The Dual Character of MAX Phase Nano-Layered Structure Highlighted by Supersonic Particles Deposition

MAX phase compounds offer an attractive mixture of ceramic–metallic properties due to their covalent ionic–metallic nature. Since their discovery, a great interest was attributed to their synthesis and potential applications, but the processing of pure compounds as coatings for industrial large-scal...

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Veröffentlicht in:	Coatings (Basel) 2021-09, Vol.11 (9), p.1038
Hauptverfasser:	Ion, Alberto, Sallot, Pierre, Badea, Victor, Duport, Patrice, Popescu, Camelia, Denoirjean, Alain
Format:	Artikel
Sprache:	eng
Schlagworte:	Ceramics Chemical Sciences Coatings Cold Deformation Deposition Engineering Sciences Formability Grain growth Material chemistry Materials Mechanical properties Particle size Phase composition Plastic deformation Raw materials Residual stress Substrates Velocity
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creator	Ion, Alberto Sallot, Pierre Badea, Victor Duport, Patrice Popescu, Camelia Denoirjean, Alain
description	MAX phase compounds offer an attractive mixture of ceramic–metallic properties due to their covalent ionic–metallic nature. Since their discovery, a great interest was attributed to their synthesis and potential applications, but the processing of pure compounds as coatings for industrial large-scale application is still considered a challenge. To date, a limited number of papers have evaluated the build-up of MAX phase coating by cold spray (CS), a novel cost-effective and productive spray technology used in both areas of research and industry. Employing CS, the hot gas-propelled material particles have ballistic impingement on a substrate where they undergo plastic deformation. Because of the brittleness, internal delamination, and limited deformability, the deposition of the pure MAX phase is rather challenging. This paper presents the building-up ability of dense MAX-phase coatings by CS with retained structures and compositions, in close relation with the substrate characteristics and phase composition that influences the dual character ceramic–metallic behaviour. Besides recent literature, the originality of this research consists of pioneering deposition of Ti3AlC2 that emphasizes the ceramic–metallic character influenced by the particle speed and the mechanical properties of both substrate and compound.
doi_str_mv	10.3390/coatings11091038
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subjects	Ceramics Chemical Sciences Coatings Cold Deformation Deposition Engineering Sciences Formability Grain growth Material chemistry Materials Mechanical properties Particle size Phase composition Plastic deformation Raw materials Residual stress Substrates Velocity
title	The Dual Character of MAX Phase Nano-Layered Structure Highlighted by Supersonic Particles Deposition
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