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Real-Time Time-Dependent Nuclear−Electronic Orbital Approach: Dynamics beyond the Born–Oppenheimer Approximation

Luning Zhao, Zhen Tao, Fabijan Pavošević, Andrew Wildman, Sharon Hammes‐Schiffer, Xiaosong Li

2020The Journal of Physical Chemistry Letters78 citationsDOIOpen Access PDF

Abstract

The quantum mechanical treatment of both electrons and nuclei is crucial in nonadiabatic dynamical processes such as proton-coupled electron transfer. The nuclear-electronic orbital (NEO) method provides an elegant framework for including nuclear quantum effects beyond the Born-Oppenheimer approximation. To enable the study of nonequilibrium properties, we derive and implement a real-time NEO (RT-NEO) approach based on time-dependent Hatree-Fock or density functional theory, in which the electronic and nuclear degrees of freedom are propagated in a time-dependent variational framework. Nuclear and electronic spectral features can be resolved from the time-dependent dipole moment computed using the RT-NEO method. The test cases show the dynamical interplay between the quantum nuclei and the electrons through vibronic coupling. Moreover, vibrational excitation in the RT-NEO approach is demonstrated by applying a resonant driving field, and electronic excitation is demonstrated by simulating excited state intramolecular proton transfer. This work shows that the RT-NEO approach is a promising tool to study nonadiabatic quantum dynamical processes within a time-dependent variational description for the coupled electronic and nuclear degrees of freedom.

Topics & Concepts

Born–Oppenheimer approximationPhysicsTime evolutionDynamics (music)Deep timeStatistical physicsQuantum mechanicsGeologyMoleculePaleontologyAcousticsSpectroscopy and Quantum Chemical StudiesAdvanced NMR Techniques and ApplicationsAdvanced Chemical Physics Studies
Real-Time Time-Dependent Nuclear−Electronic Orbital Approach: Dynamics beyond the Born–Oppenheimer Approximation | Litcius