One of the most significant drawbacks of the all-electron ab initio diffusion Monte Carlo (DMC) is that its computational cost drastically increases with the atomic number (Z), which typically scales with Z(similar to 6). In this study, we introduce a very efficient implementation of the lattice regularized diffusion Monte Carlo (LRDMC), where the conventional time discretization is replaced by its lattice space counterpart. This scheme enables us to conveniently adopt a small lattice space in the vicinity of nuclei, and a large one in the valence region, by which a considerable speedup is achieved, especially for large atomic number Z. Indeed, the computational performances of the improved LRDMC can be theoretically established based on the Thomas-Fermi model for heavy atoms, implying the optimal Z(similar to 5) scaling for all-electron DMC calculations. This improvement enables us to apply the DMC technique even for superheavy elements (Z >= 104), such as oganesson (Z = 118), which has the highest atomic number of all synthesized elements so far.
Speeding up ab initio diffusion Monte Carlo simulations by a smart lattice regularization / Nakano, Kousuke; Maezono, Ryo; Sorella, Sandro. - In: PHYSICAL REVIEW. B. - ISSN 2469-9950. - 101:15(2020), pp. 1-12. [10.1103/PhysRevB.101.155106]
Speeding up ab initio diffusion Monte Carlo simulations by a smart lattice regularization
Sorella, SandroMembro del Collaboration group
2020-01-01
Abstract
One of the most significant drawbacks of the all-electron ab initio diffusion Monte Carlo (DMC) is that its computational cost drastically increases with the atomic number (Z), which typically scales with Z(similar to 6). In this study, we introduce a very efficient implementation of the lattice regularized diffusion Monte Carlo (LRDMC), where the conventional time discretization is replaced by its lattice space counterpart. This scheme enables us to conveniently adopt a small lattice space in the vicinity of nuclei, and a large one in the valence region, by which a considerable speedup is achieved, especially for large atomic number Z. Indeed, the computational performances of the improved LRDMC can be theoretically established based on the Thomas-Fermi model for heavy atoms, implying the optimal Z(similar to 5) scaling for all-electron DMC calculations. This improvement enables us to apply the DMC technique even for superheavy elements (Z >= 104), such as oganesson (Z = 118), which has the highest atomic number of all synthesized elements so far.File | Dimensione | Formato | |
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