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Title: Long-range energy transport in photosystem II

Journal Article · · Journal of Chemical Physics
DOI:https://doi.org/10.1063/1.4953243· OSTI ID:22676032
;  [1];  [1]
  1. Department of Chemistry, University of California, Berkeley, California 94720 (United States)
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We simulate the long-range inter-complex electronic energy transfer in photosystem II—from the antenna complex, via a core complex, to the reaction center—using a non-Markovian (ZOFE) quantum master equation description that allows the electronic coherence involved in the energy transfer to be explicitly included at all length scales. This allows us to identify all locations where coherence is manifested and to further identify the pathways of the energy transfer in the full network of coupled chromophores using a description based on excitation probability currents. We investigate how the energy transfer depends on the initial excitation—localized, coherent initial excitation versus delocalized, incoherent initial excitation—and find that the overall energy transfer is remarkably robust with respect to such strong variations of the initial condition. To explore the importance of vibrationally enhanced transfer and to address the question of optimization in the system parameters, we systematically vary the strength of the coupling between the electronic and the vibrational degrees of freedom. We find that the natural parameters lie in a (broad) region that enables optimal transfer efficiency and that the overall long-range energy transfer on a ns time scale appears to be very robust with respect to variations in the vibronic coupling of up to an order of magnitude. Nevertheless, vibrationally enhanced transfer appears to be crucial to obtain a high transfer efficiency, with the latter falling sharply for couplings outside the optimal range. Comparison of our full quantum simulations to results obtained with a “classical” rate equation based on a modified-Redfield/generalized-Förster description previously used to simulate energy transfer dynamics in the entire photosystem II complex shows good agreement for the overall time scales of excitation energy transport.

OSTI ID:
22676032
Journal Information:
Journal of Chemical Physics, Vol. 144, Issue 24; Other Information: (c) 2016 Author(s); Country of input: International Atomic Energy Agency (IAEA); ISSN 0021-9606
Country of Publication:
United States
Language:
English

Cited By (6)

Charge and energy transfer in large molecular assemblies: Quantum state diffusion with an adaptive basis journal June 2019
Energy-dependent quenching adjusts the excitation diffusion length to regulate photosynthetic light harvesting journal September 2018
Exciton transport in the PE545 complex: insight from atomistic QM/MM-based quantum master equations and elastic network models journal November 2017
Quantum effects in biology: golden rule in enzymes, olfaction, photosynthesis and magnetodetection journal May 2017
Colloquium : Quantum coherence as a resource journal October 2017
Exciton transport in the PE545 complex: insight from atomistic QM/MM-based quantum master equations and elastic network models text January 2017

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Related Subjects

37 INORGANIC
ORGANIC
PHYSICAL AND ANALYTICAL CHEMISTRY
COUPLINGS
DEGREES OF FREEDOM
ENERGY TRANSFER
EXCITATION
EXPERIMENTAL DATA
POWER TRANSMISSION
REACTION KINETICS
SIMULATION