Primary Photophysical Processes in Photosystem II: Bridging the Gap between Crystal Structure and Optical Spectra

Renger, Thomas; Schlodder, E.

doi:10.1002/cphc.200900932

Cited by 77 publications

(122 citation statements)

References 89 publications

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“…At the moment, there is much evidence that two main pathways make significant contributions under ambient conditions and the lowest energy states depend on disorder (44)(45)(46)(47). Whereas in bacterial reaction centers the primary charge separation takes place at the special pair (as used in this work), the reaction centers of Photosystem II also use an additional pathway which starts at the accessory chlorophyll of the D1 branch (48,49). In this work we discuss only the first pathway, which is present in both types of reaction centers and plays an important role in optimizing the electron transfer efficiency.…”

mentioning

confidence: 89%

Photosynthetic reaction center as a quantum heat engine

Dorfman

Voronine

Mukamel

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

276

342

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Two seemingly unrelated effects attributed to quantum coherence have been reported recently in natural and artificial light-harvesting systems. First, an enhanced solar cell efficiency was predicted and second, population oscillations were measured in photosynthetic antennae excited by sequences of coherent ultrashort laser pulses. Because both systems operate as quantum heat engines (QHEs) that convert the solar photon energy to useful work (electric currents or chemical energy, respectively), the question arises whether coherence could also enhance the photosynthetic yield. Here, we show that both effects arise from the same population-coherence coupling term which is induced by noise, does not require coherent light, and will therefore work for incoherent excitation under natural conditions of solar excitation. Charge separation in light-harvesting complexes occurs in a pair of tightly coupled chlorophylls (the special pair) at the heart of photosynthetic reaction centers of both plants and bacteria. We show the analogy between the energy level schemes of the special pair and of the laser/photocell QHEs, and that both population oscillations and enhanced yield have a common origin and are expected to coexist for typical parameters. We predict an enhanced yield of 27% in a QHE motivated by the reaction center. This suggests nature-mimicking architectures for artificial solar energy devices.photosynthesis | quantum biology | population oscillations | quantum coherence A ccording to the laws of quantum thermodynamics, quantum heat engines (QHEs) convert hot thermal radiation into low-entropy useful work (1, 2). The ultimate efficiency of such QHEs is usually governed by a detailed balance between absorption and emission of the hot pump radiation (3). The laser is an example of a QHE, which can use incoherent pump (heat) radiation to produce highly coherent (low-entropy) light ( Fig. 1 A and B). Moreover, it was demonstrated both theoretically and experimentally that noise-induced quantum coherence (4) can break detailed balance and yield lasers without population inversion (5) and/or with enhanced efficiency (Fig. 1C).Recently it has been shown that quantum coherence can, in principle, enhance the efficiency of a solar cell or a photodetector (6-10). This photocell QHE (Fig. 1D) can be described by the same model as the laser QHE (Fig. 1E) and obeys similar detailed balance physics. To use the broad solar spectrum and eliminate phonon loss, we separate solar flux into narrow frequency intervals and direct it onto a cell array where each of the cells has been prepared to have its band gap equal to that photon energy (7). In particular, Shockley and Queisser (11) invoked detailed balance to show that the open-circuit voltage of a photocell is related to the energy input of a "hot" monochromatic thermal light by the Carnot factor. However, just as in the case of the laser, we can, in principle, break detailed balance by inducing coherence (Fig. 1F), which can enhance the photocell efficiency (9, 10).Other recent p...

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mentioning

confidence: 89%

Photosynthetic reaction center as a quantum heat engine

Dorfman

Voronine

Mukamel

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

276

342

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“…[468,[470][471][472] In purple bacteria the strong coupling within the special pair leads to an excitation mainly localized on that dimer, while the lowest excited state in PSII is delocalized over all six pigments with significant excitonic coupling within the special pair and between each pigment of the special pair and the neighboring pigment. [471][472][473][474] Other studies indicate that all excited states except those of the special pair can be described as monomeric, [475] or that delocalization occurs mainly in the active branch, whereas the excited states in branch B are mainly localized on individual pigments. [470] Also, the reported relative excitonic couplings for the reaction center in PSII are diverse.…”

Section: Purple Bacterial Reaction Centermentioning

confidence: 99%

Quantum Chemical Description of Absorption Properties and Excited‐State Processes in Photosynthetic Systems

2011

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The theoretical description of the initial steps in photosynthesis has gained increasing importance over the past few years. This is caused by more and more structural data becoming available for light-harvesting complexes and reaction centers which form the basis for atomistic calculations and by the progress made in the development of first-principles methods for excited electronic states of large molecules. In this Review, we discuss the advantages and pitfalls of theoretical methods applicable to photosynthetic pigments. Besides methodological aspects of excited-state electronic-structure methods, studies on chlorophyll-type and carotenoid-like molecules are discussed. We also address the concepts of exciton coupling and excitation-energy transfer (EET) and compare the different theoretical methods for the calculation of EET coupling constants. Applications to photosynthetic light-harvesting complexes and reaction centers based on such models are also analyzed.

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“…We will end this review with some open questions and suggestions for future research. We would also like to refer to various other reviews that have appeared in recent years discussing more/other aspects of PSII [2,3,[33][34][35][36][37][38].…”

Section: Introductionmentioning

confidence: 99%

Light-harvesting and structural organization of Photosystem II: From individual complexes to thylakoid membrane

Croce

Amerongen

2011

Journal of Photochemistry and Photobiology B: Biology

162

114

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a b s t r a c tPhotosystem II (PSII) is responsible for the water oxidation in photosynthesis and it consists of many proteins and pigment-protein complexes in a variable composition, depending on environmental conditions. Sunlight-induced charge separation lies at the basis of the photochemical reactions and it occurs in the reaction center (RC). The RC is located in the PSII core which also contains light-harvesting complexes CP43 and CP47. The PSII core of plants is surrounded by external light-harvesting complexes (lhcs) forming supercomplexes, which together with additional external lhcs, are located in the thylakoid membrane where they perform their functions.In this paper we provide an overview of the available information on the structure and organization of pigment-protein complexes in PSII and relate this to experimental and theoretical results on excitation energy transfer (EET) and charge separation (CS). This is done for different subcomplexes, supercomplexes, PSII membranes and thylakoid membranes. Differences in experimental and theoretical results are discussed and the question is addressed how results and models for individual complexes relate to the results on larger systems. It is shown that it is still very difficult to combine all available results into one comprehensive picture.

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Primary Photophysical Processes in Photosystem II: Bridging the Gap between Crystal Structure and Optical Spectra

Cited by 77 publications

References 89 publications

Photosynthetic reaction center as a quantum heat engine

Photosynthetic reaction center as a quantum heat engine

Quantum Chemical Description of Absorption Properties and Excited‐State Processes in Photosynthetic Systems

Light-harvesting and structural organization of Photosystem II: From individual complexes to thylakoid membrane

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