7,257 research outputs found
Solar energy conversion
If solar energy is to become a practical alternative to fossil fuels, we must have efficient ways to convert photons into electricity, fuel, and heat. The need for better conversion technologies is a driving force behind many recent developments in biology, materials, and especially nanoscience
7.2% efficient polycrystalline silicon photoelectrode
After etching, n-type cast polycrystalline silicon photoanodes immersed in a solution of methanol and a substituted ferrocene reagent exhibit photoelectrode efficiencies of 7.2%±0.7% under simulated AM2 illumination. Scanning laser spot data indicate that the grain boundaries are active; however, the semiconductor/liquid contact does not display the severe shunting effects which are observed at a polycrystalline Si/Pt Schottky barrier. Evidence for an interfacial oxide on the operating polycrystalline Si photoanode is presented. Some losses in short circuit current can be ascribed to bulk semiconductor properties; however, despite these losses, photoanodes fabricated from polycrystalline substrates exhibit efficiencies comparable to those of single crystal material. Two major conclusions of our studies are that improved photoelectrode behavior in the polycrystalline silicon/methanol system will primarily result from changes in bulk electrode properties and from grain boundary passivation, and that Fermi level pinning by surface states does not prevent the design of efficient silicon-based liquid junctions
A 14% efficient nonaqueous semiconductor/liquid junction solar cell
We describe the most efficient semiconductor/liquid junction solar cell reported to date. Under Wâhalogen (ELH) illumination, the device is a 14% efficient twoâelectrode solar cell fabricated from an nâtype silicon photoanode in contact with a nonaqueous electrolyte solution. The cellâČs central feature is an ultrathin electrolyte layer which simultaneously reduces losses which result from electrode polarization, electrolyte light absorption, and electrolyte resistance. The thin electrolyte layer also eliminates the need for forced convection of the redox couple and allows for precise control over the amount of water (and other electrolyte impurities) exposed to the semiconductor. After one month of continuous operation under ELH light at 100 mW/cm^2, which corresponds to the passage of over 70â000 C/cm^2, thinâlayer cells retained over 90% of their efficiency. In addition, when made with Wacker Silso cast polycrystalline Si, cells yield an efficiency of 9.8% under simulated AMl illumination. The thinâlayer cells employ no external compensation yet surpass their corresponding experimental (threeâelectrode) predecessors in efficiency
On The Way To Home Sweet Home
https://digitalcommons.library.umaine.edu/mmb-vp/2327/thumbnail.jp
That mellow melody
https://digitalcommons.library.umaine.edu/mmb-vp/3736/thumbnail.jp
When I First Met You
https://digitalcommons.library.umaine.edu/mmb-vp/3746/thumbnail.jp
Isch Gabibble : I should worry
https://digitalcommons.library.umaine.edu/mmb-vp/4351/thumbnail.jp
When You\u27re A Long, Long Way From Home
https://digitalcommons.library.umaine.edu/mmb-vp/2709/thumbnail.jp
My mother\u27s rosary
https://digitalcommons.library.umaine.edu/mmb-vp/2215/thumbnail.jp
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