Quest for Spatially Correlated Fluctuations in the FMO Light-Harvesting Complex

Olbrich, Carsten; Strümpfer, Johan; Schulten, Klaus; Kleinekathöfer, Ulrich

doi:10.1021/jp1099514

Cited by 138 publications

(233 citation statements)

References 70 publications

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“…In contrast, the measured spectral linewidths predict electronic dephasing times at 77 K hardly exceeding 100 fs [11], owing to rapid, stochastic variations in the environment, and coherences between excitons are expected to decay roughly on this timescale. The long coherence times could be explained by correlations between the fluctuating electronic site transition energies, but these are not concordant with recent molecular dynamics simulations [12,13].…”

Section: Introductioncontrasting

confidence: 73%

Laser-Limited Signatures of Quantum Coherence

et al. 2015

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The observation of persistent oscillatory signals in multidimensional spectra of proteinpigment complexes has spurred a debate on the role of coherence-assisted electronic energy transfer as a key operating principle in photosynthesis. Vibronic coupling has recently been proposed as an explanation for the long lifetime of the observed spectral beatings. However, photosynthetic systems are inherently complicated, and tractable studies on simple molecular compounds are in demand to fully understand the underlying physics. In this work, we present measurements and calculations on a solvated molecular homodimer with clearly resolvable oscillations in the corresponding twodimensional spectra. Through analysis of the various contributions to the nonlinear response, we succeed in isolating the signal due to inter-exciton coherence. We find that while calculations predict a prolongation of this coherence due to vibronic coupling, the combination of dynamic disorder and vibrational relaxation leads to a coherence decay on a timescale comparable to the electronic dephasing time.

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Section: Introductioncontrasting

confidence: 73%

Laser-Limited Signatures of Quantum Coherence

et al. 2015

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“…Recent molecular dynamics (MD) simulation studies on the Fenna-Mathews-Olsen (FMO) excitation energy transfer network, 11,12 the light harvesting complex 2 (LHII) photosynthetic light harvesting complex 13 and the reaction center complex, 14 however, show no significant correlation in site energy fluctuations after averaging, and similar findings have been reported from calculations for the PE545 15 light harvesting system. However, Kleinekathöfer and co-workers, for example, have found that in FMO, 11 there is evidence of correlations in fluctuations of site energy and inter site electronic couplings and electronic coupling-electronic coupling correlations that are more significant compared to the apparently uncorrelated site energy fluctuations.…”

Section: Introductionmentioning

confidence: 58%

“…Several theoretical groups [11][12][13][14][15] have begun exploring detailed microscopic simulation models looking for different types of environment driven correlated fluctuations in chromophore electronic properties. The ubiquitous finding from the various photosynthetic energy transfer systems studied so far is that fluctuations in site energies seem to be such that on average they are uncorrelated.…”

Section: Discussionmentioning

confidence: 99%

“…However, Kleinekathöfer and co-workers, for example, have found that in FMO, 11 there is evidence of correlations in fluctuations of site energy and inter site electronic couplings and electronic coupling-electronic coupling correlations that are more significant compared to the apparently uncorrelated site energy fluctuations. There have been questions raised in recent work about the magnitudes of the parameters used, and the assumptions underlying some of these model calculations.…”

Section: Introductionmentioning

confidence: 99%

“…The possible origin of such correlations could be bath modes that influence the relative distances, and angles between two transition dipoles of different chromophores. 27 Some MD simulations suggest that correlated fluctuations in electronic coupling between chromophore dimer pairs that share a common chromophore, 11 for example, correlation between 4-5 coupling and 5-7 coupling in the FMO complex (i.e., inter-site coupling-inter-site coupling correlations) may be significant and one of the primary goals of this paper is to explore the effects of such correlation on the quantum dynamics of model chromophore networks. The simplified systems we explore in this paper thus include both a two state model where we can single out the effects of site energy-inter-site coupling correlations, and a three state example that is a minimal model in which inter-site couplinginter-site coupling correlation can be explored.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Influence of environment induced correlated fluctuations in electronic coupling on coherent excitation energy transfer dynamics in model photosynthetic systems

Huo

Coker

2012

The Journal of Chemical Physics

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Two-dimensional photon-echo experiments indicate that excitation energy transfer between chromophores near the reaction center of the photosynthetic purple bacterium Rhodobacter sphaeroides occurs coherently with decoherence times of hundreds of femtoseconds, comparable to the energy transfer time scale in these systems. The original explanation of this observation suggested that correlated fluctuations in chromophore excitation energies, driven by large scale protein motions could result in long lived coherent energy transfer dynamics. However, no significant site energy correlation has been found in recent molecular dynamics simulations of several model light harvesting systems. Instead, there is evidence of correlated fluctuations in site energy-electronic coupling and electronic coupling-electronic coupling. The roles of these different types of correlations in excitation energy transfer dynamics are not yet thoroughly understood, though the effects of site energy correlations have been well studied. In this paper, we introduce several general models that can realistically describe the effects of various types of correlated fluctuations in chromophore properties and systematically study the behavior of these models using general methods for treating dissipative quantum dynamics in complex multi-chromophore systems. The effects of correlation between site energy and inter-site electronic couplings are explored in a two state model of excitation energy transfer between the accessory bacteriochlorophyll and bacteriopheophytin in a reaction center system and we find that these types of correlated fluctuations can enhance or suppress coherence and transfer rate simultaneously. In contrast, models for correlated fluctuations in chromophore excitation energies show enhanced coherent dynamics but necessarily show decrease in excitation energy transfer rate accompanying such coherence enhancement. Finally, for a three state model of the Fenna-Matthews-Olsen light harvesting complex, we explore the influence of including correlations in inter-chromophore couplings between different chromophore dimers that share a common chromophore. We find that the relative sign of the different correlations can have profound influence on decoherence time and energy transfer rate and can provide sensitive control of relaxation in these complex quantum dynamical open systems.

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Exciton Transport in Molecular Aggregates – From Natural Antennas to Synthetic Chromophore Systems

Brixner

Hildner

Köhler

et al. 2017

Advanced Energy Materials

284

301

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The transport of excitation energy in molecular aggregates is of crucial importance for the function of organic optoelectronic devices and next‐generation solar cells. First, this review summarizes the theoretical background of the nature of the electronically excited states of molecular aggregates. For these systems, the electronic interaction between the monomers leads to the formation of exciton states. This goes along with a shift of the excitation energies and a redistribution of the oscillator strength with respect to the monomers. Next, a brief overview is provided over experimental techniques that allow to study the properties of excitons in molecular aggregates. This includes single‐molecule spectroscopy, coherent two‐dimensional (2D) spectroscopy, and single‐molecule coherent spectroscopy. Finally, examples of molecular aggregates spanning the range from natural systems that act in photosynthesis as light‐harvesting antennas to artificial aggregates built from synthetic chromophores are illustrated.

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Quest for Spatially Correlated Fluctuations in the FMO Light-Harvesting Complex

Cited by 138 publications

References 70 publications

Laser-Limited Signatures of Quantum Coherence

Laser-Limited Signatures of Quantum Coherence

Influence of environment induced correlated fluctuations in electronic coupling on coherent excitation energy transfer dynamics in model photosynthetic systems

Exciton Transport in Molecular Aggregates – From Natural Antennas to Synthetic Chromophore Systems

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