Breakthrough applications of high-entropy materials

The concept of high-entropy alloys has been extended to ceramics, polymers, and composites. “High-entropy materials (HEMs)” are named to cover all these materials. Recently, HEMs has become a new emerging field through the collective efforts of many researchers. Basically, high mixing entropy can en...

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Veröffentlicht in:	Journal of materials research Jg. 33; H. 19; S. 3129 - 3137
Hauptverfasser:	Yeh, Jien-Wei, Lin, Su-Jien
Format:	Journal Article
Sprache:	Englisch
Veröffentlicht:	New York, USA Cambridge University Press 14.10.2018 Springer International Publishing Springer Nature B.V
Schlagworte:	21st century Alloys Applied and Technical Physics Biomaterials Carbide tools Ceramics Coatings Composite materials Cutting resistance Cutting tool materials Cutting tools Dies Ductility Efficiency Entropy Entropy of formation High entropy alloys High temperature Inorganic Chemistry Invited Article Materials Engineering Materials research Materials Science Microstructure Nanotechnology Polymer matrix composites Radiation damage Radiation tolerance Superalloys Turbine blades Turbines breakthrough applications high-entropy alloys high-entropy ceramics high-entropy materials
ISSN:	0884-2914, 2044-5326
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Abstract	The concept of high-entropy alloys has been extended to ceramics, polymers, and composites. “High-entropy materials (HEMs)” are named to cover all these materials. Recently, HEMs has become a new emerging field through the collective efforts of many researchers. Basically, high mixing entropy can enhance the formation of solution-type phases for alloys, ceramics, and composites at high temperatures, and in general leads to simpler microstructure. Large degrees of freedom in composition design as well as process design have been found to provide a wide range of microstructure and properties for applications. There are many opportunities for HEMs to overcome the bottlenecks of conventional materials. In this article, several possible breakthrough applications are pointed out and emphasized for turbine blades, thermal spray bond coatings, high-temperature molds and dies, sintered carbides for cutting tools, hard coatings for cutting tools, hardfacings, and radiation-damage resistant materials. In addition, more possible breakthrough examples are briefly described.
AbstractList	The concept of high-entropy alloys has been extended to ceramics, polymers, and composites. “High-entropy materials (HEMs)” are named to cover all these materials. Recently, HEMs has become a new emerging field through the collective efforts of many researchers. Basically, high mixing entropy can enhance the formation of solution-type phases for alloys, ceramics, and composites at high temperatures, and in general leads to simpler microstructure. Large degrees of freedom in composition design as well as process design have been found to provide a wide range of microstructure and properties for applications. There are many opportunities for HEMs to overcome the bottlenecks of conventional materials. In this article, several possible breakthrough applications are pointed out and emphasized for turbine blades, thermal spray bond coatings, high-temperature molds and dies, sintered carbides for cutting tools, hard coatings for cutting tools, hardfacings, and radiation-damage resistant materials. In addition, more possible breakthrough examples are briefly described.
Author	Lin, Su-Jien Yeh, Jien-Wei
Author_xml	– sequence: 1 givenname: Jien-Wei surname: Yeh fullname: Yeh, Jien-Wei email: jwyeh@mx.nthu.edu.tw organization: Department of Materials Science and Engineering, National Tsing Hua University, Hsinchu 30013, Taiwan, Republic of China – sequence: 2 givenname: Su-Jien surname: Lin fullname: Lin, Su-Jien organization: Department of Materials Science and Engineering, National Tsing Hua University, Hsinchu 30013, Taiwan, Republic of China
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Snippet	The concept of high-entropy alloys has been extended to ceramics, polymers, and composites. “High-entropy materials (HEMs)” are named to cover all these...
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SubjectTerms	21st century Alloys Applied and Technical Physics Biomaterials Carbide tools Ceramics Coatings Composite materials Cutting resistance Cutting tool materials Cutting tools Dies Ductility Efficiency Entropy Entropy of formation High entropy alloys High temperature Inorganic Chemistry Invited Article Materials Engineering Materials research Materials Science Microstructure Nanotechnology Polymer matrix composites Radiation damage Radiation tolerance Superalloys Turbine blades Turbines
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Title	Breakthrough applications of high-entropy materials
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