@article {Luque2003, title = {Handbook of Photovoltaic Science and Engineering}, year = {2003}, note = {

1. Status, Trends, Challenges and the Bright Future of Solar Electricity from Photovoltaics.\ 

2. Motivation for Photovoltaic Application and Development

3. The Physics of the Solar Cell

4. Theoretical Limits of Photovoltaic\ Conversion

5. Solar Grade Silicon Feedstock\ 

6. Bulk Crystal Growth and Wafering\ for PV

7. Crystalline Silicon Solar Cells and Modules\ 

8. Thin-film Silicon Solar Cells\ 

9. High-efficiency III-V Multijunction\ Solar Cells

10. Space Solar Cells and Arrays

11. Photovoltaic Concentrators\ 

12. Amorphous Silicon-based Solar Cells\ 

13. Cu(InGa)Se2 Solar Cells

14. Cadmium Telluride Solar Cells

15. Dye-sensitized Solar Cells

16. Measurement and Characterization of Solar Cells and Modules

17. Photovoltaic Systems

18. Electrochemical Storage for Photovoltaics

19. Power Conditioning for Photovoltaic Power Systems

20. Energy Collected and Delivered by PV Modules

21. Economic Analysis and Environmental Aspects of Photovoltaic\ Systems

22. PV in Architecture

23. Photovoltaics\ and Development

24. Financing PV Growth\ 

Index

}, pages = {1117}, publisher = {John Wiley \& Sons Ltd.}, address = {Chichester, England}, isbn = {0-471-49196-9}, url = {http://www.amazon.com/Handbook-Photovoltaic-Science-Engineering-Antonio/dp/0471491969/ref=pd_sim_b_7}, author = {Luque, A. and Hegedus, S.} } @article {Campbell2001, title = {High performance light trapping textures for monocrystalline silicon solar cells}, journal = {Solar Energy Materials and Solar Cells}, volume = {65}, year = {2001}, month = {Jan-01-2001}, pages = {369 - 375}, abstract = {Two novel texture schemes for the front of a c-Si silicon wafer solar cell are presented. The {\textquotedblleft}bipyramid{\textquotedblright} texture is of two inverted pyramids of similar sizes laid out in alternating order. The {\textquotedblleft}patch{\textquotedblright} texture uses a checkerboard layout of blocks of parallel grooves, with the grooves of alternating blocks perpendicularly oriented to each other. We estimate that these textures, which almost fully trap light for the first six passes through the substrate, can deliver better optical performance than the standard inverted pyramid texture, especially in narrow-band applications.}, issn = {09270248}, doi = {10.1016/S0927-0248(00)00115-X}, author = {Campbell, Patrick and Martin A Green} } @proceedings {Wolf1976, title = {Historical Development of Solar Cells}, year = {1976}, note = {
}, publisher = {IEEE Press}, author = {M. Wolf} } @article {531, title = {High Electron Mobility in Zinc Selenide Through Low-Temperature Annealing}, journal = {Journal of Applied Physics}, volume = {42}, year = {1971}, month = {Jan-01-1971}, pages = {1204}, abstract = {Electron mobility in ZnSe has been measured between 40{\textdegree} and 400{\textdegree}K. It is shown that through repeated annealing in liquid Zn the mobility maximum can be increased to 12 000 cm2/V sec. This is one of the highest mobilities measured for semiconductors with band gaps as wide as that of ZnSe (2.7 eV). The increase in mobility is mainly due to elimination of doubly charged acceptor states. The residual scattering is believed to be due, in part, to charged isolated impurities and, in part, to paired impurity dipoles.}, issn = {00218979}, doi = {10.1063/1.1660167}, author = {Aven, M.} } @conference {Dale1960, title = {High efficiency silicon solar cells}, booktitle = {Proceedings of the 14th Annual Power Sources Conference}, year = {1960}, note = {
}, month = {1960}, pages = {22}, publisher = {U.S. Army Signal Research and Development Lab}, organization = {U.S. Army Signal Research and Development Lab}, author = {B. Dale and H.G. Rudenberg} }