Litcius/Paper detail

Simultaneous Optimization of Nuclear–Electronic Orbitals

Aodong Liu, Mathew Chow, Andrew Wildman, Michael J. Frisch, Sharon Hammes‐Schiffer, Xiaosong Li

2022The Journal of Physical Chemistry A19 citationsDOIOpen Access PDF

Abstract

Accurate modeling of important nuclear quantum effects, such as nuclear delocalization, zero-point energy, and tunneling, as well as non-Born-Oppenheimer effects, requires treatment of both nuclei and electrons quantum mechanically. The nuclear-electronic orbital (NEO) method provides an elegant framework to treat specified nuclei, typically protons, on the same level as the electrons. In conventional electronic structure theory, finding a converged ground state can be a computationally demanding task; converging NEO wavefunctions, due to their coupled electronic and nuclear nature, is even more demanding. Herein, we present an efficient simultaneous optimization method that uses the direct inversion in the iterative subspace method to simultaneously converge wavefunctions for both the electrons and quantum nuclei. Benchmark studies show that the simultaneous optimization method can significantly reduce the computational cost compared to the conventional stepwise method for optimizing NEO wavefunctions for multicomponent systems.

Topics & Concepts

Wave functionAtomic orbitalElectronPhysicsElectronic structureQuantumSubspace topologyBenchmark (surveying)Quantum mechanicsDelocalized electronComputer scienceStatistical physicsArtificial intelligenceGeodesyGeographyAdvanced Chemical Physics StudiesMolecular Junctions and NanostructuresSpectroscopy and Quantum Chemical Studies