Rapid eutectic growth in undercooled Al-Ge alloy under free fall condition

doi:10.1088/1009-1963/12/11/315

Abstract

Abstract Eutectic growth in Al-51.6%wt Ge alloy has been investigated during free fall in a drop tube. With decreasing undercooling $\Delta T$, the microstructural evolution has shown a transition from lamellar eutectic to anomalous eutectic. A maximum cooling rate of $4.2\times10^4$K/s and undercooling of up to 240K (0.35$T_{\rm E}$) are obtained in the experiment. The eutectic coupled zone is calculated on the basis of current eutectic and dendritic growth theories, which covers a composition range from 48%－59% Ge and leans towards the Ge-rich side. The two critical undercoolings for the eutectic transition are $\Delta T_1^*$=101K and $\Delta_2^*$=178K. When $\Delta T≤\Delta T^*_1$, the microstructure for Al-51.6% Ge eutectic shows lamellar eutectic. If $\Delta T≥\Delta T^*_2$, the microstructure shows anomalous eutectic. In the intermediate range of $\Delta T^*_1<\Delta T<\Delta T^*_2$, the microstructure is the mixture of the above two types of eutectics.

Keywords: growth morphology undercooling coupled zone free fall

Received: 14 March 2003
Revised: 14 May 2003
Accepted manuscript online:

PACS:	81.30.Fb	(Solidification)
	81.30.Bx	(Phase diagrams of metals, alloys, and oxides)
	81.10.Mx	(Growth in microgravity environments)
	81.10.Fq	(Growth from melts; zone melting and refining)
	64.70.Dv
	61.50.-f	(Structure of bulk crystals)

Fund: Project supported by the National Natural Science Foundation of China (Grant Nos 50221101, 50291015, 50201013 and 50271058).

Cite this article:

Liu Xiang-Rong (刘向荣), Cao Chong-De (曹崇德), Wei Bing-Bo (魏炳波) Rapid eutectic growth in undercooled Al-Ge alloy under free fall condition 2003 Chinese Physics 12 1266

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Rapid eutectic growth in undercooled Al-Ge alloy under free fall condition

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