高压下Fe-X (X= Al, Cr, Mn, Ti, B, C)熔体动力学和热力学

Ying Zhang, Jian Tang, W. Wang, Yi Wu, D. Lin, Jun Wang, B. Tang, X. Hui, I. Belova, G. Murch, Jin Shan Li
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摘要

金属熔体的扩散率和粘度等动力学性质是揭示合金凝固过程中组织演变和玻璃形成能力的基础,从而控制材料的显微组织、缺陷和性能。本文采用从头算分子动力学方法,研究了Fe-X (X = 10- 15wt % Al, Cr, Mn和Ti,或1-2wt% B和C)熔体在不同温度和外部压力下的动力学和热力学性质以及结构弛豫,结果符合多组分铁基合金的兴趣浓度范围。动力学和结构弛豫由均方位移、速度自相关函数和自中间散射函数表征。热力学性质包括熵和热容,是基于态的振动和电子密度结合振动和电子贡献计算的。根据Stokes-Einstein关系和Hall-Wolynes (HW)关系揭示了结构弛豫与扩散之间的联系,并预测了高温高压下的动力学和热力学性质与实验和理论结果吻合较好。这项工作提供了对金属熔体的结构-性能关系的深入了解,这对开发先进的多组分铁基合金至关重要。
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Kinetics and Thermodynamics of Fe-X (X= Al, Cr, Mn, Ti, B, and C) Melts under High Pressure
The kinetic properties such as diffusivity and viscosity of the metal melt are the foundations to reveal the structure evolutions and the glass formation abilities during solidification of the investigated alloy, thus, to control the microstructures, defects and properties of materials. In this work, ab initio molecular dynamics simulations were utilized to investigate the kinetic and thermodynamic properties and the structural relaxations of Fe-X (X = 10-15 wt% Al, Cr, Mn and Ti, or 1-2wt% B and C) melts under various temperature and external pressure, which are in line with the interested concentration range of multi-component Fe-based alloys. The kinetics and structural relaxations are characterized by mean squared displacement, velocity autocorrelation function and self-intermediate scattering function. The thermodynamics properties including entropy and heat capacity are calculated by combining the vibrational and electronic contributions based on vibrational and electronic density of states. The predicted kinetics and thermodynamics properties under high temperature and pressure agree well with the experimental and theoretical results while the connection among structural relaxations and diffusion are revealed based on the Stokes-Einstein relation and the Hall-Wolynes (HW) relation. This work provides an insight into the structure-property relationships of metal melts, which are essential in the development of advanced multi-component Fe-based alloys.
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