Solidification of Undercooled Liquid under Supergravity Field by Phase-Field Crystal Approach

Solidification under a supergravity field is an effective method to control the solidified microstructure, which can be used to prepare materials with excellent comprehensive properties. In order to explore the influence of supergravity on the solidification behavior, a phase-field crystal model for...

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Published inMetals (Basel ) Vol. 12; no. 2; p. 232
Main Authors Hu, Nengwen, Huang, Yongfeng, Wang, Kun, Hu, Wangyu, Chen, Jun, Deng, Huiqiu
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.02.2022
Subjects
Alloys
Control methods
Crystallization
Energy
Equilibrium
Fourier transforms
graded structure
grain refinement
Grain size
Gravitational fields
Microstructure
Noise
Nucleation
Partial differential equations
phase-field crystal
Pressure distribution
Simulation
Solidification
Solids
Supergravity
Weightlessness
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Abstract Solidification under a supergravity field is an effective method to control the solidified microstructure, which can be used to prepare materials with excellent comprehensive properties. In order to explore the influence of supergravity on the solidification behavior, a phase-field crystal model for the solidification under supergravity fields is developed and utilized to study the supergravity-controlled solidification behaviors. The results show that the grains in the solidification structures are refined in a supergravity field. The grain size in a zero-gravity field is uniformly distributed in the sample, but gradually decreases along the direction of the supergravity, showing a graded microstructure. The simulations show real-time images of the nucleation and growth of grains during solidification. In a supergravity field, solidification occurs preferentially in the liquid subject to greater gravity and advances in the opposite direction of supergravity with the time evolution. In addition, the driving force of crystallization in liquid is calculated to explain the effect of the supergravity field on the solidification structure from a thermodynamic point of view. Our findings are expected to provide a new approach and insight for understanding the solidification behaviors under supergravity.
AbstractList Solidification under a supergravity field is an effective method to control the solidified microstructure, which can be used to prepare materials with excellent comprehensive properties. In order to explore the influence of supergravity on the solidification behavior, a phase-field crystal model for the solidification under supergravity fields is developed and utilized to study the supergravity-controlled solidification behaviors. The results show that the grains in the solidification structures are refined in a supergravity field. The grain size in a zero-gravity field is uniformly distributed in the sample, but gradually decreases along the direction of the supergravity, showing a graded microstructure. The simulations show real-time images of the nucleation and growth of grains during solidification. In a supergravity field, solidification occurs preferentially in the liquid subject to greater gravity and advances in the opposite direction of supergravity with the time evolution. In addition, the driving force of crystallization in liquid is calculated to explain the effect of the supergravity field on the solidification structure from a thermodynamic point of view. Our findings are expected to provide a new approach and insight for understanding the solidification behaviors under supergravity.
Author Chen, Jun
Hu, Wangyu
Huang, Yongfeng
Deng, Huiqiu
Wang, Kun
Hu, Nengwen
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SubjectTerms Alloys
Control methods
Crystallization
Energy
Equilibrium
Fourier transforms
graded structure
grain refinement
Grain size
Gravitational fields
Microstructure
Noise
Nucleation
Partial differential equations
phase-field crystal
Pressure distribution
Simulation
Solidification
Solids
Supergravity
Weightlessness
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Title Solidification of Undercooled Liquid under Supergravity Field by Phase-Field Crystal Approach
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