Rui Su
(, ), Jieyi Yu
(, ), Pengfei Guan
(, ), Weihua Wang
(, )
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Extensive calculations demonstrate that the newly developed NNP faithfully reproduces the phase stabilities and structural characteristics obtained from <i>ab initio</i> calculations and experiments. In the combined NNP-SHMC algorithm, the structure equilibration time at deeply supercooled temperatures is accelerated by at least five orders of magnitude, and the quenched glassy samples exhibit comparable stability to those prepared in the laboratory. Our results pave the way for next-generation studies of the vitrification process and, thereby, the composition-dependent glass-forming ability and physical properties of multicomponent metallic glasses.\n</p><div><figure><div><div><picture><source><img></source></picture></div></div></figure></div></div>","PeriodicalId":773,"journal":{"name":"Science China Materials","volume":"67 10","pages":"3298 - 3308"},"PeriodicalIF":6.8000,"publicationDate":"2024-07-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Efficient and accurate simulation of vitrification in multicomponent metallic liquids with neural network potentials\",\"authors\":\"Rui Su \\n (, ), Jieyi Yu \\n (, ), Pengfei Guan \\n (, ), Weihua Wang \\n (, )\",\"doi\":\"10.1007/s40843-024-2953-9\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>Constructing an accurate interatomic potential and overcoming the exponential growth of structural equilibration time are challenges for atomistic investigations of the composition-dependent structure and dynamics during the vitrification process of deeply supercooled multicomponent metallic liquids. In this work, we describe a state-of-the-art strategy to address these challenges simultaneously. In the case of the representative Zr–Cu–Al system, in combination with a general algorithm for effectively and accurately generating the neural network potentials (NNPs) of multicomponent metallic glasses, we propose a highly efficient atom-swapping hybrid Monte Carlo (SHMC) algorithm for accelerating the thermodynamic equilibration of deeply supercooled liquids. Extensive calculations demonstrate that the newly developed NNP faithfully reproduces the phase stabilities and structural characteristics obtained from <i>ab initio</i> calculations and experiments. In the combined NNP-SHMC algorithm, the structure equilibration time at deeply supercooled temperatures is accelerated by at least five orders of magnitude, and the quenched glassy samples exhibit comparable stability to those prepared in the laboratory. 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Efficient and accurate simulation of vitrification in multicomponent metallic liquids with neural network potentials
Constructing an accurate interatomic potential and overcoming the exponential growth of structural equilibration time are challenges for atomistic investigations of the composition-dependent structure and dynamics during the vitrification process of deeply supercooled multicomponent metallic liquids. In this work, we describe a state-of-the-art strategy to address these challenges simultaneously. In the case of the representative Zr–Cu–Al system, in combination with a general algorithm for effectively and accurately generating the neural network potentials (NNPs) of multicomponent metallic glasses, we propose a highly efficient atom-swapping hybrid Monte Carlo (SHMC) algorithm for accelerating the thermodynamic equilibration of deeply supercooled liquids. Extensive calculations demonstrate that the newly developed NNP faithfully reproduces the phase stabilities and structural characteristics obtained from ab initio calculations and experiments. In the combined NNP-SHMC algorithm, the structure equilibration time at deeply supercooled temperatures is accelerated by at least five orders of magnitude, and the quenched glassy samples exhibit comparable stability to those prepared in the laboratory. Our results pave the way for next-generation studies of the vitrification process and, thereby, the composition-dependent glass-forming ability and physical properties of multicomponent metallic glasses.
期刊介绍:
Science China Materials (SCM) is a globally peer-reviewed journal that covers all facets of materials science. It is supervised by the Chinese Academy of Sciences and co-sponsored by the Chinese Academy of Sciences and the National Natural Science Foundation of China. The journal is jointly published monthly in both printed and electronic forms by Science China Press and Springer. The aim of SCM is to encourage communication of high-quality, innovative research results at the cutting-edge interface of materials science with chemistry, physics, biology, and engineering. It focuses on breakthroughs from around the world and aims to become a world-leading academic journal for materials science.