Rheological Behavior of a New Amorphous Alloy (Al74Cu16Mg10)99,7Zr0.3

IF 0.7 4区 材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
V. Dyakova, Gergi Stefanov, N. Marinkov, S. Gyurov, Y. Kostova
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Abstract

A new amorphous alloy (Al74Cu16Mg10)99,7Zr0.3 was prepared the applying a melt-spinning technique. Temperature dependence of viscosity of the alloy was determined using data from a PerkinElmer TMS2 thermo-mechanical analyzer processed according to a methodology based on the Free Volume Model (FVM). The strength of the alloy was calculated according to the Yang equation and the glass-forming ability was calculated according to the values of the Angell index mA. The activation energy of crystallization and the activation energy of the glass transition were computed using data from differential scanning calorimetry and thermomechanical experiments respectively. The activation energy of crystallization Еx = 168 ± 3.7 kJ/mol, was found to be higher than the activation energy of the glass transition Еg = 156 ± 1.4 kJ/mol, which means a dominant contribution of the atomic transport barrier, compared to the nucleation barrier. The relatively high temperature interval of the supercooled melt state Tx-Tg = 32 K and the low viscosity values in the same range ƞ(Тg) = 3.40E + 11 Pa.s and ƞ(Тx) = 1.87E + 10 Pa.s would allow thermomechanical treatment of the alloy in the temperature range of supercooled melt.
新型无定形合金 (Al74Cu16Mg10)99,7Zr0.3 的流变行为
采用熔融纺丝技术制备了一种新型非晶合金 (Al74Cu16Mg10)99,7Zr0.3。合金粘度的温度依赖性是利用珀金埃尔默 TMS2 热机械分析仪根据自由体积模型(FVM)方法处理的数据确定的。合金的强度根据杨氏方程计算,玻璃化能力根据安格尔指数 mA 值计算。结晶活化能和玻璃化活化能分别利用差示扫描量热法和热力学实验的数据计算得出。结果发现,结晶活化能 Еx = 168 ± 3.7 kJ/mol 高于玻璃转变活化能 Еg = 156 ± 1.4 kJ/mol,这意味着与成核障碍相比,原子传输障碍的贡献占主导地位。过冷熔体状态 Tx-Tg = 32 K 的温度区间相对较高,且同一范围内的粘度值ƞ(Тg) = 3.40E + 11 Pa.s 和 ƞ(Тx) = 1.87E + 10 Pa.s 较低,因此可以在过冷熔体温度范围内对合金进行热机械处理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Materials Science
Materials Science 工程技术-材料科学:综合
CiteScore
1.60
自引率
44.40%
发文量
63
审稿时长
4-8 weeks
期刊介绍: Materials Science reports on current research into such problems as cracking, fatigue and fracture, especially in active environments as well as corrosion and anticorrosion protection of structural metallic and polymer materials, and the development of new materials.
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