Speed of sound for understanding metals in extreme environments

IF 11.9 1区物理与天体物理 Q1 PHYSICS, APPLIED

Applied physics reviews Pub Date : 2024-10-07 DOI:10.1063/5.0186669

Elizabeth G. Rasmussen, Boris Wilthan

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引用次数: 0

Abstract

Knowing material behavior is crucial for successful design, especially given the growing number of next-generation energy, defense, and manufacturing systems operating in extreme environments. Specific applications for materials in extreme environments include fusion energy, semiconductor manufacturing, metal additive manufacturing, and aerospace. With increased applications, awareness of foundational science for materials in extreme environments is imperative. The speed of sound provides insights into phase boundaries, like shock-induced melting. Thermodynamic integration of the speed of sound enables the deduction of other desirable properties that are difficult to measure accurately, like density, heat capacity, and expansivity. Metrology advancements enable the speed of sound to be measured at extreme conditions up to 15 000 K and 600 GPa. This comprehensive review presents state-of-the-art sound speed metrology while contextualizing it through a historical lens. Detailed discussions on new standards and metrology best practices, including uncertainty reporting, are included. Data availability for condensed matter speed of sound is presented, highlighting significant gaps in the literature. A theoretical section covers empirically based theoretical models like equations of state and CALPHAD models, the growing practice of using molecular dynamics and density functional theory simulations to fill gaps in measured data, and the use of artificial intelligence and machine learning prediction tools. Concluding, we review how a lack of measurement methods leads to gaps in data availability, which leads to data-driven theoretical models having higher uncertainty, thus limiting confidence in optimizing designs via numerical simulation for critical emerging technologies in extreme environments.

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了解极端环境中金属的声速

了解材料的特性对成功设计至关重要，尤其是考虑到在极端环境中运行的下一代能源、国防和制造系统越来越多。材料在极端环境中的具体应用包括聚变能源、半导体制造、金属增材制造和航空航天。随着应用的增加，对极端环境下材料基础科学的认识势在必行。声速有助于深入了解相界，如冲击诱导熔化。通过对声速进行热力学整合，可以推导出难以精确测量的其他理想特性，如密度、热容量和膨胀率。计量学的进步使声速可以在高达 15 000 K 和 600 GPa 的极端条件下测量。这篇全面的综述介绍了最先进的声速计量学，同时通过历史视角对其进行了梳理。其中包括对新标准和计量最佳实践（包括不确定性报告）的详细讨论。报告介绍了凝聚态声速的数据可用性，并强调了文献中的重大空白。理论部分涵盖了基于经验的理论模型，如状态方程和 CALPHAD 模型，使用分子动力学和密度泛函理论模拟来填补测量数据缺口的做法日益增多，以及人工智能和机器学习预测工具的使用。最后，我们回顾了测量方法的缺乏如何导致数据可用性的差距，从而导致数据驱动的理论模型具有更高的不确定性，从而限制了通过数值模拟优化极端环境中关键新兴技术设计的信心。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Applied physics reviews PHYSICS, APPLIED-

CiteScore

22.50

自引率

2.00%

发文量

113

审稿时长

2 months

期刊介绍： Applied Physics Reviews (APR) is a journal featuring articles on critical topics in experimental or theoretical research in applied physics and applications of physics to other scientific and engineering branches. The publication includes two main types of articles: Original Research: These articles report on high-quality, novel research studies that are of significant interest to the applied physics community. Reviews: Review articles in APR can either be authoritative and comprehensive assessments of established areas of applied physics or short, timely reviews of recent advances in established fields or emerging areas of applied physics.