High-entropy ceramics: Propelling applications through disorder

Cormac Toher; Corey Oses; Marco Esters; David Hicks; George N. Kotsonis; Christina M. Rost; Donald W. Brenner; Jon Paul Maria; Stefano Curtarolo

doi:10.1557/s43577-022-00281-x

High-entropy ceramics: Propelling applications through disorder

Cormac Toher, Corey Oses, Marco Esters, David Hicks, George N. Kotsonis, Christina M. Rost, Donald W. Brenner, Jon Paul Maria, Stefano Curtarolo

Materials Science and Engineering

Research output: Contribution to journal › Review article › peer-review

50 Scopus citations

Abstract

Disorder enhances desired properties, as well as creating new avenues for synthesizing materials. For instance, hardness and yield stress are improved by solid-solution strengthening, a result of distortions and atomic-size mismatches. Thermochemical stability is increased by the preference of chemically disordered mixtures for high-symmetry superlattices. Vibrational thermal conductivity is decreased by force-constant disorder without sacrificing mechanical strength and stiffness. Thus, high-entropy ceramics propel a wide range of applications: from wear-resistant coatings and thermal and environmental barriers to catalysts, batteries, thermoelectrics, and nuclear energy management. Here, we discuss recent progress of the field, with a particular emphasis on disorder-enhanced properties and applications. Graphical abstract: [Figure not available: see fulltext.]

Original language	English (US)
Pages (from-to)	194-202
Number of pages	9
Journal	MRS Bulletin
Volume	47
Issue number	2
DOIs	https://doi.org/10.1557/s43577-022-00281-x
State	Published - Feb 2022

All Science Journal Classification (ASJC) codes

General Materials Science
Condensed Matter Physics
Physical and Theoretical Chemistry

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10.1557/s43577-022-00281-x

Cite this

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title = "High-entropy ceramics: Propelling applications through disorder",

abstract = "Disorder enhances desired properties, as well as creating new avenues for synthesizing materials. For instance, hardness and yield stress are improved by solid-solution strengthening, a result of distortions and atomic-size mismatches. Thermochemical stability is increased by the preference of chemically disordered mixtures for high-symmetry superlattices. Vibrational thermal conductivity is decreased by force-constant disorder without sacrificing mechanical strength and stiffness. Thus, high-entropy ceramics propel a wide range of applications: from wear-resistant coatings and thermal and environmental barriers to catalysts, batteries, thermoelectrics, and nuclear energy management. Here, we discuss recent progress of the field, with a particular emphasis on disorder-enhanced properties and applications. Graphical abstract: [Figure not available: see fulltext.]",

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language = "English (US)",

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TY - JOUR

T1 - High-entropy ceramics

T2 - Propelling applications through disorder

AU - Toher, Cormac

AU - Oses, Corey

AU - Esters, Marco

AU - Hicks, David

AU - Kotsonis, George N.

AU - Rost, Christina M.

AU - Brenner, Donald W.

AU - Maria, Jon Paul

AU - Curtarolo, Stefano

PY - 2022/2

Y1 - 2022/2

N2 - Disorder enhances desired properties, as well as creating new avenues for synthesizing materials. For instance, hardness and yield stress are improved by solid-solution strengthening, a result of distortions and atomic-size mismatches. Thermochemical stability is increased by the preference of chemically disordered mixtures for high-symmetry superlattices. Vibrational thermal conductivity is decreased by force-constant disorder without sacrificing mechanical strength and stiffness. Thus, high-entropy ceramics propel a wide range of applications: from wear-resistant coatings and thermal and environmental barriers to catalysts, batteries, thermoelectrics, and nuclear energy management. Here, we discuss recent progress of the field, with a particular emphasis on disorder-enhanced properties and applications. Graphical abstract: [Figure not available: see fulltext.]

AB - Disorder enhances desired properties, as well as creating new avenues for synthesizing materials. For instance, hardness and yield stress are improved by solid-solution strengthening, a result of distortions and atomic-size mismatches. Thermochemical stability is increased by the preference of chemically disordered mixtures for high-symmetry superlattices. Vibrational thermal conductivity is decreased by force-constant disorder without sacrificing mechanical strength and stiffness. Thus, high-entropy ceramics propel a wide range of applications: from wear-resistant coatings and thermal and environmental barriers to catalysts, batteries, thermoelectrics, and nuclear energy management. Here, we discuss recent progress of the field, with a particular emphasis on disorder-enhanced properties and applications. Graphical abstract: [Figure not available: see fulltext.]

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High-entropy ceramics: Propelling applications through disorder

Abstract

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