Generalized nonequilibrium Fermi’s golden rule and its semiclassical approximations for electronic transitions between multiple states

Author:

Sun Xiang1234ORCID,Zhang Xiaofang123ORCID,Liu Zengkui1234ORCID

Affiliation:

1. Division of Arts and Sciences, NYU Shanghai 1 , 567 West Yangsi Road, Shanghai 200124, China

2. NYU-ECNU Center for Computational Chemistry at NYU Shanghai 2 , 3663 Zhongshan Road North, Shanghai 200062, China

3. Department of Chemistry, New York University 3 , New York, New York 10003, USA

4. Shanghai Frontiers Science Center of Artificial Intelligence and Deep Learning, NYU Shanghai 4 , 567 West Yangsi Road, Shanghai 200124, China

Abstract

The nonequilibrium Fermi’s golden rule (NE-FGR) approach is developed to simulate the electronic transitions between multiple excited states in complex condensed-phase systems described by the recently proposed multi-state harmonic (MSH) model Hamiltonian. The MSH models were constructed to faithfully capture the photoinduced charge transfer dynamics in a prototypical organic photovoltaic carotenoid-porphyrin-C60 molecular triad dissolved in tetrahydrofuran. A general expression of the fully quantum-mechanical NE-FGR rate coefficients for transitions between all pairs of states in the MSH model is obtained. Besides, the linearized semiclassical NE-FGR formula and a series of semiclassical approximations featuring Wigner and classical nuclear sampling choices and different dynamics during the quantum coherence period for the MSH model are derived. The current approach enables all the possible population transfer pathways between the excited states of the triad, in contrast to the previous applications that only addressed the donor-to-acceptor transition. Our simulations for two triad conformations serve as a demonstration for benchmarking different NE-FGR approximations and show that the difference between all levels of approximation is small for the current system, especially at room temperature. By comparing with nonadiabatic semiclassical dynamics, we observe similar timescales for the electronic population transfer predicted by NE-FGR. It is believed that the general formulation of NE-FGR for the MSH Hamiltonian enables a variety of applications in realistic systems.

Funder

National Natural Science Foundation of China

Hefei National Laboratory for Physical Sciences at the Microscale

Publisher

AIP Publishing

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