Long-lived quantum coherence in photosynthetic complexes at physiological temperature

Panitchayangkoon, Gitt; Hayes, Dugan; Fransted, Kelly A.; Caram, Justin R.; Harel, Elad; Wen, Jianzhong; Blankenship, Robert E.; Engel, Gregory S.

doi:10.1073/pnas.1005484107

Cited by 988 publications

(1,197 citation statements)

References 30 publications

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“…The signatures of vibronic coupling in multidimensional spectroscopy have drawn great interest lately, in particular to interpret oscillatory transients observed for light-harvesting complexes [3,[8][9][10] that persist much longer than predicted electronic dephasing times [11].…”

Section: Resultsmentioning

confidence: 99%

“…For FMO, the oscillations were found to persist for hundreds of femtoseconds at ambient temperatures and even up to a few picoseconds at 77 K [10]. 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.…”

Section: Introductionmentioning

confidence: 83%

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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: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 83%

Laser-Limited Signatures of Quantum Coherence

et al. 2015

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“…Quantum coherence in electron transfer in photosynthesis lasts for a long time (600 fs) in the pigment-protein complex (Engel, 2007;Ishizaki, 2010). But it is not yet fully known how this coherence is brought about in living tissue, although it has been shown that environmental noise increases energy delivery efficiency (Panitchayangkoona, 2010;Collini, 2010). The inferred algorithm of the present study shows that this coherence may be embedded in both higher and lower frequency bands.…”

Section: Photosynthesismentioning

confidence: 99%

Quantum Wave Information of Life Revealed: An Algorithm for Electromagnetic Frequencies that Create Stability of Biological Order, With Implications for Brain Function and Consciousness

Geesink¹,

Meijer

2016

Neuroquantology

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We propose a hypothesis of a mathematical algorithm for coherent quantum frequencies, that may create stability of biological order. The concept is based on an extensive literature survey, comprising 175 articles from 1950 to 2015, dealing with effects of electromagnetic radiation on in vitro and in vivo life systems, indicating that typical discrete coherent frequencies of electromagnetic waves are able to stabilize cells, whereas others cause a clear destabilization. We find support for the hypothesis of H. Fröhlich, that a driven set of oscillators condenses in a broad energy range, may activate a vibrational mode in life organisms at room temperature. Taking into account the life sustaining frequencies, as extracted from literature, an algorithm of coherent frequencies of standing waves for the stability of biological order was inferred. Interestingly, we found that the origin of the particular biological algorithm can be mathematically approached by a selected "tempered Pythagorean" reference acoustic scale. The algorithm expresses one-dimensional wave equations known for vibrating strings. The origin of the biological algorithm was condensed in a mathematical expression, in which all frequencies have ratios of 1:2 and closely approach ratios of 2:3. This inferred algorithm was subsequently verified with regard to various frequencies of electromagnetic waves, as applied in the above-mentioned independent biological studies. It was also matched with a range of 23 different measured quantum resonances emitted by a selected inorganic silicate mineral, that is able to catalyze the oligomerization of RNA. The selected silicate was experimentally shown to act as a quantum replicator, specifically emitting EM radiation at frequencies that are fully in line with this algorithm. Such silicate quantum replicators, therefore may have been instrumental in the initiation of first replicating, life, cells at the edge of pre-biotic evolution. Our model may imply that, at the quantum scale, an underlying electromagnetically defined order may have been present, that was a prerequisite for the coding of synthesis and functional arrangement of cellular elements in biological evolution. Far infrared dynamics, reminiscent of coherent nonrelativistic super fluids in 3+1-dimensions, may have played a role. Finally, we address the question whether the identified electromagnetic fields may also influence neural systems in general and human (self) consciousness in particular. We are finding support for recent electromagnetic and stochastic zero-point energy field theories in quantum consciousness studies. The striking similarity of electromagnetic wave frequencies, detected by us in the biological studies, and in selected clay minerals, as well as in color spectra, tone scales and sound induced geometric Chladni patterns, may indicate that we identified the involvement of a universal electromagnetic principle, that underlies the observed life sustaining effects and also may have been instrumental in the creation of biologica...

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“…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%

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.

120

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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Long-lived quantum coherence in photosynthetic complexes at physiological temperature

Cited by 988 publications

References 30 publications

Laser-Limited Signatures of Quantum Coherence

Laser-Limited Signatures of Quantum Coherence

Quantum Wave Information of Life Revealed: An Algorithm for Electromagnetic Frequencies that Create Stability of Biological Order, With Implications for Brain Function and Consciousness

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

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