The solidification in the presence of a metastable miscibility gap: the case of Co-Cu and Co-Cu-X alloys

L. Battezzati; Erik Johnson; Nini Pryds; A. Penna; C. Stefano

doi:10.4028/www.scientific.net/msf.649.41

The solidification in the presence of a metastable miscibility gap: the case of Co-Cu and Co-Cu-X alloys

L. Battezzati, Erik Johnson, Nini Pryds, A. Penna, C. Stefano

1 Citation (Scopus)

Abstract

Alloys displaying positive enthalpy of mixing demix below a critical temperature. In Co-Cu and related ternaries the miscibility gap is metastable, i.e. it occurs at temperatures lower than the liquidus. In order to study the liquid phase separation high melt undercooling is necessary. This was obtained via rapid solidification techniques using melt spinning and casting in moulding devices, as well as high temperature DSC experiments with samples embedded in a flux. Results are given for Co-Cu, Co-Cu-Fe and Co-Cu-Ni systems. Phase diagrams were optimised using the DSC data. The mechanism of phase separation was investigated by comparing samples produced under different cooling conditions. The hierarchy of microstructures obtained was interpreted accounting for the processing technique and the phase diagram. They constitute a database useful for the interpretation of the thermal history of samples processed in microgravity.

Original language	English
Journal	Materials Science Forum
Volume	649
Issue number	41
Pages (from-to)	41-45
Number of pages	5
ISSN	0255-5476
DOIs	https://doi.org/10.4028/www.scientific.net/msf.649.41
Publication status	Published - 1 May 2010

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title = "The solidification in the presence of a metastable miscibility gap: the case of Co-Cu and Co-Cu-X alloys",

abstract = "Alloys displaying positive enthalpy of mixing demix below a critical temperature. In Co-Cu and related ternaries the miscibility gap is metastable, i.e. it occurs at temperatures lower than the liquidus. In order to study the liquid phase separation high melt undercooling is necessary. This was obtained via rapid solidification techniques using melt spinning and casting in moulding devices, as well as high temperature DSC experiments with samples embedded in a flux. Results are given for Co-Cu, Co-Cu-Fe and Co-Cu-Ni systems. Phase diagrams were optimised using the DSC data. The mechanism of phase separation was investigated by comparing samples produced under different cooling conditions. The hierarchy of microstructures obtained was interpreted accounting for the processing technique and the phase diagram. They constitute a database useful for the interpretation of the thermal history of samples processed in microgravity.",

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T2 - the case of Co-Cu and Co-Cu-X alloys

AU - Battezzati, L.

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AU - Stefano, C.

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The solidification in the presence of a metastable miscibility gap: the case of Co-Cu and Co-Cu-X alloys

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