钛和铝金属中轻杂质与空位的相互作用:DFT研究

Andrey I. Kartamyshev , Dat Duy Vo , Alexey G. Lipnitskii
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引用次数: 4

摘要

本文用密度泛函理论(DFT)计算了钛(Ti)和铝(Al)的面心立方(FCC)晶格中氢(H)、碳(C)、氮(N)和氧(O)原子之间的结合能和空位。我们还研究了一个空位捕获多达5个氢原子,以及由于氢-空位配合物的形成而导致的空位形成能的降低。我们使用了0 K连续弛豫的分子动力学模型,得到了空位-杂质配合物的原子构型,对应于全局能量最小值。根据我们的计算,C - v、H-V、C - (H-V)、N - (H-V)配合物在Al晶格中稳定,只有H-V配合物在Ti晶格中稳定。Al晶格中C - (H-V)和N - (H-V)配合物的形成导致空位形成能为负。H-V配合物的形成使Ti晶格中的空位形成能降低了0.26 eV。钛晶格中的一个空位可以捕获多达四个氢原子。
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The interaction between light impurities and vacancies in titanium and aluminum metals: A DFT study

In this paper, we present binding energies between hydrogen (H), carbon (C), nitrogen (N) and oxygen (O) atoms and a vacancy in the hexagonal closed-packed (HCP) lattice of titanium (Ti) and the face centered cubic (FCC) lattice of aluminum (Al), calculated using the density functional theory (DFT). We have also investigated the trapping of up to five hydrogen atoms by a vacancy and the reduction of the vacancy formation energy, due to the formation of a hydrogenvacancy complex. We used the molecular-dynamics modeling with consecutive relaxation at 0 K to obtain an atomic configuration of the vacancyimpurity complex, corresponding to the global energy minimum. According to our calculations, CV, HV, C (HV), N(HV) complexes are stable in the Al lattice with only HV complex being stable in Ti. The formation of C(HV) and N(HV) complexes in the Al lattice results in the negative vacancy formation energy. The formation of HV complex decreases the vacancy formation energy by 0.26 eV in the Ti lattice. A vacancy in the Ti lattice can trap up to four hydrogen atoms.

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