Environment-assisted quantum walks in photosynthetic energy transfer

Mohseni, Masoud; Rebentrost, Patrick; Lloyd, Seth; Aspuru‐Guzik, Alán

doi:10.1063/1.3002335

Cited by 1,147 publications

(1,493 citation statements)

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“…This finding mirrors the results found in the transport analysis of the FMO complex 9,16 and demonstrates that no fine-tuning of specific vibrational modes is required to sustain robust and efficient environmentally assisted energy transfer. 11,12,56 5 Chlb/Chla transfer time-scale in LHC II LHC II has been extensively studied within the Redfield, Förster, and interpolating approximations. Without an exact solution of the open system dynamics obtained with QMaster, the error made by the approximate methods is undefined and it is not known which approximation works best for a specific system.…”

Section: Influence Of the Vibrational Peaks On The Transport In Lhc IImentioning

confidence: 99%

“…4 On top of the relaxation process, oscillatory components prevail in 2d-spectra which contain signatures of electronic coherences and specific vibrational modes. 6,[8][9][10] The coupling to the environment determines the transfer efficiency in LHCs 11,12 through the bath-correlation time of the phonon bath, [13][14][15] the shape of the continuum part of the spectral density, 9,16 and specific structures within the spectral density. 9,17 For the FMO complex, the superohmic character of the spectral density results in long-lasting electronic coherences despite a strong coupling to the environment.…”

Section: Introductionmentioning

confidence: 99%

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Scalable High-Performance Algorithm for the Simulation of Exciton Dynamics. Application to the Light-Harvesting Complex II in the Presence of Resonant Vibrational Modes

Kreisbeck

Kramer

Aspuru‐Guzik

2014

J. Chem. Theory Comput.

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117

160

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The accurate simulation of excitonic energy transfer in molecular complexes with coupled electronic and vibrational degrees of freedom is essential for comparing excitonic systemparameters obtained from ab-initio methods with measured time-resolved spectra. Several exact methods for computing the exciton dynamics within a density-matrix formalism are known, * To whom correspondence should be addressed † Institut für Physik, Humboldt-Universität zu Berlin, Newtonstr. 15, 12489 Berlin, Germany ‡ Mads Clausen Institute, University of Southern Denmark, Alsion 2, 6400 Sønderborg, Denmark ¶ Department of Chemistry and Chemical Biology, Harvard University, 12 Oxford St, Cambridge, Massachusetts 02138, USA 1 but are restricted to small systems with less than ten sites due to their computational complexity. To study the excitonic energy transfer in larger systems, we adapt and extend the exact hierarchical equation of motion (HEOM) method to various high-performance many-core platforms using the Open Compute Language (OpenCL). For the light-harvesting complex II (LHC II) found in spinach, the HEOM results deviate from predictions of approximate theories and clarify the time-scale of the transfer-process. We investigate the impact of resonantly coupled vibrations on the relaxation and show that the transfer does not rely on a fine-tuning of specific modes.

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Section: Influence Of the Vibrational Peaks On The Transport In Lhc IImentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Scalable High-Performance Algorithm for the Simulation of Exciton Dynamics. Application to the Light-Harvesting Complex II in the Presence of Resonant Vibrational Modes

Kreisbeck

Kramer

Aspuru‐Guzik

2014

J. Chem. Theory Comput.

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117

160

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“…In the case of the Fenna-MatthewsOlson (FMO) complex, these coherences can persist on picosecond timescales in cryogenic conditions and are still observable at room temperatures [2,8]. Several phenomenological theories have subsequently shown that there is an optimal mixture of coherent inter-pigment energy transport and stochastic environmental noise that may lead to faster and higher-yield energy delivery in PPC architectures, suggesting that quantum effects may underpin their efficient function [9][10][11][12][13][14][15]. Microscopic investigations have also recently shown the key role of both discrete and continuous environmental fluctuation spectra in stabilising the long-lasting coherences observed in spectroscopy as well as facilitating efficient transport [16][17][18][19][20].…”

mentioning

confidence: 99%

“…The states obeying H S |e n = E n |e n are in general delocalized excitonic states, which can be also be expressed in the site basis as |e n = ∑ i C i n |i . The ultimate transfer of the exciton to a reaction center is modelled by including an isolated site (labeled 0 and referred to as the 'sink') which is populated irreversibly from a particular local site [9][10][11].…”

mentioning

confidence: 99%

Exploiting Structured Environments for Efficient Energy Transfer: The Phonon Antenna Mechanism

Rey

Chin

Huelga

et al. 2013

J. Phys. Chem. Lett.

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A non-trivial interplay between quantum coherence and dissipative environment-driven dynamics is becoming increasingly recognised as key for efficient energy transport in photosynthetic pigment-protein complexes, and converting these biologically-inspired insights into a set of design principles that can be implemented in artificial light-harvesting systems has become an active research field. Here we identify a specific design principlethe phonon antenna -that demonstrates how inter-pigment coherence is able to modify and optimize the way that excitations spectrally sample their local environmental fluctuations. We place this principle into a broader context and furthermore we provide evidence that the Fenna-Matthews-Olson complex of green sulphur bacteria has an excitonic structure that is close to such an optimal operating point, and suggest that this general design principle might well be exploited in other biomolecular systems. Introduction.-Experimental techniques such as optical 2D Fourier Transform spectroscopy have recently begun to probe the ultrafast photophysics of energy transport in a range of pigment-protein complexes (PPCs) taken from photosynthetic green sulphur bacteria, marine algae and higher plants [1][2][3][4]. All of the key photosynthetic light reactions (photon capture, energy transport and charge generation) are carried out in PPC structures [5,6], and the often > 90% quantum efficiency with which they carry out these functions has created considerable interest in understanding and exploiting their design features for artifical solar energy applications [5,7]. Surprisingly, recent experiments have found direct evidence for long-lasting quantum coherence amongst the excitons which transport energy in these complexes. In the case of the Fenna-MatthewsOlson (FMO) complex, these coherences can persist on picosecond timescales in cryogenic conditions and are still observable at room temperatures [2,8]. Several phenomenological theories have subsequently shown that there is an optimal mixture of coherent inter-pigment energy transport and stochastic environmental noise that may lead to faster and higher-yield energy delivery in PPC architectures, suggesting that quantum effects may underpin their efficient function [9][10][11][12][13][14][15]. Microscopic investigations have also recently shown the key role of both discrete and continuous environmental fluctuation spectra in stabilising the long-lasting coherences observed in spectroscopy as well as facilitating efficient transport [16][17][18][19][20].

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“…In periodic systems, for example, the quantum particle propagates much faster (ballistic propagation) than its classical counterpart (diffusive propagation) [1]. Quantum walkers have been widely studied in a variety of different settings such as in the development of quantum algorithms [2][3][4], efficient energy transfer in proteins complex [5], classical optics [6,7], waveguide lattices [8,9], nuclear magnetic resonance [10], quantum dots [11], trapped atoms in optical lattices [12,13], disorder [14,15], interacting particles [16,17] and bacteria behavior in biological systems [18].…”

Section: Introductionmentioning

confidence: 99%

Unidirectional quantum walk of two correlated particles: Manipulating bound-pair and unbound wave-packet components

Buarque¹,

Dias²

2017

Physics Letters A

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We study the unidirectional transport of two-particle quantum wavepackets in a regular onedimensional lattice. We show that the bound-pair state component behaves differently from unbound states when subjected to an external pulsed electric field. Thus, strongly entangled particles exhibit a quite distinct dynamics when compared to a single particle system. With respect to centroid motion, our numerical results are corroborated with an analytical expression obtained using a semiclassical approach. The wavefunction profile reveals that the particle-particle interaction induces the splitting of the initial wavepacket into two branches that propagate with specific directions and drift velocities. With a proper external field tunning, the wavepacket components can perform an unidirectional transport on the same or opposite directions. The amplitude of each mode is related to the degree of entanglement betweem particles, which presents a non-monotonic dependence on the interaction strength.

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Environment-assisted quantum walks in photosynthetic energy transfer

Cited by 1,147 publications

References 61 publications

Scalable High-Performance Algorithm for the Simulation of Exciton Dynamics. Application to the Light-Harvesting Complex II in the Presence of Resonant Vibrational Modes

Scalable High-Performance Algorithm for the Simulation of Exciton Dynamics. Application to the Light-Harvesting Complex II in the Presence of Resonant Vibrational Modes

Exploiting Structured Environments for Efficient Energy Transfer: The Phonon Antenna Mechanism

Unidirectional quantum walk of two correlated particles: Manipulating bound-pair and unbound wave-packet components

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