Calculation of Surface Binding Energy in Ni\({}_{\boldsymbol{x}}\)Pd\({}_{\boldsymbol{y}}\) Alloys Using Density Functional Theory

IF 0.4 4区 物理与天体物理 Q4 PHYSICS, MULTIDISCIPLINARY Moscow University Physics Bulletin Pub Date : 2024-08-15 DOI:10.3103/S0027134924700498
S. S. Moskalenko, J. A. Melkozerova, A. E. Ieshkin, I. K. Gainullin
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Abstract

In the study, surface binding energies for pure Ni and Pd metals were calculated using density functional theory. The values obtained were 5.32 and 4.65 eV, respectively, which represents good accuracy for ab initio calculations. The work also included calculations of surface binding energy for different configurations of NiPd alloys with nickel and palladium concentrations of 66, 50, and 33\(\%\). Calculations were performed for each type of lattice for both Ni and Pd surface binding energies. Several types of lattices were simulated, and it was found that the average surface binding energies for Ni and Pd are: 5.02 and 4.36 eV, respectively in the alloy with a Ni concentration of 50\(\%\); 4.89 and 4.22 eV, respectively in the alloy with a Ni concentration of 66\(\%\); 5.12 and 4.40 eV, respectively in the alloy with a Ni concentration of 33\(\%\).

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利用密度泛函理论计算 Ni $${}_{\boldsymbol{x}}$ Pd $$${}_{\boldsymbol{y}}$ 合金中的表面结合能
摘要 在这项研究中,使用密度泛函理论计算了纯镍和钯金属的表面结合能。得到的数值分别为 5.32 和 4.65 eV,这代表了良好的原子序数计算精度。这项工作还包括计算镍钯合金不同构型的表面结合能,镍和钯的浓度分别为 66、50 和 33(%)。每种类型的晶格都对镍和钯的表面结合能进行了计算。模拟了几种类型的晶格后发现,镍和钯的平均表面结合能分别为在镍浓度为 50\(\%\) 的合金中分别为 5.02 和 4.36 eV;在镍浓度为 66\(\%\) 的合金中分别为 4.89 和 4.22 eV;在镍浓度为 33\(\%\) 的合金中分别为 5.12 和 4.40 eV。
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来源期刊
Moscow University Physics Bulletin
Moscow University Physics Bulletin PHYSICS, MULTIDISCIPLINARY-
CiteScore
0.70
自引率
0.00%
发文量
129
审稿时长
6-12 weeks
期刊介绍: Moscow University Physics Bulletin publishes original papers (reviews, articles, and brief communications) in the following fields of experimental and theoretical physics: theoretical and mathematical physics; physics of nuclei and elementary particles; radiophysics, electronics, acoustics; optics and spectroscopy; laser physics; condensed matter physics; chemical physics, physical kinetics, and plasma physics; biophysics and medical physics; astronomy, astrophysics, and cosmology; physics of the Earth’s, atmosphere, and hydrosphere.
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