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Influence of casting temperature on microstructures and mechanical properties of Cu50Zr45.5Ti2.5Y2 metallic glass prepared using copper mold casting
Author(s) -
Zhengwang Zhu,
Haifeng Zhang,
Hao Wang,
Bingzhe Ding,
Zhuangqi Hu,
Han Huang
Publication year - 2009
Publication title -
journal of materials research/pratt's guide to venture capital sources
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.788
H-Index - 148
eISSN - 0884-2914
pISSN - 0884-1616
DOI - 10.1557/jmr.2009.0373
Subject(s) - materials science , microstructure , casting , amorphous metal , nanoindentation , alloy , composite material , phase (matter) , metallurgy , supercooling , composite number , amorphous solid , crystallography , thermodynamics , chemistry , physics , organic chemistry
We investigated the influence of casting temperatures on microstructures and mechanical properties of rapidly solidified Cu50Zr45.5Ti2.5Y2 alloy. With casting temperatures increasing, the content of the crystalline phase decreases. At high casting temperature, i.e., 1723 K, glass forming ability (GFA) of the present alloy enhanced. It is implied that adjusting casting temperatures could be used for designing the microstructures of bulk metallic glass matrix composite (BMGC). Nano-indentation tests\udindicated that CuZr phases is a little softer and can accommodate more plastic deformation than the amorphous matrix. Compression tests confirmed that this kind of the second phase (CuZr) precipitated under lower casting temperatures helps to initiate multiple shear bands, resulting in great improvement of mechanical properties of the samples. Our work indicate that casting temperatures lead a great influence on GFA, microstructures and mechanical properties of rapidly solidified alloy and controlling casting temperatures is crucial to the application of BMGs

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