非平衡温致密金中交流电导率的演化

Y. Tsui, Z. Chen, B. Holst, S. Kirkwood, V. Sametoglu, M. Reid, V. Recoules, A. Ng
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引用次数: 0

摘要

交流电导率一直是热致密物质电子结构和输运性质研究的热点。利用啁啾脉冲探针技术,我们获得了在能量密度高达4.1MJ/kg (8×1010J/m3)的飞秒激光加热产生的非平衡热致密金的电子能量弛豫过程中交流电导率的单次测量。研究结果揭示了在早期研究中被掩盖的重要变化。同样重要的是,他们提供了测试ab-initio模型的第一个基准,该模型用于在单一的第一性原理框架中计算电子热容量,电子-离子耦合和交流电导率。虽然对交流电导率实部的测量证实了我们理论中与温度相关的电子热容,但它们指出电子-离子耦合系数为~2.2×1016W/m3 K,大大低于理论预测的值。此外,对交流电导率虚部的测量表明,需要改进在极低光子能量下带内贡献的理论处理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evolution of AC conductivity in non-equilibrium warm dense gold
AC conductivity has long been of interest in the study of electronic structure and transport properties of Warm Dense Matter. Using a chirped pulse probe technique, we have obtained single-shot measurements of the temporal evolution of AC conductivity during electron energy relaxation in non-equilibrium warm dense gold produced by femtosecond-laser heating with energy density up to 4.1MJ/kg (8×1010J/m3). The results uncover important changes that have been masked in earlier studies. Equally significant, they provide the first benchmark for testing an ab-initio model that is used to calculate electron heat capacity, electron-ion coupling and AC conductivity in a single, first principles framework. While measurements of the real part of AC conductivity corroborate our theoretical temperature-dependent electron heat capacity, they point to an electron-ion coupling factor of ~2.2×1016W/m3 K, substantially below that predicted by theory. In addition, measurements of the imaginary part of AC conductivity reveal the need to improve theoretical treatment of intraband contribution at very low photon energy.
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