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Generalized spin mapping for quantum-classical dynamics

Johan E. Runeson, Jeremy O. Richardson

2020The Journal of Chemical Physics117 citationsDOIOpen Access PDF

Abstract

We recently derived a spin-mapping approach for treating the nonadiabatic dynamics of a two-level system in a classical environment [J. E. Runeson and J. O. Richardson, J. Chem. Phys. 151, 044119 (2019)] based on the well-known quantum equivalence between a two-level system and a spin-1/2 particle. In the present paper, we generalize this method to describe the dynamics of N-level systems. This is done via a mapping to a classical phase space that preserves the SU(N)-symmetry of the original quantum problem. The theory reproduces the standard Meyer-Miller-Stock-Thoss Hamiltonian without invoking an extended phase space, and we thus avoid leakage from the physical subspace. In contrast to the standard derivation of this Hamiltonian, the generalized spin mapping leads to an N-dependent value of the zero-point energy parameter that is uniquely determined by the Casimir invariant of the N-level system. Based on this mapping, we derive a simple way to approximate correlation functions in complex nonadiabatic molecular systems via classical trajectories and present benchmark calculations on the seven-state Fenna-Matthews-Olson light-harvesting complex. The results are significantly more accurate than conventional Ehrenfest dynamics, at a comparable computational cost, and can compete in accuracy with other state-of-the-art mapping approaches.

Topics & Concepts

Phase spaceHamiltonian (control theory)Casimir effectQuantumPhysicsQuantum dynamicsStatistical physicsQuantum systemHomogeneous spaceSubspace topologyQuantum mechanicsInvariant (physics)Hamiltonian mechanicsMathematicsMathematical analysisGeometryMathematical optimizationSpectroscopy and Quantum Chemical StudiesQuantum, superfluid, helium dynamicsMolecular spectroscopy and chirality
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