A bcc refractory high-entropy alloy: the ideal case of smooth plastic flow

Yen Ting Chang; Abhi Sharda; Julian M. Rosalie; Christoph Robert Eduard Maass; Marie A. Charpagne

doi:10.1080/21663831.2025.2497860

A bcc refractory high-entropy alloy: the ideal case of smooth plastic flow

Yen Ting Chang, Abhi Sharda, Julian M. Rosalie, Christoph Robert Eduard Maass, Marie A. Charpagne

Research output: Contribution to journal › Article › peer-review

Abstract

Single crystalline metals exhibit correlated dislocation dynamics, irrespective of lattice system. This collective evolution of dislocation structures is intermittent and scale-free, implying divergent length scales that play a critical role in failure initiation and therefore microstructural design. Here we report on a HfNbTaTiZr refractory high-entropy alloy, that lacks criticality in the collective dislocation response. This unusual behaviour manifests itself in almost quenched-out microplastic stress-strain fluctuations and sluggish dislocation avalanching, otherwise only seen in complex engineering alloys. These findings demonstrate how the high-entropy paradigm can serve as a role model to effectively suppress unwanted plastic fluctuations in metals deformation.

Original language	English (US)
Pages (from-to)	666-673
Number of pages	8
Journal	Materials Research Letters
Volume	13
Issue number	6
DOIs	https://doi.org/10.1080/21663831.2025.2497860
State	Published - 2025

Keywords

avalanches
dislocations
Plasticity
refractory high-entropy alloys

ASJC Scopus subject areas

General Materials Science

Online availability

10.1080/21663831.2025.2497860License: CC BY

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title = "A bcc refractory high-entropy alloy: the ideal case of smooth plastic flow",

abstract = "Single crystalline metals exhibit correlated dislocation dynamics, irrespective of lattice system. This collective evolution of dislocation structures is intermittent and scale-free, implying divergent length scales that play a critical role in failure initiation and therefore microstructural design. Here we report on a HfNbTaTiZr refractory high-entropy alloy, that lacks criticality in the collective dislocation response. This unusual behaviour manifests itself in almost quenched-out microplastic stress-strain fluctuations and sluggish dislocation avalanching, otherwise only seen in complex engineering alloys. These findings demonstrate how the high-entropy paradigm can serve as a role model to effectively suppress unwanted plastic fluctuations in metals deformation.",

keywords = "avalanches, dislocations, Plasticity, refractory high-entropy alloys",

author = "Chang, {Yen Ting} and Abhi Sharda and Rosalie, {Julian M.} and Maass, {Christoph Robert Eduard} and Charpagne, {Marie A.}",

note = "The authors gratefully acknowledge support from the University of Illinois. The authors thank Peter Ispanovity for fruitful discussions. This research was carried out in part at the electron microscopy center at BAM. Particular thanks goes to Leonardo Agudo J\u00E1come at BAM for extensive TEM support. We acknowledge the use of facilities and instrumentation at the Materials Research Laboratory Central Research Facilities, University of Illinois.",

year = "2025",

doi = "10.1080/21663831.2025.2497860",

language = "English (US)",

volume = "13",

pages = "666--673",

journal = "Materials Research Letters",

issn = "2166-3831",

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number = "6",

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T1 - A bcc refractory high-entropy alloy

T2 - the ideal case of smooth plastic flow

AU - Chang, Yen Ting

AU - Sharda, Abhi

AU - Rosalie, Julian M.

AU - Maass, Christoph Robert Eduard

AU - Charpagne, Marie A.

N1 - The authors gratefully acknowledge support from the University of Illinois. The authors thank Peter Ispanovity for fruitful discussions. This research was carried out in part at the electron microscopy center at BAM. Particular thanks goes to Leonardo Agudo J\u00E1come at BAM for extensive TEM support. We acknowledge the use of facilities and instrumentation at the Materials Research Laboratory Central Research Facilities, University of Illinois.

PY - 2025

Y1 - 2025

N2 - Single crystalline metals exhibit correlated dislocation dynamics, irrespective of lattice system. This collective evolution of dislocation structures is intermittent and scale-free, implying divergent length scales that play a critical role in failure initiation and therefore microstructural design. Here we report on a HfNbTaTiZr refractory high-entropy alloy, that lacks criticality in the collective dislocation response. This unusual behaviour manifests itself in almost quenched-out microplastic stress-strain fluctuations and sluggish dislocation avalanching, otherwise only seen in complex engineering alloys. These findings demonstrate how the high-entropy paradigm can serve as a role model to effectively suppress unwanted plastic fluctuations in metals deformation.

AB - Single crystalline metals exhibit correlated dislocation dynamics, irrespective of lattice system. This collective evolution of dislocation structures is intermittent and scale-free, implying divergent length scales that play a critical role in failure initiation and therefore microstructural design. Here we report on a HfNbTaTiZr refractory high-entropy alloy, that lacks criticality in the collective dislocation response. This unusual behaviour manifests itself in almost quenched-out microplastic stress-strain fluctuations and sluggish dislocation avalanching, otherwise only seen in complex engineering alloys. These findings demonstrate how the high-entropy paradigm can serve as a role model to effectively suppress unwanted plastic fluctuations in metals deformation.

KW - avalanches

KW - dislocations

KW - Plasticity

KW - refractory high-entropy alloys

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DO - 10.1080/21663831.2025.2497860

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JO - Materials Research Letters

JF - Materials Research Letters

IS - 6

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A bcc refractory high-entropy alloy: the ideal case of smooth plastic flow

Abstract

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