Concentration Dependent Growth Velocities in Undercooled Al-Rich Al-Ni Alloy Systems

Georg J. Ehlen; Hai Feng Wang; Dieter M. Herlach

doi:10.4028/www.scientific.net/MSF.790-791.485

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HomeMaterials Science ForumMaterials Science Forum Vols. 790-791Concentration Dependent Growth Velocities in...

Concentration Dependent Growth Velocities in Undercooled Al-Rich Al-Ni Alloy Systems

Abstract:

Dendrite growth velocity V as a function of undercooling on the Al-rich side of the Al-Ni system has recently been measured by electromagnetic levitation. The results have shown an anomalous behaviour, which so far cannot be theoretically described. The present work uses two simplified qualitative models of sharp interface theory, one of them treating the forming AlNi (B2) phase as a solid-solution, one treating it as an intermetallic phase, to investigate the influence of the phase diagram on the growth velocities. The results imply that the concentration dependent growth behaviour is a superposition of at least two effects: 1) A strong decrease of the total growth velocitiy level for increasing Al concentrations. 2) An increase of growth velocities with increase of Al concentration at medium and low undercoolings. The present work is able to explain the first effect, namely the concentration dependent reduction of velocities. Results are compared to experimental data. In both models the properties of the phase diagram lead to an increase of the constitutional undercooling ΔT_c when the Al content increases. This reduces the fraction left for kinetic undercooling ΔT_k, which is responsible for interface migration and which determines the growth velocity. Neither of the models can reproduce the second effect.

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Materials Science Forum (Volumes 790-791)

Pages:

485-490

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.790-791.485

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Online since:

May 2014

Authors:

Georg J. Ehlen*, Hai Feng Wang, Dieter M. Herlach

Keywords:

Al-Rich Al-Ni, Concentration Dependence, Constitutional Undercooling, Dendrite Growth Velocity, Kinetic Undercooling

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