Your search keyword '"Protein photoelectrochemical cells"' showing total 2 results

1. Self-powered all weather sensory systems powered by Rhodobacter sphaeroides protein solar cells

Author

Swee Ching Tan, Jayraj V. Vaghasiya, Lin Yang, Yaoxin Zhang, Nikita Paul, Lakshmi Suresh, Michael R. Jones, and Dilip Krishna Nandakumar

Subjects

Materials science, Biomedical Engineering, Biophysics, BrisSynBio, Biosensing Techniques, Rhodobacter sphaeroides, 02 engineering and technology, Electrolyte, low temperature, 01 natural sciences, Solar Energy, Electrochemistry, self-recovery, Photosynthesis, Photosystem, Photocurrent, amphiphilic triblock copolymer, biology, business.industry, Bristol BioDesign Institute, 010401 analytical chemistry, General Medicine, Photoelectrochemical cell, 021001 nanoscience & nanotechnology, biology.organism_classification, Solar energy, 0104 chemical sciences, Freezing point, Chemical engineering, Protein photoelectrochemical cells, Sunlight, quasi-solid electrolyte, Quantum efficiency, 0210 nano-technology, business, Biotechnology

Abstract

Natural photosynthetic proteins can convert solar energy into electrical energy with close to 100% quantum efficiency, and there is increasing interest in their use for sustainable photoelectrochemical devices. The primary processes of photosynthesis remain operational and efficient down to extremely low temperatures, and natural photosystems exhibit a variety of self-healing mechanisms. Herein we demonstrate the use of an amphiphilic triblock copolymer, Pluronic F127, to fabricate a self-healing photosynthetic protein photoelectrochemical cell that operates optimally at sub-zero temperatures. A concentration of 30% (w/w) Pluronic F127 depressed the freezing point of an electrolyte comprising 50 mM ubiquinone-0 in aqueous buffer such that optimal device solar energy conversion was seen at -12 °C rather than at room temperature. Fabrication of the protein photoelectrochemical cells with flexible electrodes enabled the demonstration of self-healing of damage caused by repeated mechanical deformation. Multiple bending cycles caused a marked deterioration of the photocurrent response to around a third of initial levels due to damage to the gel phase of the electrolyte, but this could be restored to ~95% by simply cooling and rewarming the device. This self-recoverability of the electrolyte extended the operational life of the protein cell through a process that increased its photoelectrochemical output during the repair. Utility of the cells as components of a touch sensor operational across a wide temperature range, including freezing conditions, is demonstrated.

Published

2020

2. Self-powered all weather sensory systems powered by Rhodobacter sphaeroides protein solar cells.

Author

Paul, Nikita, Suresh, Lakshmi, Vaghasiya, Jayraj V., Yang, Lin, Zhang, Yaoxin, Nandakumar, Dilip Krishna, Jones, Michael R., and Tan, Swee Ching

Subjects

*RHODOBACTER sphaeroides, *SOLAR cells, *SENSE organs, *DYE-sensitized solar cells, *DEFORMATIONS (Mechanics), *SOLAR energy conversion

Abstract

Natural photosynthetic proteins can convert solar energy into electrical energy with close to 100% quantum efficiency, and there is increasing interest in their use for sustainable photoelectrochemical devices. The primary processes of photosynthesis remain operational and efficient down to extremely low temperatures, and natural photosystems exhibit a variety of self-healing mechanisms. Herein we demonstrate the use of an amphiphilic triblock copolymer, Pluronic F127, to fabricate a self-healing photosynthetic protein photoelectrochemical cell that operates optimally at sub-zero temperatures. A concentration of 30% (w/w) Pluronic F127 depressed the freezing point of an electrolyte comprising 50 mM ubiquinone-0 in aqueous buffer such that optimal device solar energy conversion was seen at −12 °C rather than at room temperature. Fabrication of the protein photoelectrochemical cells with flexible electrodes enabled the demonstration of self-healing of damage caused by repeated mechanical deformation. Multiple bending cycles caused a marked deterioration of the photocurrent response to around a third of initial levels due to damage to the gel phase of the electrolyte, but this could be restored to ~95% by simply cooling and rewarming the device. This self-recoverability of the electrolyte extended the operational life of the protein cell through a process that increased its photoelectrochemical output during the repair. Utility of the cells as components of a touch sensor operational across a wide temperature range, including freezing conditions, is demonstrated. • Integration of quasi-solid electrolyte matrix with RC-LH1 and flexible electrodes enables protein cells to operate at sub-zero temperatures. • Self-recoverability of the electrolyte helps in extending the operational life of the protein cell upto 95% of the initial performance. • Recoverability of the electrolyte after 1300 bending cycles can improve the reliability and robustness at sub-zero temperatures. • Utility of these self-healing cells operational from 40°C to -20°C is demonstrated through the fabrication of a self-powered tactile sensor. [ABSTRACT FROM AUTHOR]

Published

2020