合金元素对 α-Fe(110)表面氢吸附和扩散的影响:第一原理研究

Metals Pub Date : 2024-04-23 DOI:10.3390/met14050487
Luying Zhang, Qingzhe Zhang, Peng Jiang, Ying Liu, Chen-Yang Zhao, Yuhang Dong
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引用次数: 0

摘要

本研究基于第一原理密度泛函理论(DFT)方法,采用材料工作室(MS)软件中的剑桥序列总能量包(CASTEP)模块,在广义梯度近似下研究了氢原子在α-Fe(110)和α-Fe(110)-Me(锰、铬、镍、钼)表面的吸附、扩散行为和电子特性,包括计算其吸附能和状态密度(DOS)。结果表明,掺杂合金原子 Me 增加了表面上 H2 分子的物理吸附能。具体来说,掺入 Mo 后,吸附能从-1.00825 eV 上升到-0.70226 eV,最大的相对变化为 30.35%。掺杂 Me 后,两个氢原子的化学吸附能变化不大,其中掺杂 Cr 会导致化学吸附能下降。在此基础上,我们进一步分析了表面单原子的化学吸附情况。通过比较氢原子和铁/掺杂金属原子之间的吸附能和键长,发现掺杂钼的影响最大,键长增加了 58.58%。不同掺杂条件下的 DOS 函数分析验证了不同合金元素与氢原子之间的相互作用。同时,还对 H 原子扩散到金属内部所跨越的能量障碍进行了模拟。结果表明,镍元素的掺杂促进了 H 原子的扩散,而铬、锰和钼元素则阻碍了 H 原子的扩散,其中钼元素的影响最为显著,其能障是未掺杂表面的 21.88 倍。这一结论深入揭示了不同掺杂元素对氢吸附和扩散的影响,有助于设计抗氢脆材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effects of Alloying Element on Hydrogen Adsorption and Diffusion on α-Fe(110) Surfaces: First Principles Study
Based on first principles density functional theory (DFT) methods, this study employed the Cambridge Serial Total Energy Package (CASTEP) module within Materials Studio (MS) software under the generalized gradient approximation to investigate the adsorption, diffusion behavior, and electronic properties of hydrogen atoms on α-Fe(110) and α-Fe(110)-Me (Mn, Cr, Ni, Mo) surfaces, including calculations of their adsorption energies and density of states (DOS). The results demonstrated that doping with alloy atoms Me increased the physical adsorption energy of H2 molecules on the surface. Specifically, Mo doping elevated the adsorption energy from −1.00825 eV to −0.70226 eV, with the largest relative change being 30.35%. After doping with Me, the chemical adsorption energy of two hydrogen atoms does not change significantly, among which doping with Cr results in a decrease in the chemical adsorption energy. Building on this, further analysis of the chemical adsorption of single atoms on the surface was conducted. By comparing the adsorption energy and the bond length between a hydrogen atom and iron/dopant metal atom, it was found that Mo doping has the greatest impact, increasing the bond length by 58.58%. Analysis of the DOS functions under different doping conditions validated the interaction between different alloy elements and H atoms. Simultaneously, simulations were carried out on the energy barrier crossed by H atoms diffusing into the metal interior. The results indicate that Ni doping facilitates the diffusion of H atoms, while Cr, Mn, and Mo hinder their diffusion, with Mo having the most significant effect, where its barrier is 21.88 times that of the undoped surface. This conclusion offers deep insights into the impact of different doping elements on hydrogen adsorption and diffusion, aiding in the design of materials resistant to hydrogen embrittlement.
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