Get our free book (in Spanish or English) on rainwater now - To Catch the Rain.


Jump to navigation Jump to search
This is where you can describe what already exists, what is needed, etc. You may want to include inline references. <ref> You can use the ref code to include inline references. See [[Help:Footnotes]] for more.</ref>
To make bullets use == Advantages of Quantum Dots Over Current Solar cells * Don’t rely on a single p-n junction configuration* Tandem cells-stacks of p-n junctions structures* Theoretical energy conversion efficiency of up to 66% (E.446)* Optical and electronic properties can be tweaked by changing the asterisk:size of Quantum Dots (E.446)* Able “to inject electrons to a wider band gap material, such as TiO2”(Etgar 452)* Higher light to energy efficiency* Like thisEasy to manufacture* and like thisLow cost*Capable of layer-by-layer deposition (Webber p.7835)* Theoretical Energy Conversion Efficiency of 66% (Etgar) ==How CdSe Quantum Dots Work  Semi-conductive nano-particles also known as Quantum Dots (QDs) absorbs light in solar cells. The characteristics of QDs that are needed for transferring the absorbed light’s energy is its “conduction and valence bands of the QDs permit electron injection and hole transportation” through to the metal oxide and metal layers, which the QDs is between (Etgar 448). The amount of light absorbed by the Quantum dots depends on its thickness if it “is too thick, the collection of photogenerated charge carriers is incomplete, while too-thin QD layers show poor light harvesting” (E. 448). The QDs size also plays a factor in its performance when “open circuit voltage, fill factor and photocurrent decrease with increasing the QD size; however, inner-particle electron transfer is facilitated in films made of the larger QDs” (E.448). Electrons and holes move faster “by one or two orders of magnitude with an increase in QD diameter” (E.448). These solar cells don’t rely on single p-n junction design, but uses tandem cells or multi-junction solar cells with a “stack of p-n junctions of low-dimensional semiconductor structures” (E. 446). The p-n junction stacks can have different Eg, thus covering a very wide range of the solar spectrum, thus increasing the theoretical energy conversion efficiency from 31% to 66%. ==References Etgar, L. “Semiconductor Nanocrystals as Light Harvesters in Solar Cells”, Materials, p. 445-455, 2013.Luber, Erik., Mobarok, M., and Buriak, J. “Solution-Processed Zinc Phosphide (α- Zn3P2) Colliodal Semiconducting Nanocrystals for Thin Film Photovoltaic Applications ”, National Institute for the next indentNanotechnology, p.A-K. 2013.* Webber, D. and Brutchey, R. “Nanocrystal ligand exchange with 1,2,3,4-thiatriazole-5-thiolate and back its facile in situ conversion to onethiocyanate” The Royal Society of Chemistry, p.7835-7838., 2012.Yang, Y. N.d. 0. n.p. “Best Research-Cell Efficiencies”, National Center for Photovoltaics, October 11, 2013.
== Project goals ==


Navigation menu