Tianding Xu, Xiao-Dong Wang, Eric M. Dufresne, Kevin A. Beyer, Pengfei An, Jingyuan Ma, Nan Wang, Suya Liu, Qing-Ping Cao, Shao-Qing Ding, Dong-Xian Zhang, Lei Zheng, Jing Zhang, Tian-Dou Hu, Zheng Jiang, Yuying Huang, Jian-Zhong Jiang
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引用次数: 0
摘要
β-松弛是金属玻璃(MGs)的主要动态行为之一,具有多种特征。尽管经过数十年的努力,人们对其结构起源及其对 MG 系统整体动力学的贡献仍不甚了解。本文报告了两种钯基 Pd─Cu─P 和 Pd─Ni─P MG,它们具有截然不同的β-松弛行为,并利用先进的 X 射线光子相关光谱和吸收精细结构技术以及第一原理计算揭示了造成这种差异的结构起源。Pd─Cu─P MG 中明显的β松弛和快速原子动力学主要来自于铜原子的强流动性及其局部有利的结构。与此相反,在 Pd─Ni─P MG 中,Ni 原子的运动受到 P 原子的限制,从而导致β-松弛峰减弱和动力学迟缓。原子动力学与微观结构的相关性为了解不同动力学行为的结构起源以及无序材料的老化性质提供了一种方法。
Unveiling the Structural Origins of Dynamic Diversity in Pd-Based Metallic Glasses
The β-relaxation is one of the major dynamic behaviors in metallic glasses (MGs) and exhibits diverse features. Despite decades of efforts, the understanding of its structural origin and contribution to the overall dynamics of MG systems is still unclear. Here two palladium-based Pd─Cu─P and Pd─Ni─P MGs are reported with distinct different β-relaxation behaviors and reveal the structural origins for the difference using the advanced X-ray photon correlation spectroscopy and absorption fine structure techniques together with the first-principles calculations. The pronounced β-relaxation and fast atomic dynamics in the Pd─Cu─P MG mainly come from the strong mobility of Cu atoms and their locally favored structures. In contrast, the motion of Ni atoms is constrained by P atoms in the Pd─Ni─P MG, leading to the weakened β-relaxation peak and sluggish dynamics. The correlation of atomic dynamics with microscopic structures provides a way to understand the structural origins of different dynamic behaviors as well as the nature of aging in disordered materials.
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