Abstract
Using ab initio Hartree-Fock self-consistent field method combined with many-body expansion method, the investigation is based on the first-principles. We have considered two-, three- and four-body potential energies of face-centered cubic (fcc) solid neon of which the atomic distance ranges from 1.6 to 3.0 . By discussing the truncation and convergence of many-body potential of solid neon, we obtain the cohesive energy, the zero-point vibration energy and equation of state (EOS). The results show that, when the number of neighboring atoms increases, two-body, three-body, and four-body potential energy tend to a saturation value for a certain atomic distance ( ). The even many-body contributions to the cohesive energy, such as two-, four-body terms and so on, are positive, whereas the odd many-body contributions to the cohesive energy, such as three-, five-body terms and so on, are negative. The zero-point vibration energy of solid neon is only 6% of the total atomic interaction energy, but should not be neglected. Compared with the experimental data, the importance of the four-body interactions in compressed solid neon is emphasized. Only taking into account the two-body term, the pressure is overestimated, and our calculated results are in good agreement with the experimental values at the low-pressure regions (<15GPa). Adding three-body term up to 55GPa, considering the four-body term, it has a good consistency at the experimentally studied pressure range of 0~237GPa, and maybe helpful to accurately explain the phenomenon of the experiment above 237GPa when the higher many-body effects are considered.
Highlights
The condensed matters of solid Neon (Ne) have been one of the widely studied materials both theoretically and experimentally [1,2,3,4,5,6]
The results show that the two-body and three-body potentials can only accurately describe the compression properties of solid Ne at low pressure, the compression properties at high pressures can not been described precisely
When the atomic distance (R) decreases, we have to consider the effects of neighboring atoms of the second, third shells and higher shells
Summary
The condensed matters of solid Neon (Ne) have been one of the widely studied materials both theoretically and experimentally [1,2,3,4,5,6]. The many-body potential energy and equation of state for solid Ne have attracted many significant attentions theoretically and experimentally [8,9,10,11,12,13]. These studies mainly contain research work of two-body potential and three-body potential. Using the combination of Hartree-Fock SCF and many-body expansion methods, we accurately calculate two-, three- and four-body potentials of fcc solid Ne when the atomic distance (R) increases from 1.6Å to 3.0Å, and discuss the truncation and convergence of many-body potential. Energy, the zero-point vibration energy and equation of state of solid Ne are obtained
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