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Numerical and Experimental Analysis of the Deformation Behavior of CoCrFeNiMn High Entropy Alloy Particles onto Various Substrates During Cold Spraying

Akisin, C. J.; Bennett, C. J.; Venturi, F.; Assadi, H.; Hussain, T.

Numerical and Experimental Analysis of the Deformation Behavior of CoCrFeNiMn High Entropy Alloy Particles onto Various Substrates During Cold Spraying Thumbnail


Authors

C. J. Akisin

CHRIS BENNETT C.Bennett@nottingham.ac.uk
Professor of Solid Mechanics

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Dr FEDERICO VENTURI FEDERICO.VENTURI@NOTTINGHAM.AC.UK
Assistant Professor in Materials & Aerospace Engineering

H. Assadi

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TANVIR HUSSAIN TANVIR.HUSSAIN@NOTTINGHAM.AC.UK
Professor of Coatings and Surface Engineering



Abstract

The bonding mechanisms of a wide range of metallic materials in cold spraying have been studied, mainly attributed to adiabatic shear instability (ASI) at high strain rates, whereas the impact and deformation behavior of high entropy alloys (HEAs) onto various substrates has not been widely explored. HEAs have been characterized by excellent strain-hardening ability and high resistance to shear localization, which can influence their bonding mechanism during cold spray. In this study, experimental and numerical analyses of single-particle impact behavior during cold spraying of CoCrFeNiMn onto commercially pure aluminum (CP Al), aluminum alloy (Al6082), stainless steel (SS304), and titanium alloy (Ti6Al4V) substrates were carried out. The impact morphology revealed ASI in the HEA particle, and SS304 and Ti6Al4V substrates. The HEA/SS304 pair showed a higher critical velocity compared to HEA/Ti6Al4V due to the lower density and thermal conductivity of Ti6Al4V compared to SS304. Mechanical interlocking was observed on CP Al and Al6082 substrates and was attributed to the localized deformation of the substrates. An empirical equation showed this is influenced by the particle density and substrate hardness. This work critically evaluates and provides a better understanding of HEA particle–substrates deformation behavior, expanding its applicability to a wider range of substrates.

Journal Article Type Article
Acceptance Date Feb 28, 2022
Online Publication Date Apr 8, 2022
Publication Date Apr 8, 2022
Deposit Date Apr 1, 2022
Publicly Available Date Apr 8, 2022
Journal Journal of Thermal Spray Technology
Print ISSN 1059-9630
Electronic ISSN 1544-1016
Peer Reviewed Peer Reviewed
Volume 31
Issue 4
Pages 1085-1111
DOI https://doi.org/10.1007/s11666-022-01377-1
Keywords Materials Chemistry; Surfaces, Coatings and Films; Condensed Matter Physics
Public URL https://nottingham-repository.worktribe.com/output/7682806
Publisher URL https://link.springer.com/article/10.1007/s11666-022-01377-1

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