6533b873fe1ef96bd12d5f75

RESEARCH PRODUCT

In situ synchrotron characterization of mechanically activated self-propagating high-temperature synthesis applied in Mo–Si system

Frédéric BernardFrederic CharlotFrederic CharlotChristophe GrasChristophe GrasJean-claude NiepceEric Gaffet

subject

DiffractionNanostructureMaterials sciencePolymers and PlasticsMetals and AlloysSelf-propagating high-temperature synthesisAnalytical chemistryMicrostructureCombustionElectronic Optical and Magnetic MaterialsTemperature gradientCrystallographyPhase (matter)Ceramics and CompositesFront velocity

description

Abstract An original experiment was designed to monitor structural and thermal evolutions during the MASHS (Mechanically Activated Self-propagating High-temperature Synthesis) process in the Mo–Si system. Time-Resolved X-Ray Diffraction (TRXRD) coupled with an infrared imaging technique was performed to study, in situ, the formation of the α-MoSi2 phase in the combustion front. Despite a temporal resolution of 50 ms between two consecutive diffractograms, no intermediate phase was observed during the passage of the combustion front. The only reaction responsible for the self-sustentation is Mo+2Si→MoSi2 in the primary zone inside the combustion wave. The mechanical activation was found to influence Self-propagation High-temperature Synthesis (SHS) parameters such as the propagation front velocity (>13 mm/s), the maximal combustion temperature and the local thermal gradient. After the MASHS process, the α-MoSi2 compound is nanostructured (DMoSi2=88 nm) and some explanations are expressed in order to understand why the nanostructure of the as-milled powders can be maintained during the combustion reaction.

yearjournalcountryeditionlanguage
1999-05-01Acta Materialia
https://doi.org/10.1016/s1359-6454(99)00084-1