Size effects on plasticity in high-entropy alloys

The current review outlines the size-dependent plastic behavior of high-entropy alloys (HEAs) and the underlying deformation mechanisms. Particular focus is laid upon the influence of microstructural design on the small-scale deformation characteristics. The role of defect types as carriers of plast...

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Veröffentlicht in:	Journal of materials research 2018-10, Vol.33 (19), p.3055-3076
Hauptverfasser:	Basu, Indranil, Ocelík, Václav, De Hosson, Jeff Th. M.
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Sprache:	eng
Schlagworte:	Alloys Applied and Technical Physics Biomaterials Crystal defects Crystal lattices Crystallography Deformation Deformation mechanisms Design Design defects Ductility Entropy High entropy alloys Inorganic Chemistry Invited Review Magnesium Materials Engineering Materials research Materials Science Mechanical properties Mechanical tests Metals Nanoindentation Nanotechnology Plastic properties Single crystals Size effects Solid solutions Solvents Temperature Tensile strength
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container_title	Journal of materials research
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creator	Basu, Indranil Ocelík, Václav De Hosson, Jeff Th. M.
description	The current review outlines the size-dependent plastic behavior of high-entropy alloys (HEAs) and the underlying deformation mechanisms. Particular focus is laid upon the influence of microstructural design on the small-scale deformation characteristics. The role of defect types as carriers of plasticity is appraised and correlated with the frequently observed mechanical behavior peculiar to the breed of HEAs. Deformation response is classified on the basis of mechanical testing techniques probing intrinsic (nanoindentation techniques) as well as extrinsic size (micro/nanopillar compression) effects. The mechanisms of incipient plasticity and serrated flow behavior in HEAs are discussed. Furthermore, the role of interfaces between crystallographically dissimilar lattices on small-scale deformation behavior in these alloys is assessed. The article provides a clear overview of the existing HEA research in this avenue as well as the critical knowledge gaps that need to be addressed.
doi_str_mv	10.1557/jmr.2018.282
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subjects	Alloys Applied and Technical Physics Biomaterials Crystal defects Crystal lattices Crystallography Deformation Deformation mechanisms Design Design defects Ductility Entropy High entropy alloys Inorganic Chemistry Invited Review Magnesium Materials Engineering Materials research Materials Science Mechanical properties Mechanical tests Metals Nanoindentation Nanotechnology Plastic properties Single crystals Size effects Solid solutions Solvents Temperature Tensile strength
title	Size effects on plasticity in high-entropy alloys
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