无序金属、暖致密物质和热致密等离子体的群电导率和非绝热博恩有效电荷

arXiv - PHYS - Plasma Physics Pub Date : 2024-08-29 DOI:arxiv-2408.16230

Vidushi Sharma, Alexander J. White

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引用次数: 0

摘要

平均电离状态是等离子体模型中关于带电粒子传输、状态方程和光学响应的关键参数。通过第一原理随时间变化的密度泛函理论计算得出的动态或非绝热天生有效电荷（NBEC）为金属和绝缘材料的体电子响应提供了精确的离子分区。NBEC 可以简单地转化为 "基团电导率"，即归因于离子子集的电子电导率。我们证明，对于无序金属系统，如温致密物质（WDM）和热致密等离子体，NBEC 的静态极限与平均电离态不同，但即使在混合系统中，电离态也可以从群导率中提取出来。我们利用一组典型的例子演示了这种方法，包括冷铝和暖铝、低密度和高密度波长多波长碳以及波长多波长碳-铍-氢混合物。

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Group Conductivity and Nonadiabatic Born Effective Charges of Disordered Metals, Warm Dense Matter and Hot Dense Plasma

The average ionization state is a critical parameter in plasma models for charged particle transport, equation of state, and optical response. The dynamical or nonadiabatic Born effective charge (NBEC), calculated via first principles time-dependent density functional theory, provides exact ionic partitioning of bulk electron response for both metallic and insulating materials. The NBEC can be trivially transformed into a ''group conductivity", that is, the electron conductivity ascribed to a subset of ions. We show that for disordered metallic systems, such as warm dense matter (WDM) and hot dense plasma, the static limit of the NBEC is different from the average ionization state, but that the ionization state can be extracted from the group conductivity even in mixed systems. We demonstrate this approach using a set of archetypical examples, including cold and warm aluminium, low- and high- density WDM carbon, and a WDM carbon-beryllium-hydrogen mixture.

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arXiv - PHYS - Plasma Physics

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