Microdomain atomic structure of Zr₅₀Pd₄₀Al₁₀ metallic glasses and its formation mechanism

Kai Li^1,2,3，Fangliang Gao^1,2,3，Yu-Jen Chou³，Kaixiang Shen⁴，Guoqiang Li^1,2,3

1. State Key Laboratory of Luminescent Materials and Devices, South China University of Technology2. Engineering Research Center on Solid-State Lighting and Its Informationisation of Guangdong Province, South China University of Technology3. Department of Electronic Materials, School of Materials Science and Engineering, South China University of Technology4. School of Physics and Telecommunications Engineering, South China Normal University

摘 要：Zr-based Zr₅0Pd₄0Al₁0 metallic glasses has not only crystalline phases of about 5 nm in diameter but also amorphous phases. In this work, the radial distribution functions（RDFs） of amorphous structure of Zr₅0Pd₄0Al₁0 metallic glasses were firstly measured by electron diffraction, and then Reverse Monte Carlo（RMC） optimization accompanied by density functional theory（DFT） calculations. The amorphous structure has not only short-range order but also good medium-range order. In the RDFs of its amorphous structure, the first and the second peaks are located at 2.96 ? and 4.79 ?, respectively. Partial radical distribution functions（PRDFs） show that the contributions of the first and the second nearest-neighbor distances of various atom pairs to the G（r） peak values, and the first nearest-neighbor distances of Pd–Zr and Zr–Zr atom pairs are the sources of main G（r） peak values between 2? and 6?. The competition mechanism for generating the Pd₂5Zr₅5 Al₂0 amorphous phase and the intermetallic crystalline phase Pd₁1Zr₉ is associated with the differences of atomic radius, the proportion, and the melting point of different atoms, as well as the heat of mixing between atoms, leading to an equilibrium state of the two phases. Accordingly, a composite system with intertwined nanocrystals and amorphous phases is in turn formed, and improves the stability of the material.

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