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Neural network variational Monte Carlo for positronic chemistry

Gino Cassella, W. M. C. Foulkes, David Pfau, James S. Spencer

2024Nature Communications11 citationsDOIOpen Access PDF

Abstract

Quantum chemical calculations of the ground-state properties of positron-molecule complexes are challenging. The main difficulty lies in employing an appropriate basis set for representing the coalescence between electrons and a positron. Here, we tackle this problem with the recently developed Fermionic neural network (FermiNet) wavefunction, which does not depend on a basis set. We find that FermiNet produces highly accurate, in some cases state-of-the-art, ground-state energies across a range of atoms and small molecules with a wide variety of qualitatively distinct positron binding characteristics. We calculate the binding energy of the challenging non-polar benzene molecule, finding good agreement with the experimental value, and obtain annihilation rates which compare favourably with those obtained with explicitly correlated Gaussian wavefunctions. Our results demonstrate a generic advantage of neural network wavefunction-based methods and broaden their applicability to systems beyond the standard molecular Hamiltonian.

Topics & Concepts

Wave functionHamiltonian (control theory)Ground statePhysicsStatistical physicsGaussianVariational Monte CarloElectronPositronBinding energyCoalescence (physics)Quantum Monte CarloMonte Carlo methodQuantum mechanicsMathematicsAstrobiologyMathematical optimizationStatisticsMuon and positron interactions and applicationsAdvanced Chemical Physics StudiesAdvanced NMR Techniques and Applications
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