Synthesis of high-purity polycrystalline MAX phases in Ti–Al–C system through Mechanically Activated Self-propagating High-temperature Synthesis

Ternary MAX phase compounds were synthesized using an alternative route called MASHS (Mechanically Activated Self-propagating High-temperature Synthesis). This original process combines a short duration ball milling (MA) of reactants (Ti, Al, C) with a self-sustaining combustion (SHS). The particle...

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Veröffentlicht in:	Journal of the European Ceramic Society 2010-03, Vol.30 (4), p.1049-1057
Hauptverfasser:	Hendaoui, A., Vrel, D., Amara, A., Langlois, P., Andasmas, M., Guerioune, M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Carbides Electron microscopy Engineering Sciences Materials Microstructure-final Powders-solid state reaction X-ray methods
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container_end_page	1057
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container_title	Journal of the European Ceramic Society
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creator	Hendaoui, A. Vrel, D. Amara, A. Langlois, P. Andasmas, M. Guerioune, M.
description	Ternary MAX phase compounds were synthesized using an alternative route called MASHS (Mechanically Activated Self-propagating High-temperature Synthesis). This original process combines a short duration ball milling (MA) of reactants (Ti, Al, C) with a self-sustaining combustion (SHS). The particle size evolution of the powder mixture during Mechanical Activation was monitored using XRD profile analysis. The effect of Al-excess was also discussed. XRD and SEM analyses have proved that the activation of the reaction kinetics must be accompanied by a decrease in the overall exothermicity in order to synthesize pure Ti–Al–C MAX phases by MASHS.
doi_str_mv	10.1016/j.jeurceramsoc.2009.10.001
format	Article
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subjects	Carbides Electron microscopy Engineering Sciences Materials Microstructure-final Powders-solid state reaction X-ray methods
title	Synthesis of high-purity polycrystalline MAX phases in Ti–Al–C system through Mechanically Activated Self-propagating High-temperature Synthesis
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