Bulk High-entropy Nitrides and Carbonitrides

Overview

Journal Sci Rep

Specialty Science

Date 2020 Dec 5

PMID 33277546

Citations 4

Authors

Olivia F Dippo

Neda Mesgarzadeh

Tyler J Harrington

Grant D Schrader

Kenneth S Vecchio

Affiliations

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Abstract

High-entropy ceramics have potential to improve the mechanical properties and high-temperature stability over traditional ceramics, and high entropy nitrides and carbonitrides (HENs and HECNs) are particularly attractive for high temperature and high hardness applications. The synthesis of 5 bulk HENs and 4 bulk HECNs forming single-phase materials is reported herein among 11 samples prepared. The hardness of HENs and HECNs increased by an average of 22% and 39%, respectively, over the rule-of-mixtures average of their monocarbide and mononitride precursors. Similarly, elastic modulus values increased by an average of 17% in nitrides and 31% in carbonitrides over their rule-of-mixtures values. The enhancement in mechanical properties is tied to an increase in the configurational entropy and a decrease in the valence electron concentration, providing parameters for tuning mechanical properties of high-entropy ceramics.

Citing Articles

A review of high-entropy materials with their unique applications.

Ren J, Kumkale V, Hou H, Kadam V, Jagtap C, Lokhande P Adv Compos Hybrid Mater. 2025; 8(2):195.

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Melting simulations of high-entropy carbonitrides by deep learning potentials.

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Disordered enthalpy-entropy descriptor for high-entropy ceramics discovery.

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Valence electron concentration as key parameter to control the fracture resistance of refractory high-entropy carbides.

Sangiovanni D, Kaufmann K, Vecchio K Sci Adv. 2023; 9(37):eadi2960.

PMID: 37703369 PMC: 10499311. DOI: 10.1126/sciadv.adi2960.

Experimental Investigations into the Pyrolysis Mechanism and Composition of Ceramic Precursors Containing Boron and Nitrides with Different Boron Contents.

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