Phase-field method and Materials Genome Initiative(MGI) 被引量：4

Phase-field method and Materials Genome Initiative(MGI)

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摘要 Predicting and controlling the microstructure evolution within a material are considered as the‘‘holy grail’’of materials science and engineering.Many important engineering materials are designed by controlling their phase transformations and microstructure evolution.Examples include the improvement of mechanical properties through solid-state precipitation reactions in Nibased superalloys and age-hardened Al alloys,the useful dielectric properties and electro-mechanical coupling effects by manipulating the phase transitions in ferroelectric crystals,and the memory effect of shape-memory alloys by utilizing martensitic transformations.Phase-field method has become the method of choice for modeling three-dimensional microstructure evolution for a wide variety of materials processes.This short article briefly discusses the potential roles that phase-field method can play in the Materials Genome Initiative. Predicting and controlling the microstructure evolution within a material are considered as the ＂holy grail＂ of materials science and engineering. Many impor- tant engineering materials are designed by controlling their phase transformations and microstructure evolution. Examples include the improvement of mechanical prop- erties through solid-state precipitation reactions in Ni- based superalloys and age-hardened A1 alloys, the useful dielectric properties and electro-mechanical coupling effects by manipulating the phase transitions in ferroelec- tric crystals, and the memory effect of shape-memory alloys by utilizing martensitic transformations. Phase-field method has become the method of choice for modeling three-dimensional microstructure evolution for a wide variety of materials processes. This short article briefly discusses the potential roles that phase-field method can play in the Materials Genome Initiative.

作者 Long-Qing Chen

机构地区 Department of Materials Science and Engineering

出处《Chinese Science Bulletin》 SCIE EI CAS 2014年第15期1641-1645,共5页

基金 supported by the National Science Foundation through the Designing Materials to Revolutionize and Engineer our Future(DMREF)Initiative(DMR-1234096) the Grant Opportunities for Academic Liaison with Industry(GOALI)Program(CMMI-1235092)

关键词材料科学与工程基因组计划相场方法马氏体相变超耐热合金组织演变形状记忆合金工程材料 Materials Genome Initiative Phase field - Microstructure

分类号 TB303 [一般工业技术—材料科学与工程]

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参考文献18

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Phase-field method and Materials Genome Initiative(MGI) 被引量：4

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