Difference between revisions of "Lead Sulfide Quantum Dot Synthesis"
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[[wikipedia:Quantum_dot]] | [[wikipedia:Quantum_dot]] | ||
*[http://entropyproduction.blogspot.com/2006/04/quantum-dot-photovoltaics.html Quantum dot blog] | *[http://entropyproduction.blogspot.com/2006/04/quantum-dot-photovoltaics.html Quantum dot blog] | ||
*Absence of Photoinduced Charge Transfer in Blends of PbSe Quantum Dots and Conjugated Polymers | |||
Kevin M. Noone, Nicholas C. Anderson, Noah E. Horwitz, Andrea M. Munro, Abhishek P. Kulkarni, David S. Ginger | |||
ACS Nano 2009 3 (6), 1345-1352 {{Doi|10.1021/nn800871j}} | |||
Revision as of 15:18, 9 August 2011
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Overview
Quantum dots are semiconductor nanocrystals on the scale of a few nanometers, or several hundred atoms. At this size quantum effects dominate and the electrons are quantum confined to narrow energy levels determined by the size of the particle. This means that the absorption wavelength the light can be fine-tuned and that quantum dots can be used to adjust the bandgap of the materials they are associated with. Quantum dots being explored for use in photovoltaics and in signal processing.
Significance
Quantum dots can be used increase the efficiency of solar cells by tapping different portions of the spectrum and by increasing the number of excitons that be formed per photon, resulting in higher quantum efficiency.
Procedure
External Links
- Quantum dot blog
- Absence of Photoinduced Charge Transfer in Blends of PbSe Quantum Dots and Conjugated Polymers
Kevin M. Noone, Nicholas C. Anderson, Noah E. Horwitz, Andrea M. Munro, Abhishek P. Kulkarni, David S. Ginger ACS Nano 2009 3 (6), 1345-1352 doi:10.1021/nn800871j