Abstract
Au-Zr binary system was reassessed by using the calculation phase diagram (CALPHAD) technique based on experimental thermodynamic data and newly reported phase diagrams. The excess Gibbs energies of the three terminal solutions and the liquid phases were formulated with Redlich-Kister polynomial. All the intermetallic phases were treated as stoichiometric compounds with the exception of ZrAu which is modeled by a two-sublattice model, (Au,Zr) : (Au,Zr). The results show that there exist seven intermetallics: Zr3Au, Zr2Au, Zr5Au4, Zr7Au10, ZrAu2, ZrAu3, and ZrAu4 in the system. The eutectoid reaction: β(Zr) → α(Zr)+Zr3Au takes place at 1048 K and the maximal solubility of Au in α-Zr is 4.7% (mole fraction). The maximal solubility of Zr in Au is 6.0% (mole fraction) at 1347 K. The homogeneity range of ZrAu phase is about 44.5%–52.9% (mole fraction) of Au. The present assessment fits experimental data very well.
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Foundation item: The National Natural Science Foundation of China (No. 59871065)
Biography of the first author: LI Zhi-hua, born in Oct. 1975, majoring in materials science and engineering.
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Li, Zh., Jin, Zp. & Liu, Hs. Thermodynamic assessment of Au-Zr system. J Cent. South Univ. Technol. 10, 94–97 (2003). https://doi.org/10.1007/s11771-003-0046-2
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DOI: https://doi.org/10.1007/s11771-003-0046-2