展脉络,分析不同阶段的关键实验问题及其内在联系,并对未来大型激光装置在宽域状态方程与动态物性研究中的发展方向进行展望。

     

    Abstract: The equation of state (EOS) is fundamental to describing the thermodynamic response of materials under extreme conditions and is of great importance in inertial confinement fusion, high-energy-density physics, planetary interior science, and shock dynamics. Owing to their high power density, short pulse duration, and strong loading capability, large laser facilities have become essential platforms for obtaining ultrahigh-pressure EOS data. The development of laser-driven EOS experiments has progressed from high-precision shock Hugoniot measurements to the control of complex initial states, the design of low-entropy compression paths, and the exploration of a broader thermodynamic regime. Early studies focused primarily on shock Hugoniot measurements at high pressure and systematically addressed key technical issues, including laser beam smoothing, shock planarity and stable propagation, suppression of X-ray preheating, impedance-matching target design, the use of standard materials, and uncertainty analysis, thereby establishing the foundational capability for high-precision EOS experiments on large laser facilities. On this basis, recent efforts have further expanded to samples with complex initial states, such as metal powders and cryogenic liquid deuterium, and have developed miniature target fabrication techniques and precise initial-state characterization methods suitable for laser-driven conditions. Meanwhile, supported by high-quality loading and precise velocity diagnostics, new experimental approaches, including quasi-isentropic compression and combined static–dynamic loading, have been realized, promoting EOS studies on laser platforms from single-shock paths to wide-range, multi-path coordinated measurements. This paper reviews the main development trajectory of high-pressure EOS experimental techniques on large laser facilities, from the establishment of fundamental capabilities for shock Hugoniot measurements to advances in initial-state control, quasi-isentropic compression, and combined static–dynamic loading. The key experimental issues at different stages and their intrinsic connections are analyzed, and future directions for large laser facilities in wide-range EOS and dynamic property studies are discussed.

     

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