INTERACTION OF HYDROGEN IMPURITY WITH NANOCRYSTALLINE PALLADIUM AND NICKEL

Q3 Materials Science
G. Poletaev, I. Zorya, Roman Rakitin
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Abstract

The interaction of hydrogen atoms with nanocrystalline palladium and nickel in the work was studied by the molecular dynamics method. The nanocrystalline structure of palladium and nickel was created in the model by crystallization from the liquid state at the presence of several specially introduced crystalline embryos. After solidification, the calculation blocks, in addition to the crystalline phase, contained grain boundaries and triple junctions of grain boundaries. The interactions of metal atoms with each other were described by the multi-particle Cleri-Rosato potential constructed in the framework of the tight-binding model. Morse potentials were used to describe the interactions of hydrogen atoms with metal atoms and with each other. The parameters of Morse potentials were calculated from the experimental data of theabsorption energy, the activation energy of the above-barrier diffusion of hydrogen in a metal (at normal and high temperatures), the binding energy with a vacancy, dilatation. According to the results obtained in the present work, at a high concentration of hydrogen (the concentration of 10% from the metal atoms was considered), the hydrogen atoms combine into aggregates, which are formed predominantly near the surface of the metal. The aggregates contained, as a rule, several dozen hydrogen atoms and had low diffusion activity. The binding energy of hydrogen atoms with these aggregates was greater than with the metal crystal lattice or grain boundaries in it. In palladium, hydrogen aggregates were formed farther from the surface than in nickel. Apparently, this is due not so much to the relatively low energy of hydrogen absorption by palladium (–0.1 eV) in comparison with nickel (0.16 eV), but rather to the difference in lattice parameters of the metals under consideration: 3.89 Å for Pd and 3.524 Å for Ni. For the same reason, conspicuously, hydrogen aggregates in a pure crystal lattice were more often observed in Pd than in Ni. In Ni, aggregates, as a rule, were formed in defect areas containing an excess free volume: near the free surface, in grain boundaries and in triple junctions.
氢杂质与纳米晶钯、镍的相互作用
用分子动力学方法研究了工作中氢原子与纳米晶钯、镍的相互作用。在模型中,钯和镍的纳米晶结构是在几个特别引入的晶体胚胎的存在下由液态结晶而成的。凝固后的计算块除晶相外,还包含晶界和晶界的三重结。金属原子之间的相互作用用在紧密结合模型框架下构建的多粒子Cleri-Rosato势来描述。莫尔斯电势被用来描述氢原子与金属原子以及氢原子与金属原子之间的相互作用。根据吸收能、氢在金属中(常温和高温下)势垒以上扩散的活化能、带空位的结合能、膨胀的实验数据,计算了摩尔斯势的参数。根据本研究的结果,在高浓度的氢(考虑来自金属原子的浓度为10%)下,氢原子结合成聚集体,聚集体主要在金属表面附近形成。聚集体通常含有几十个氢原子,具有较低的扩散活性。在这些聚集体中氢原子的结合能比在金属晶格或晶界中氢原子的结合能大。在钯中,氢聚集体的形成距离表面比在镍中更远。显然,这并不是因为钯(-0.1 eV)与镍(0.16 eV)相比吸收氢的能量相对较低,而是因为所考虑的金属晶格参数的差异:Pd为3.89 Å, Ni为3.524 Å。由于同样的原因,明显地,氢在纯晶格中的聚集在Pd中比在Ni中更常见。在Ni中,通常在含有过量自由体积的缺陷区域形成聚集体:靠近自由表面、晶界和三重结。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya
Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya Materials Science-Materials Science (miscellaneous)
CiteScore
0.90
自引率
0.00%
发文量
81
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