On the Stability of Mg Nanograins to Coarsening after Repeated Melting

Autor:	Andrew R. McGhie, Luke L. Daemen, José M. Córdoba Gallego, Shahram Amini, Chaoying Ni, Lars Hultman, Michel W. Barsoum, Magnus Odén
Rok vydání:	2009
Předmět:	Anatase Materials science Annealing (metallurgy) Mechanical Engineering Mineralogy Bioengineering General Chemistry Condensed Matter Physics Microstructure Grain size Amorphous solid Differential scanning calorimetry Melting point General Materials Science Thermal stability Composite material
Zdroj:	Nano Letters. 9:3082-3086
ISSN:	1530-6992 1530-6984
DOI:	10.1021/nl9015683
Popis:	Herein we report on the extraordinary thermal stability of approximately 35 nm Mg-nanograins that constitute the matrix of a Ti(2)AlC-Mg composite that has previously been shown to have excellent mechanical properties. The microstructure is so stable that heating the composite three times to 700 degrees C, which is 50 degrees C over the melting point of Mg, not only resulted in the repeated melting of the Mg, but surprisingly and within the resolution of our differential scanning calorimeter, did not lead to any coarsening. The reduction in the Mg melting point due to the nanograins was approximately 50 degrees C. X-ray diffraction and neutron spectroscopy results suggest that thin, amorphous, and/or poorly crystallized rutile, anatase, and/or magnesia layers separate the Mg nanograins and prevent them from coarsening. Clearly that layer is thin enough, and thus mechanically robust enough, to survive the melting and solidification stresses encountered during cycling. Annealing in hydrogen at 250 degrees C for 20 h, also did not seem to alter the grain size significantly.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::575d5d4c61bc310dc1e8987e59564358 https://doi.org/10.1021/nl9015683 Zobrazit plný text záznamu