Your search keyword '"Jennings GK"' showing total 3 results

1. Photoactive films of photosystem I on transparent reduced graphene oxide electrodes.

Author

Darby E, LeBlanc G, Gizzie EA, Winter KM, Jennings GK, and Cliffel DE

Subjects

Electrodes, Electron Transport, Ferricyanides chemistry, Ferrocyanides chemistry, Oxidation-Reduction, Oxides, Ruthenium Compounds chemistry, Solar Energy, 2,6-Dichloroindophenol chemistry, Graphite chemistry, Photosystem I Protein Complex chemistry

Abstract

Photosystem I (PSI) is a photoactive electron-transport protein found in plants that participates in the process of photosynthesis. Because of PSI's abundance in nature and its efficiency with charge transfer and separation, there is a great interest in applying the protein in photoactive electrodes. Here, we developed a completely organic, transparent, conductive electrode using reduced graphene oxide (RGO) on which a multilayer of PSI could be deposited. The resulting photoactive electrode demonstrated current densities comparable to that of a gold electrode modified with a multilayer film of PSI and significantly higher than that of a graphene electrode modified with a monolayer film of PSI. The relatively large photocurrents produced by integrating PSI with RGO and using an opaque, organic mediator can be applied to the facile production of more economic solar energy conversion devices.

Published

2014

2. Photosystem I on graphene as a highly transparent, photoactive electrode.

Author

Gunther D, LeBlanc G, Prasai D, Zhang JR, Cliffel DE, Bolotin KI, and Jennings GK

Subjects

Adsorption, Electrodes, Photochemical Processes, Photosystem I Protein Complex isolation & purification, Photosystem I Protein Complex metabolism, Spinacia oleracea enzymology, Surface Properties, Graphite chemistry, Photosystem I Protein Complex chemistry

Abstract

We report the fabrication of a hybrid light-harvesting electrode consisting of photosystem I (PSI) proteins extracted from spinach and adsorbed as a monolayer onto electrically contacted, large-area graphene. The transparency of graphene supports the choice of an opaque mediator at elevated concentrations. For example, we report a photocurrent of 550 nA/cm(2) from a monolayer of PSI on graphene in the presence of 20 mM methylene blue, which yields an opaque blue solution. The PSI-modified graphene electrode has a total thickness of less than 10 nm and demonstrates photoactivity that is an order of magnitude larger than that for unmodified graphene, establishing the feasibility of conjoining these nanomaterials as potential constructs in next-generation photovoltaic devices.

Published

2013

3. Graphene: corrosion-inhibiting coating.

Author

Prasai D, Tuberquia JC, Harl RR, Jennings GK, Rogers BR, and Bolotin KI

Subjects

Copper chemistry, Corrosion, Dielectric Spectroscopy, Mechanical Phenomena, Surface Properties, Volatilization, Electrochemical Techniques methods, Graphite chemistry

Abstract

We report the use of atomically thin layers of graphene as a protective coating that inhibits corrosion of underlying metals. Here, we employ electrochemical methods to study the corrosion inhibition of copper and nickel by either growing graphene on these metals, or by mechanically transferring multilayer graphene onto them. Cyclic voltammetry measurements reveal that the graphene coating effectively suppresses metal oxidation and oxygen reduction. Electrochemical impedance spectroscopy measurements suggest that while graphene itself is not damaged, the metal under it is corroded at cracks in the graphene film. Finally, we use Tafel analysis to quantify the corrosion rates of samples with and without graphene coatings. These results indicate that copper films coated with graphene grown via chemical vapor deposition are corroded 7 times slower in an aerated Na(2)SO(4) solution as compared to the corrosion rate of bare copper. Tafel analysis reveals that nickel with a multilayer graphene film grown on it corrodes 20 times slower while nickel surfaces coated with four layers of mechanically transferred graphene corrode 4 times slower than bare nickel. These findings establish graphene as the thinnest known corrosion-protecting coating.

Published

2012