Abstract
The mapping approach addresses the mismatch between the continuous nuclear phase space and discrete electronic states by creating an extended, fully continuous phase space using a set of harmonic oscillators to encode the populations and coherences of the electronic states. Existing quasiclassical dynamics methods based on mapping, such as the linearised semiclassical initial value representation (LSC-IVR) and Poisson bracket mapping equation (PBME) approaches, have been shown to fail in predicting the correct relaxation of electronic-state populations following an initial excitation. Here we generalise our recently published modification to the standard quasiclassical approximation for simulating quantum correlation functions. We show that the electronic-state population operator in any system can be exactly rewritten as a sum of a traceless operator and the identity operator. We show that by treating the latter at a quantum level instead of using the mapping approach, the accuracy of traditional quasiclassical dynamics methods can be drastically improved, without changes to their underlying equations of motion. We demonstrate this approach for the seven-state Frenkel-exciton model of the Fenna-Matthews-Olson light harvesting complex, showing that our modification significantly improves the accuracy of traditional mapping approaches when compared to numerically exact quantum results.
Highlights
Simulating nonadiabatic effects in quantum dynamics continues to pose a considerable challenge in theoretical chemistry and physics, especially in the condensed phase
There are two differences between the phase-space representations given in eqn (7a) and (7b): the factor of f(X,P), which is only present in ASnEO, and the differing constant terms, which are related to zero-point energy (ZPE) of the mapping degree of freedom (DoF).[45]
The Frenkel-exciton model for the energy transfer in FMO is a challenging benchmark for quantum dynamics methods
Summary
Approximation, these effects have been found to have a profound impact on a wide range of systems spanning physics, chemistry and biology.[1,2,3]. Given the favourable scaling of classical trajectories with respect to the nuclear DoFs, a number of mixed quantum-classical dynamics approaches, aimed speci cally at large, realistic systems in the condensed phase, have been developed based on this formalism.[10,11,12,14,24,26] Note that in this work we will use the term quasiclassical to refer to mixed quantum-classical approaches which employ a single set of mapping variables per electronic state as well as a single set of positions and momenta for each nuclear degree of freedom. We apply this general formulation to the challenging benchmark model for the Fenna–Matthews–Olson (FMO) light harvesting complex.[40,41,42,43,44] Our results are signi cantly more accurate than those obtained using the standard operator de nitions and in excellent agreement with numerically exact quantum dynamics methods
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