Warm dense matter simulation via electron temperature dependent deep potential molecular dynamics

Yuzhi Zhang, Chang Gao, Qianrui Liu, Linfeng Zhang, Han Wang, Mohan Chen
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引用次数: 20

Abstract

Simulating warm dense matter that undergoes a wide range of temperatures and densities is challenging. Predictive theoretical models, such as quantum-mechanics-based first-principles molecular dynamics (FPMD), require a huge amount of computational resources. Herein, we propose a deep learning based scheme, called electron temperature dependent deep potential molecular dynamics (TDDPMD), for efficiently simulating warm dense matter with the accuracy of FPMD. The TDDPMD simulation is several orders of magnitudes faster than FPMD, and, unlike FPMD, its efficiency is not affected by the electron temperature. We apply the TDDPMD scheme to beryllium (Be) in a wide range of temperatures (0.4 to 2500 eV) and densities (3.50 to 8.25 g/cm$^3$). Our results demonstrate that the TDDPMD method not only accurately reproduces the structural properties of Be along the principal Hugoniot curve at the FPMD level, but also yields even more reliable diffusion coefficients than typical FPMD simulations due to its ability to simulate larger systems with longer time.
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通过依赖于电子温度的深势分子动力学模拟热致密物质
模拟温度和密度范围很大的温暖致密物质是一项挑战。预测理论模型,如基于量子力学的第一性原理分子动力学(FPMD),需要大量的计算资源。在此,我们提出了一种基于深度学习的方案,称为电子温度依赖的深势分子动力学(TDDPMD),以FPMD的精度有效地模拟温暖的致密物质。TDDPMD模拟比FPMD快几个数量级,并且与FPMD不同,其效率不受电子温度的影响。我们将TDDPMD方案应用于铍(Be)在宽温度(0.4至2500 eV)和密度(3.50至8.25 g/cm$^3$)范围内。我们的研究结果表明,TDDPMD方法不仅在FPMD水平上沿着主Hugoniot曲线准确地再现了Be的结构特性,而且由于其能够模拟更大的系统和更长的时间,因此比典型的FPMD模拟产生了更可靠的扩散系数。
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