开发用于电催化的 Ni-Mo 合金的嵌入原子法潜力/表面成分研究

Ambesh Gupta, Chinmay Dahale, Soumyadipta Maiti, Sriram Goverapet Srinivasan, Beena Rai
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引用次数: 0

摘要

镍-钼超合金因其优越的机械性能、出色的耐腐蚀性和抗氧化性、电催化行为和表面稳定性,已成为各种应用的首选材料。了解和优化镍钼合金的表面成分对提高其实际应用性能至关重要。传统的实验表面分析技术虽然信息量大,但成本和时间往往过高。同样,第一原理计算等理论方法也需要大量的计算资源,而且难以模拟大型结构。本研究介绍了利用蒙特卡洛/分子动力学(MC/MD)混合模拟研究镍钼合金表面成分的替代方法。我们报告了专为镍钼合金开发的优化嵌入式原子法(EAM)势,该势利用元素和面心立方(FCC)镍钼固溶体合金的经验晶格常数和形成能进行了精心参数化。通过对状态方程的评估,EAM 电位的可靠性得到了证实,重点是再现结构特性。利用这一经过验证的势,进行了 MC/MD 模拟,以了解镍钼合金纳米颗粒和扩展表面成分的深度变化。模拟结果表明,镍在表面优先偏析,而钼在次表层优先偏析。由于这种优先偏析,在为目标应用定制表面特性时,考虑表面偏析是非常重要的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Development of an embedded-atom method potential of Ni-Mo alloys for electrocatalysis / surface compositional studies
Ni-Mo superalloys have emerged as materials of choice for a diverse array of applications owing to their superior mechanical properties, exceptional corrosion and oxidation resistance, electrocatalytic behavior, and surface stability. Understanding and optimizing the surface composition of Ni-Mo alloys is critical for enhancing their performance in practical applications. Traditional experimental surface analysis techniques, while informative, are often prohibitive in terms of cost and time. Likewise, theoretical approaches such as first-principle calculations demand substantial computational resources and it is difficult to simulate large structures. This study introduces an alternative approach utilizing hybrid Monte-Carlo / Molecular Dynamics (MC/MD) simulations to investigate the surface composition of Ni-Mo alloys. We report the development of an optimized Embedded-Atom Method (EAM) potential specifically for Ni-Mo alloys, carefully parameterized using empirical lattice constants and formation energies of elemental and face-centered cubic (FCC) Ni-Mo solid solution alloys. The reliability of the EAM potential is corroborated via the evaluation of equations of state, with a particular focus on reproducing structural properties. Utilizing this validated potential, MC/MD simulations were performed to understand the depth-wise variations in the compositions of Ni-Mo alloy nanoparticles and extended surfaces. These simulations reveal a preferential segregation of nickel on surface, and molybdenum in sub-surface layer. Due to this preferential segregation, it is imperative to consider surface segregation while tailoring the surface properties for targeted applications.
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