2014
DOI: 10.1002/chem.201402585
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Engineered Electron‐Transfer Chain in Photosystem 1 Based Photocathodes Outperforms Electron‐Transfer Rates in Natural Photosynthesis

Abstract: Photosystem 1 (PS1) triggers the most energetic light-induced charge-separation step in nature and the in vivo electron-transfer rates approach 50 e(-)  s(-1)  PS1(-1). Photoelectrochemical devices based on this building block have to date underperformed with respect to their semiconductor counterparts or to natural photosynthesis in terms of electron-transfer rates. We present a rational design of a redox hydrogel film to contact PS1 to an electrode for photocurrent generation. We exploit the pH-dependent pro… Show more

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Cited by 121 publications
(160 citation statements)
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“…In comparison, the addition of the freely diffusing mediator does not change the photocurrent for hydrogel films, such as PS1-G43, that display non-limiting ET rates. 15 This clearly demonstrates that the low photocurrent obtained for the DOs modified polymers is not due to inefficient PS1 entrapment in the film, but to the limiting ET processes. The latter limitation may be due to the increased hydrophobicity of the DOs electron relay which reduces their solvation in aqueous media and thus their mobility, leading to an inefficient ET inside the hydrogel network.…”
Section: Cl]mentioning
confidence: 78%
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“…In comparison, the addition of the freely diffusing mediator does not change the photocurrent for hydrogel films, such as PS1-G43, that display non-limiting ET rates. 15 This clearly demonstrates that the low photocurrent obtained for the DOs modified polymers is not due to inefficient PS1 entrapment in the film, but to the limiting ET processes. The latter limitation may be due to the increased hydrophobicity of the DOs electron relay which reduces their solvation in aqueous media and thus their mobility, leading to an inefficient ET inside the hydrogel network.…”
Section: Cl]mentioning
confidence: 78%
“…Hence, the recombination of the methyl viologen radical cation with the oxidized Os-complex or the electrode is impeded. 15,24 This strategy ensures that the resulting photocurrents are primarily limited by the electron transfer chain from the electrode to PS1, which is the subject of the current study. To verify that the photocurrents are generated from PS1 rather than from the polymer matrix, control experiments with electrodes lacking PS1 were conducted.…”
Section: Resultsmentioning
confidence: 99%
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“…The similarities of the two systems are readily apparent with a light-harvesting unit (chlorophyll or quantum dot) becoming excited by light to generate an electron-hole pair which is separated and each carrier is transferred through different media (either across a thylakoid membrane or within nanoparticle network) along the energetic gradient of the chargecarriers. However, the electron-transfer rate in photosystem I is 47 e -/s [12] which is minimal compared to the electron-transfer rate between quantum dots and TiO 2 , which is reported to be between 10 7 and 10 10 e -/s depending on the binding environment of the quantum dots [13][14][15][16].…”
Section: Introductionmentioning
confidence: 99%