Solar cell

The first generation photovoltaic consists of a large-area, single layer p-n junction diode, which is capable of generating usable electrical energy from light sources with the wavelengths of sunlight. These cells are typically made using a silicon wafer. First generation photovoltaic cells (also known as silicon wafer-based solar cells) are the dominant technology in the commercial production of solar cells, accounting for more than 86% of the solar cell market.

The second generation of photovoltaic materials is based on the use of thin-film deposits of semiconductors. These devices were initially designed to be high-efficiency, multiple junction photovoltaic cells. Later, the advantage of using a thin-film of material was noted, reducing the mass of material required for cell design. This contributed to a prediction of greatly reduced costs for thin film solar cells. Currently (2007) there are different technologies/semiconductor materials under investigation or in mass production, such as amorphous silicon, poly-crystalline silicon, micro-crystalline silicon, cadmium telluride, copper indium selenide/sulfide. Typically, the efficiencies of thin-film solar cells are lower compared with silicon (wafer-based) solar cells, but manufacturing costs are also lower, so that a lower price in terms of $/watt of electrical output can be achieved. Another advantage of the reduced mass is that less support is needed when placing panels on rooftops and it allows fitting panels on light materials or flexible materials, even textiles. This allows for portable roll-up solar panels, which can fit in a backpack and be used to power cell phones or laptops in remote areas.

Third generation photovoltaics are very different from the other two, broadly defined as semiconductor devices which do not rely on a traditional p-n junction to separate photogenerated charge carriers. These new devices include photoelectrochemical cells, Polymer solar cells, and nanocrystal solar cells.

Companies working on third generation photovoltaics include Xsunx, Konarka Technologies, Inc., Nanosolar and Nanosys. Research is also being done in this area by the USA's National Renewable Energy Laboratory (http://www.nrel.gov/).

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  A conventional crystalline silicon solar cell (as of 2005). Electrical contacts made from busbars (the larger silver-colored strips) and fingers (the smaller ones) are printed on the silicon wafer.

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  Symbol of a Photovoltaic cell.

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  The Sunraycer vehicle developed by GM (General Motors)

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  From a solar cell to a PV system. Diagram of the possible components of a photovoltaic system

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  NASA used solar cells on its spacecraft from the very beginning. For Example, Explorer 6, launched in 1959, had four arrays that folded out once in orbit. They provided power for months in space.

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  Schematic of charge collection by solar cells. Light transmits through transparent conducting electrode creating electron hole pairs, which are collected by both the electrodes.

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  Working mechanism of a solar cell

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  The Shockley-Queisser limit for the theoretical maximum efficiency of a solar cell. Semiconductors with band gap between 1 and 1.5eV (827 nm to 1240 nm; near-infrared) have the greatest potential to form an efficient single-junction cell. (The efficiency "limit" shown here can be exceeded by multijunction solar cells.)

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  Reported timeline of research solar cell energy conversion efficiencies (National Renewable Energy Laboratory)

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  Global photovoltaics market share by technology 1980-2021.^:24,25

• McDonald SA, Konstantatos G, Zhang S, Cyr PW, Klem EJ, Levina L, Sargent EH (2005). "Solution-processed PbS quantum dot infrared photodetectors and photovoltaics". Nature Materials. 4 (2): 138–42. Bibcode:2005NatMa...4..138M. doi:10.1038/nmat1299. PMID 15640806. S2CID 11957853.{{cite journal}}: CS1 maint: multiple names: authors list (link)
• PVNET European Roadman for PV R&D Ed Arnulf Jager-Waldan Office for Publications of the European Union 2004

• Directory of Solar Cell Manufacturers Archived 2007-04-20 at the Wayback Machine
• Directory of Solar Cell Manufacturing Equipment Suppliers Archived 2007-04-20 at the Wayback Machine
• School of Photovoltaic and Renewable Energy Engineering (Research lab of Prof. Martin Green et al.)
• Energex: Animation of how a solar cell works Archived 2007-03-22 at the Wayback Machine
• Carbon Nanotube Solar Cells Archived 2007-03-10 at the Wayback Machine (28 February 2005)
• Flexible Silicon Solar Cells (15 February 2003)
• Historical: Photovoltaic Solar Energy Conversion: An Update (M. Green, 1998)
• Howstuffworks.com: How Solar Cells Work
• Organic Photovoltaics and Materials — Overview Archived 2007-03-30 at the Wayback Machine
• Organic Solar Cells for the Near-Infrared Spectrum Archived 2007-02-21 at the Wayback Machine
• Photovoltaic Residential Benefits Archived 2007-05-19 at the Wayback Machine
• Photovoltaic Solar Panel Overview Archived 2007-04-15 at the Wayback Machine
• Photovoltaic Thin Films for the Full Solar Spectrum Archived 2008-07-02 at the Wayback Machine (W. Walukiewicz 2002)
• Pliable solar cells are on a roll Archived 2008-04-20 at the Wayback Machine
• Điện mặt trời Địa Cầu Xanh Archived 2020-12-04 at the Wayback Machine
• Superefficient, Cost-Effective Solar Cell Breaks Conversion Records - 40.7 percent efficiency achieved (Scientific American, December 2006)

PEC (Photo Electro Chromic)

• How to Build Your Own Solar Cell Archived 2007-04-02 at the Wayback Machine
• DIY (Do It Yourself): Nanocrystalline Dye-Sensitized Solar Cell Kit Quote: "... sunlight-to-electrical energy conversion efficiency is between 1 and 0.5%..."

Cuprous oxide solar cells

• Make a Solar Cell in Your Kitchen, A Flat Panel Solar Battery

• alt.solar.photovoltaic