Prediction of the maximal recalescence temperature upon rapid solidification of bulk undercooled Cu70Ni30 alloy

W. Yang; F. Liu; H. F. Wang; Z. Chen; G. C. Yang; Y. H. Zhou

doi:10.1016/j.jallcom.2008.02.074

Prediction of the maximal recalescence temperature upon rapid solidification of bulk undercooled Cu₇₀Ni₃₀ alloy

W. Yang, F. Liu, H. F. Wang, Z. Chen, G. C. Yang, Y. H. Zhou

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Letter › peer-review

23 Scopus citations

Abstract

Applying melt-fluxing, how to predict the maximal recalescence temperature T_R upon rapid solidification of bulk undercooled Cu₇₀Ni₃₀ alloy has been investigated. Reproducible experimental results show that T_R decreases with the increase of the initial melting undercooling ΔT, and moreover, its value is much lower than that predicted by Level rule and Scheil equation, let alone the equilibrium liquidus temperature. Quantitative thermodynamic calculation, in combination with an analysis of solute distribution, demonstrates that, T_R is affected by the difference of Gibbs free energy between the residual liquid and solid after recalescence. Subjected to sufficiently high ΔT, T_R should be nearly equal to the thermodynamic T₀ point corresponding to the concentration of the residual melt after recalescence.

Original language	English
Pages (from-to)	L13-L16
Journal	Journal of Alloys and Compounds
Volume	470
Issue number	1-2
DOIs	https://doi.org/10.1016/j.jallcom.2008.02.074
State	Published - 20 Feb 2009

Keywords

Metals and alloys
Rapid solidification
Thermal analysis
Thermodynamics

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10.1016/j.jallcom.2008.02.074

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title = "Prediction of the maximal recalescence temperature upon rapid solidification of bulk undercooled Cu70Ni30 alloy",

abstract = "Applying melt-fluxing, how to predict the maximal recalescence temperature TR upon rapid solidification of bulk undercooled Cu70Ni30 alloy has been investigated. Reproducible experimental results show that TR decreases with the increase of the initial melting undercooling ΔT, and moreover, its value is much lower than that predicted by Level rule and Scheil equation, let alone the equilibrium liquidus temperature. Quantitative thermodynamic calculation, in combination with an analysis of solute distribution, demonstrates that, TR is affected by the difference of Gibbs free energy between the residual liquid and solid after recalescence. Subjected to sufficiently high ΔT, TR should be nearly equal to the thermodynamic T0 point corresponding to the concentration of the residual melt after recalescence.",

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AU - Yang, W.

AU - Liu, F.

AU - Wang, H. F.

AU - Chen, Z.

AU - Yang, G. C.

AU - Zhou, Y. H.

PY - 2009/2/20

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N2 - Applying melt-fluxing, how to predict the maximal recalescence temperature TR upon rapid solidification of bulk undercooled Cu70Ni30 alloy has been investigated. Reproducible experimental results show that TR decreases with the increase of the initial melting undercooling ΔT, and moreover, its value is much lower than that predicted by Level rule and Scheil equation, let alone the equilibrium liquidus temperature. Quantitative thermodynamic calculation, in combination with an analysis of solute distribution, demonstrates that, TR is affected by the difference of Gibbs free energy between the residual liquid and solid after recalescence. Subjected to sufficiently high ΔT, TR should be nearly equal to the thermodynamic T0 point corresponding to the concentration of the residual melt after recalescence.

AB - Applying melt-fluxing, how to predict the maximal recalescence temperature TR upon rapid solidification of bulk undercooled Cu70Ni30 alloy has been investigated. Reproducible experimental results show that TR decreases with the increase of the initial melting undercooling ΔT, and moreover, its value is much lower than that predicted by Level rule and Scheil equation, let alone the equilibrium liquidus temperature. Quantitative thermodynamic calculation, in combination with an analysis of solute distribution, demonstrates that, TR is affected by the difference of Gibbs free energy between the residual liquid and solid after recalescence. Subjected to sufficiently high ΔT, TR should be nearly equal to the thermodynamic T0 point corresponding to the concentration of the residual melt after recalescence.

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Prediction of the maximal recalescence temperature upon rapid solidification of bulk undercooled Cu₇₀Ni₃₀ alloy

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