Abstract
In the Baeck-An (BA) approximation, first-order nonadiabatic coupling vectors are given in terms of adiabatic energy gaps and the second derivative of the gaps with respect to the coupling coordinate. In this paper, a time-dependent (TD) BA approximation is derived, where the couplings are computed from the energy gaps and their second time-derivatives. TD-BA couplings can be directly used in fewest switches surface hopping, enabling nonadiabatic dynamics with any electronic structure methods able to provide excitation energies and energy gradients. Test results of surface hopping with TD-BA couplings for ethylene and fulvene show that the TD-BA approximation delivers a qualitatively correct picture of the dynamics and a semiquantitative agreement with reference data computed with exact couplings. Nevertheless, TD-BA does not perform well in situations conjugating strong couplings and small velocities. Considered the uncertainties in the method, TD-BA couplings could be a competitive approach for inexpensive, exploratory dynamics with a small trajectories ensemble. We also assessed the potential use of TD-BA couplings for surface hopping dynamics with time-dependent density functional theory (TDDFT), but the results are not encouraging due to singlet instabilities near the crossing seam with the ground state.
Highlights
Surface hopping has become one of the main tools for nonadiabatic dynamics simulations of photoexcited molecules[1,2]
The results show that time-dependent Baeck-An (TD-BA) does a good job predicting the dynamics of these molecules
Surface hopping is commonly implemented to work with on-the-fly calculations of electronic properties obtained with many different quantum chemical methods[3,4,5,6,7,8,9], and it requires neither pre-calculated nor modeled global potential energy surfaces
Summary
Fewest switches surface hopping with Baeck-An couplings [version 1; peer review: 3 approved].
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