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Non-adiabatic mapping dynamics in the phase space of the <i>SU</i> ( <i>N</i> ) Lie group

Duncan Bossion, Wenxiang Ying, Sutirtha N. Chowdhury, Pengfei Huo

2022The Journal of Chemical Physics24 citationsDOI

Abstract

We present the rigorous theoretical framework of the generalized spin mapping representation for non-adiabatic dynamics. Our work is based upon a new mapping formalism recently introduced by Runeson and Richardson [J. Chem. Phys. 152, 084110 (2020)], which uses the generators of the su(N) Lie algebra to represent N discrete electronic states, thus preserving the size of the original Hilbert space. Following this interesting idea, the Stratonovich-Weyl transform is used to map an operator in the Hilbert space to a continuous function on the SU(N) Lie group, i.e., a smooth manifold which is a phase space of continuous variables. We further use the Wigner representation to describe the nuclear degrees of freedom and derive an exact expression of the time-correlation function as well as the exact quantum Liouvillian for the non-adiabatic system. Making the linearization approximation, this exact Liouvillian is reduced to the Liouvillian of several recently proposed methods, and the performance of this linearized method is tested using non-adiabatic models. We envision that the theoretical work presented here provides a rigorous and unified framework to formally derive non-adiabatic quantum dynamics approaches with continuous variables and connects the previous methods in a clear and concise manner.

Topics & Concepts

Hilbert spaceAdiabatic processLie algebraLie groupPhase spaceMathematicsLinearizationMathematical physicsPhysicsQuantum mechanicsAlgebra over a fieldPure mathematicsNonlinear systemSpectroscopy and Quantum Chemical StudiesMolecular spectroscopy and chiralityAdvanced Chemical Physics Studies
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