Volker Hartmann scite author profile

The improvement of Z-scheme inspired biophotovoltaics is achieved by fine tuning the properties of redox hydrogels applied as immobilization and electron conducting matrices for the photosystem-protein complexes. The formal potentials of the redox hydrogels are adjusted to the respective redox sites in the photosystems for optimized electron transfer without substantial voltage loss. The anode is based on photosystem 2 (PS2) integrated in a phenothiazine modified redox hydrogel with a formal potential of -1 mV vs. SHE, which is 59 mV more positive than the QB acceptor site in PS2. The cathode is based on photosystem 1 (PS1) contacted via an Os-complex based redox hydrogel with a formal potential of 395 mV vs. SHE, i.e. 28 mV more negative than the primary P700 electron acceptor of PS1. The potential difference between the two redox hydrogels is 396 mV. An open circuit voltage (VOC) of 372.5 ± 2.1 mV could be achieved for the biophotovoltaic cell. The maximum power output is 1.91 ± 0.56 μW cm(-2) and the conversion efficiency (η) is 4.5 × 10(-5), representing a 125-fold improvement in comparison to the previously proposed device exploiting the photosynthetic Z-scheme for electrical energy production.

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Light Induced H₂ Evolution from a Biophotocathode Based on Photosystem 1 – Pt Nanoparticles Complexes Integrated in Solvated Redox Polymers Films

Zhao

Conzuelo

Hartmann

et al. 2015

J. Phys. Chem. B

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We report on a biophotocathode based on photosystem 1 (PS1)-Pt nanoparticle complexes integrated in a redox hydrogel for photoelectrocatalytic H2 evolution at low overpotential. A poly(vinyl)imidazole Os(bispyridine)2Cl polymer serves as conducting matrix to shuttle the electrons from the electrode to the PS1-Pt complexes embedded within the hydrogel. Light induced charge separation at the PS1-Pt complexes results in the generation of photocurrents (4.8 ± 0.4 μA cm(-2)) when the biophotocathodes are exposed to anaerobic buffer solutions. Under these conditions, the protons are the sole possible electron acceptors, suggesting that the photocurrent generation is associated with H2 evolution. Direct evidence for the latter process is provided by monitoring the H2 production with a Pt microelectrode in scanning electrochemical microscopy configuration over the redox hydrogel film containing the PS1-Pt complexes under illumination.

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Volker Hartmann

Rational wiring of photosystem II to hierarchical indium tin oxide electrodes using redox polymers

A photosystem I monolayer with anisotropic electron flow enables Z-scheme like photosynthetic water splitting

Redox hydrogels with adjusted redox potential for improved efficiency in Z-scheme inspired biophotovoltaic cells

Light Induced H₂ Evolution from a Biophotocathode Based on Photosystem 1 – Pt Nanoparticles Complexes Integrated in Solvated Redox Polymers Films

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Volker Hartmann

Rational wiring of photosystem II to hierarchical indium tin oxide electrodes using redox polymers

A photosystem I monolayer with anisotropic electron flow enables Z-scheme like photosynthetic water splitting

Redox hydrogels with adjusted redox potential for improved efficiency in Z-scheme inspired biophotovoltaic cells

Light Induced H2 Evolution from a Biophotocathode Based on Photosystem 1 – Pt Nanoparticles Complexes Integrated in Solvated Redox Polymers Films

Contact Info

Product

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Light Induced H₂ Evolution from a Biophotocathode Based on Photosystem 1 – Pt Nanoparticles Complexes Integrated in Solvated Redox Polymers Films