氮化硼在 16 Mbar 条件下沿主休戈诺的状态方程

IF 4.8 1区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Matter and Radiation at Extremes Pub Date : 2024-08-16 DOI:10.1063/5.0206889
Huan Zhang, Yutong Yang, Weimin Yang, Zanyang Guan, Xiaoxi Duan, Mengsheng Yang, Yonggang Liu, Jingxiang Shen, Katarzyna Batani, Diluka Singappuli, Ke Lan, Yongsheng Li, Wenyi Huo, Hao Liu, Yulong Li, Dong Yang, Sanwei Li, Zhebin Wang, Jiamin Yang, Zongqing Zhao, Weiyan Zhang, Liang Sun, Wei Kang, Dimitri Batani
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引用次数: 0

摘要

氮化硼在极端压力和温度下的热力学性质对材料科学和惯性约束核聚变物理具有极大的兴趣和重要性,但由于进行实验和实现非初始计算所面临的挑战,人们对其了解甚少。在这里,我们首次报告了在中国 SGIII-p 激光设备上使用霍勒姆驱动的冲击波在 5-16 Mbar 压力下六方氮化硼的冲击休格尼奥特数据。我们的密度泛函理论分子动力学计算结果与实验数据非常吻合,验证了氮化硼冲击响应建模的状态方程,填补了多巴压力和电子伏特温度区域氮化硼特性知识的重要空白。本文介绍的结果提供了在与惯性约束聚变、氢硼聚变和高能量密度物理学相关的极端条件下氮化硼的基本见解。
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Equation of state for boron nitride along the principal Hugoniot to 16 Mbar
The thermodynamic properties of boron nitride under extreme pressures and temperatures are of great interest and importance for materials science and inertial confinement fusion physics, but they are poorly understood owing to the challenges of performing experiments and realizing ab initio calculations. Here, we report the first shock Hugoniot data on hexagonal boron nitride at pressures of 5–16 Mbar, using hohlraum-driven shock waves at the SGIII-p laser facility in China. Our density functional theory molecular dynamics calculations closely match experimental data, validating the equations of state for modeling the shock response of boron nitride and filling a crucial gap in the knowledge of boron nitride properties in the region of multi-Mbar pressures and eV temperatures. The results presented here provide fundamental insights into boron nitride under the extreme conditions relevant to inertial confinement fusion, hydrogen–boron fusion, and high-energy-density physics.
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来源期刊
Matter and Radiation at Extremes
Matter and Radiation at Extremes Physics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
8.60
自引率
9.80%
发文量
160
审稿时长
15 weeks
期刊介绍: Matter and Radiation at Extremes (MRE), is committed to the publication of original and impactful research and review papers that address extreme states of matter and radiation, and the associated science and technology that are employed to produce and diagnose these conditions in the laboratory. Drivers, targets and diagnostics are included along with related numerical simulation and computational methods. It aims to provide a peer-reviewed platform for the international physics community and promote worldwide dissemination of the latest and impactful research in related fields.
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