The Quantum Trajectory-quided Adaptive Gaussian Methodology in the Libra Software Package

Abstract: In this account we report an implementation of the quantum trajectory-guided adaptive Gaussian (QTAG) method in a modular open-source Libra package for quantum dynamics calculations. The QTAG method is based on a representation of wavefunctions in terms of a quantum trajectory-guided adaptable Gaussians basis and is generalized for time-propagation on multiple coupled surfaces to be applicable to model nonadiabatic dynamics. The potential matrix elements are evaluated within either the local harmonic or bra-ke… Show more

“…In the present work, we approach the problem of the phase consistency correction and state identity tracking from the conceptually satisfying viewpoint of basis re-expansion. This re-expansion approach is also motivated by the recently presented integrator for the quantum trajectory with adaptive Gaussians (QTAG) methodology [40] as well as by the TD-SE integration in a quasi-diabatic basis. [41] Although we rely on the well-known ideas, we use them to develop a unified and self-consistent formalism for state tracking and phase correction.…”

Generalization of the Local Diabatization Approach for Propagating Electronic Degrees of Freedom in Nonadiabatic Dynamics

“…In the present work, we approach the problem of the phase consistency correction and state identity tracking from the conceptually satisfying viewpoint of basis re-expansion. This re-expansion approach is also motivated by the recently presented integrator for the quantum trajectory with adaptive Gaussians (QTAG) methodology [40] as well as by the TD-SE integration in a quasi-diabatic basis. [41] Although we rely on the well-known ideas, we use them to develop a unified and self-consistent formalism for state tracking and phase correction.…”

Generalization of the Local Diabatization Approach for Propagating Electronic Degrees of Freedom in Nonadiabatic Dynamics