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August 15, 2011 - Volume 89, Number 33
- p. 31
Science & Technology Concentrates
More Science & Technology Concentrates
- Liquid Crystal Shines In Three Colors
- Mild heating and rubbing cause films to turn red, green, and yellow
- New Detector For Time-Of-Flight Mass Spec
- Nanomembrane design offers enhanced sensitivity to heavy ions
- Animal’s Amino Acids Go Unnatural
- Non-canonical amino acids incorporated into multicellular organism
- Making Nanotubes In The Microwave
- From starting materials to product, method takes less than 30 seconds
- Natural Product Syntheses Analyzed
- Mechanistic details could aid combinatorial efforts for drug discovery
- Examining Methane’s Slowing Increase
- Conflicting explanations attribute change in emission rates to human activity
- Supramolecular Polymerization
- Peptide-based molecules form tubes and helices
- Plasmons Enhance Solar-Cell Output
- Electron waves associated with core-shell particles lead to thinner better-performing devices
Topics Covered
ACS Nano
Silver-TiO2 core-shell nanoparticles (TEM shown) enhance the performance of dye-sensitized solar cells.
Incorporating core-shell nanoparticles into the anodes of dye-sensitized solar cells (DSCs) can boost the cells’ photovoltaic performance, researchers at MIT report in ACS Nano (DOI: 10.1021/nn201808g). DSC photoanodes are generally made from a film of interconnected TiO2 nanoparticles that are coated with a light-sensitive dye. The MIT group, which includes Jifa Qi, Xiangnan Dang, Paula T. Hammond, and Angela M. Belcher, prepared silver particles roughly 20 nm in diameter with a 2-nm-thick TiO2 shell and embedded the core-shell particles among the bare TiO2 particles. The team exploited interfacial electron waves known as surface plasmons, which intensify the electromagnetic field near the core-shell particles and enhance the dye molecules’ light absorption. The oxide shells help capitalize on those benefits by impeding the processes that quench the light-induced electronic excitations and thereby reduce the cell’s electrical output. Compared with 7.8%-efficient conventional DSCs, DSCs with just 0.1% by weight core-shell particles are 9% efficient and can be made with 25% thinner anodes. Similarly, conventional cell efficiencies can be obtained from core-shell cells fabricated from 62% less material, the team reports.
- Chemical & Engineering News
- ISSN 0009-2347
- Copyright © 2011 American Chemical Society
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