Embedding theory contributions to average atom models for warm dense matter

arXiv - PHYS - Plasma Physics Pub Date : 2024-09-03 DOI:arxiv-2409.02105

Sameen Yunus, David A. Strubbe

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Abstract

Accurate modeling in the warm dense matter regime is a persistent challenge with the most detailed models such as quantum molecular dynamics and path integral Monte Carlo being immensely computationally expensive. Density functional theory (DFT)-based average atom models (AAM) offer significant speed-ups in calculation times while still retaining fair accuracy in evaluating equations of state, mean ionizations, and more. Despite their success, AAMs struggle to precisely account for electronic interactions -- in particular, they do not account for effects on the kinetic energy arising from overlaps in neighboring atom densities. We aim to enhance these models by including such interactions via the non-additive kinetic potential $v^{\rm nadd}$ as in DFT embedding theories. $v^{\rm nadd}$ can be computed using Thomas-Fermi, von Weizs\"acker, or more sophisticated kinetic energy functionals. The proposed model introduces $v^{\rm nadd}$ as a novel interaction term in existing ion-correlation models, which include interactions beyond the central atom. We have applied this model to hydrogen at 5 eV and densities ranging 0.008 to 0.8 g/cm$^3$, and investigated the effects of $v^{\rm nadd}$ on electron densities, Kohn-Sham energy level shifts, mean ionization, and total energies.

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嵌入理论对暖致密物质平均原子模型的贡献

在暖致密物质体系中进行精确建模是一项长期的挑战，量子分子动力学和路径积分蒙特卡罗等最详细的模型计算成本都非常昂贵。基于密度函数理论（DFT）的平均原子模型（AAM）在计算时间上大大加快，同时在评估状态方程、平均电离度等方面仍然保持相当的准确性。尽管取得了成功，但平均原子模型在精确解释电子相互作用方面仍有困难，特别是它们无法解释相邻原子密度的重叠对动能的影响。我们的目标是通过DFT嵌入理论中的非相加动势$v^{\rm nadd}$将这种相互作用包括进来，从而增强这些模型。$v^{\rm nadd}$可以用托马斯-费米、冯-魏茨（von Weizs\"acker ）或更复杂的动能函数来计算。所提出的模型在现有的离子相关模型中引入了$v^{rm nadd}$作为新的相互作用项，其中包括中心原子之外的相互作用。我们将该模型应用于 5 eV 和密度范围为 0.008 至 0.8 g/cm$^^3$ 的氢，并研究了 $v^{rm nadd}$ 对电子密度、Kohn-Sham 能级移动、平均离子化和总能量的影响。

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arXiv - PHYS - Plasma Physics

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