Evidence for wavelike energy transfer through quantum coherence in photosynthetic systems

Engel, Gregory S.; Calhoun, Tessa R.; Read, Elizabeth L.; Ahn, Tae-Kyu; Mančal, Tomáš; Cheng, Yuan‐Chung; Blankenship, Robert E.; Fleming, Graham R.

doi:10.1038/nature05678

Cited by 2,966 publications

(3,283 citation statements)

References 26 publications

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“…For those systems, 2D electronic spectra provide detailed information on the electronic couplings among chromophores and on the excited energy and coherence transfer. [61][62][63][64][65] We leave them for future studies. Figure 3.…”

Section: Resultsmentioning

confidence: 99%

Dynamics of a Multimode System Coupled to Multiple Heat Baths Probed by Two-Dimensional Infrared Spectroscopy

2007

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Reduced equation of motion for a multimode system coupled to multiple heat baths is constructed by extending the quantum Fokker-Planck equation with low-temperature correction terms (J. Phys. Soc. Jpn. 2005, 74, 3131). Unlike such common approaches used to describe intramolecular multimode vibration as a BlochRedfield theory and a stochastic theory, the present formalism is defined by the molecular coordinates. To explore the correlation among different modes through baths, we consider two cases of system-bath couplings. One is a correlated case in which two modes are coupled to a single bath, and the other is an uncorrelated case in which each mode is coupled to a different bath. We further classify the correlated case into two cases, the plus-and minus-correlated cases, according to distinct correlation manners. For these, one-dimensional and two-dimensional infrared (2D-IR) spectra are calculated numerically by solving the equation of motion. It is demonstrated that 2D-IR spectroscopy has the ability to analyze the correlation of fluctuation-dissipation processes among different modes.

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Section: Resultsmentioning

confidence: 99%

Dynamics of a Multimode System Coupled to Multiple Heat Baths Probed by Two-Dimensional Infrared Spectroscopy

2007

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“…[15][16] However, more recent experimental and theoretical work has questioned the assignment to pure electronic coherence. [17][18][19] One criterion for distinguishing electronic from vibrational coherences, initially proposed by Cheng and Fleming, is the separate analysis of rephasing and nonrephasing 2D signals.…”

Section: Introductionmentioning

confidence: 99%

Full Characterization of Vibrational Coherence in a Porphyrin Chromophore by Two-Dimensional Electronic Spectroscopy

et al. 2014

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In this work we present experimental and calculated two-dimensional electronic spectra for a 5,15-bisalkynyl porphyrin chromophore. The lowest energy electronic Q y transition couples mainly to a single 380 cm -1 vibrational mode. The two-dimensional electronic spectra reveal diagonal and cross peaks which oscillate as a function of population time. We analyse both the amplitude and phase distribution of this main vibronic transition as a function of excitation and detection frequencies.Even though Feynman diagrams provide a good indication of where the amplitude of the oscillating components are located in the excitation-detection plane, other factors also affect this distribution.Specifically, the oscillation corresponding to each Feynman diagram is expected to have a phase that is a function of excitation and detection frequencies. Therefore, the overall phase of the experimentally observed oscillation will reflect this phase dependence. Another consequence is that the overall oscillation amplitude can show interference patterns resulting from overlapping contributions from neighbouring Feynman diagrams. These observations are consistently reproduced through simulations based on third order perturbation theory coupled to a spectral density described by a Brownian oscillator model.

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“…Recent evidence indicates that room temperature quantum processes are supported by the structures in graphene [70] and conjugated polymers [71], structures that are not that dissimilar to aromatic rings. Additionally, quantum coherence at relatively warm temperatures has been shown to occur in the protein structures required for photosynthesis [72]. These proteins also show a similarity with the microtubule cytoskeleton; hence, we believe that if there are quantum effects present in microtubules, they must occur via a mechanism similar to the one manifested in photosynthesis.…”

Section: Resultsmentioning

confidence: 99%

A critical assessment of the information processing capabilities of neuronal microtubules using coherent excitations

Craddock

Tuszyński

2009

J Biol Phys

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Evidence for signaling, communication, and conductivity in microtubules (MTs) has been shown through both direct and indirect means, and theoretical models predict their potential use in both classical and quantum information processing in neurons. The notion of quantum information processing within neurons has been implicated in the phenomena of consciousness, although controversies have arisen in regards to adverse physiological temperature effects on these capabilities. To investigate the possibility of quantum processes in relation to information processing in MTs, a biophysical MT model is used based on the electrostatic interior of the tubulin protein. The interior is taken to constitute a double-well potential structure within which a mobile electron is considered capable of occupying at least two distinct quantum states. These excitonic states together with MT lattice vibrations determine the state space of individual tubulin dimers within the MT lattice. Tubulin dimers are taken as quantum well structures containing an electron that can exist in either its ground state or first excited state. Following previous models involving the mechanisms of exciton energy propagation, we estimate the strength of exciton and phonon interactions and their effect on the formation and dynamics of coherent exciton domains within MTs. Also, estimates of energy and timescales for excitons, phonons, their interactions, and thermal effects are presented. Our conclusions cast doubt on the possibility of sufficiently long-lived coherent exciton/phonon structures existing at physiological temperatures in the absence of thermal isolation mechanisms. These results are discussed in comparison with previous models based on quantum effects in non-polar hydrophobic regions, which have yet to be disproved.

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Evidence for wavelike energy transfer through quantum coherence in photosynthetic systems

Cited by 2,966 publications

References 26 publications

Dynamics of a Multimode System Coupled to Multiple Heat Baths Probed by Two-Dimensional Infrared Spectroscopy

Dynamics of a Multimode System Coupled to Multiple Heat Baths Probed by Two-Dimensional Infrared Spectroscopy

Full Characterization of Vibrational Coherence in a Porphyrin Chromophore by Two-Dimensional Electronic Spectroscopy

A critical assessment of the information processing capabilities of neuronal microtubules using coherent excitations

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