Abstract
The calculation of electron correlation is vital for the description of atomistic phenomena in physics, chemistry, and biology. However, accurate wavefunction-based methods exhibit steep scaling and often sluggish convergence with respect to the basis set at hand. Because of their delocalization and ease of extrapolation to the basis-set limit, plane waves would be ideally suited for the calculation of basis-set limit correlation energies. However, the routine use of correlated wavefunction approaches in a plane-wave basis set is hampered by prohibitive scaling due to a large number of virtual continuum states and has not been feasible for all but the smallest systems, even if substantial computational resources are available and methods with comparably beneficial scaling, such as the Møller–Plesset perturbation theory to second order (MP2), are used. Here, we introduce a stochastic sampling of the MP2 integrand based on Monte Carlo summation over continuum orbitals, which allows for speedups of up to a factor of 1000. Given a fixed number of sampling points, the resulting algorithm is dominated by a flat scaling of . Absolute correlation energies are accurate to <0.1 kcal/mol with respect to conventional calculations for several hundreds of electrons. This allows for the calculation of unbiased basis-set limit correlation energies for systems containing hundreds of electrons with unprecedented efficiency gains based on a straightforward treatment of continuum contributions.
Highlights
Electron correlation lies at the heart of a wide range of fundamental physical and chemical phenomena, which range from the structural diversity and dynamics of water[1] over the dissociation of liquid hydrogen at high pressure[2] and the stability and mobility of point defects in semiconductors[3] to the barrier height of chemical reactions
Continuum states have been shown to be an important contributor to the overall electron correlation energy.[47]
Among the basis sets commonly used in solid-state physics, quantum chemical calculations, and first-principles molecular dynamics, plane wave (PW) stand out as the only choice that can effectively account for continuum contributions, which are the base of a simple basis-set limit extrapolation technique.[44]
Summary
Electron correlation lies at the heart of a wide range of fundamental physical and chemical phenomena, which range from the structural diversity and dynamics of water[1] over the dissociation of liquid hydrogen at high pressure[2] and the stability and mobility of point defects in semiconductors[3] to the barrier height of chemical reactions. The approach is based on a simple stochastic sampling of the integrands of eq 1 and can be implemented with little effort, representing a sleek and clean approach to tackle the issues arising in the continuum This opens the path to routine applications of PW MP2-based approaches in both isolated and periodic systems with up to hundreds of occupied orbitals, making it possible to obtain basis-set limit DH or MP2 correlation energies on conventional computational infrastructure within a reasonable time
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