In the 19th century, it was observed that the sunlight striking certain materials generates detectable electric current – the photoelectric effect. This discovery laid the foundation for solar cells. Solar cells have gone on to be used in many applications. They have historically been used in situations where electrical power from the grid was unavailable.
As the invention was brought out it made solar cells as a prominent utilization for power generation for satellites. Satellites orbit the Earth, thus making solar cells a prominent source for power generation through the sunlight falling on them. Solar cells are commonly used in satellites in today's times.
1874 - James Clerk Maxwell writes to fellow mathematician Peter Tait of his observation that light affects the conductivity of selenium.[4]
1877 - William Grylls Adams and Richard Evans Day observed the photovoltaic effect in solidified selenium, and published a paper on the selenium cell. 'The action of light on selenium,' in "Proceedings of the Royal Society, A25, 113.
1883 - Charles Fritts develops a solar cell using selenium on a thin layer of gold to form a device giving less than 1% efficiency.[5]
1954 - On April 25, 1954, Bell Labs announces the invention of the first practical silicon solar cell.[8][9] Shortly afterwards, they are shown at the National Academy of Sciences Meeting. These cells have about 6% efficiency. The New York Times forecasts that solar cells will eventually lead to a source of "limitless energy of the sun".
1955 - Western Electric licences commercial solar cell technologies. Hoffman Electronics-Semiconductor Division creates a 2% efficient commercial solar cell for $25/cell or $1,785/watt.
1957 - AT&T assignors (Gerald L. Pearson, Daryl M. Chapin, and Calvin S. Fuller) receive patent US2780765, "Solar Energy Converting Apparatus." They refer to it as the "solar battery". Hoffman Electronics creates an 8% efficient solar cell.
1958 - T. Mandelkorn, U.S. Signal Corps Laboratories, creates n-on-p silicon solar cells, which are more resistant to radiation damage and are better suited for space. Hoffman Electronics creates 9% efficient solar cells. Vanguard I, the first solar-powered satellite, was launched with a 0.1 W, 100 cm2 solar panel.
1959 - Hoffman Electronics creates a 10% efficient commercial solar cell, and introduces the use of a grid contact, reducing the cell's resistance.
1960–1979
1960 - Hoffman Electronics creates a 14% efficient solar cell.
1961 - "Solar Energy in the Developing World" conference is held by the United Nations.
1962 - The Telstar communications satellite is powered by solar cells.
1963 - Sharp Corporation produces a viable photovoltaic module of silicon solar cells.
1964 - The satellite Nimbus I is equipped with Sun-tracking solar panels.
1974 - J. Baldwin, at Integrated Living Systems, co-develops the world's first building (in New Mexico) heated and otherwise powered by solar and wind power exclusively.
1976 - David E. Carlson and Christopher Wronski of RCA Laboratories create first amorphous silicon PV cells, which have an efficiency of 2.4%.
Late 1970s: the "Energy Crisis"; groundswell of public interest in solar energy use: photovoltaic and active and passive solar, including in architecture and off-grid buildings and home sites.
1983 - Worldwide photovoltaic production exceeds 21.3 megawatts, and sales exceed $250 million.
1984 - 30,000 SF Building-Integrated Photovoltaic [BI-PV] Roof completed for the Intercultural Center of Georgetown University. Eileen M. Smith, M.Arch. took 20th Anniversary Journey by Horseback for Peace and Photovoltaics in 2004 from solar roof to Ground Zero NY World Trade Center to educate public about BI-PV Solar Architecture. Array was still generating an average of one MWh daily as it has since 1984 in the dense urban environment of Washington, DC.
1986 - 'Solar-Voltaic DomeTM' patented by Lt. Colonel Richard T. Headrick of Irvine, California, as an efficient architectural configuration for building-integrated photovoltaics [BI-PV]; Hesperia, California field array.
1988 - The Dye-sensitized solar cell is created by Michael Grätzel and Brian O'Regan. These photoelectrochemical cells work from an organic dye compound inside the cell and cost half as much as silicon solar cells.
1988–1991 AMOCO/Enron used Solarex patents to sue ARCO Solar out of the business of a-Si (see Solarex Corp.(Enron/Amoco) v.Arco Solar, Inc.Ddel, 805 Fsupp 252 Fed Digest.)
1989 - Reflective solar concentrators are first used with solar cells.
1990 - The Magdeburg Cathedral installs solar cells on the roof, marking the first installation on a church in East Germany.
1992 - The PV Pioneer Program started at Sacramento Municipal Utility District (SMUD). It was the first broad based commercialization of distributed, grid-connected PV system ("roof-top solar") It became the model for the later CA Million Solar Roofs Program.[22]
1992 - University of South Florida fabricates a 15.89% efficient thin-film cell.[citation needed]
1994 - NREL develops a GaInP/GaAs two-terminal concentrator cell (180 suns) which becomes the first solar cell to exceed 30% conversion efficiency.[citation needed]
2006 - California Public Utilities Commission approved the California Solar Initiative (CSI), a comprehensive $2.8 billion program that provides incentives toward solar development over 11 years.[26]
2006 - New World Record Achieved in Solar Cell Technology - New Solar Cell Breaks the "40 Percent Efficient" Sunlight-to-Electricity Barrier.[27]
2007 - The Vatican announced that in order to conserve Earth's resources they would be installing solar panels on some buildings, in "a comprehensive energy project that will pay for itself in a few years."[28]
2007 - University of Delaware claims to achieve new world record in Solar Cell Technology without independent confirmation: 42.8% efficiency.[29]
2007 - Nanosolar ships the first commercial printed CIGS, claiming that they will eventually ship for less than $1/watt.[30] However, the company does not publicly disclose the technical specifications or current selling price of the modules.[31]
2008 - New record achieved in solar cell efficiency. Scientists at the U.S. Department of Energy's National Renewable Energy Laboratory (NREL) have set a world record in solar cell efficiency with a photovoltaic device that converts 40.8% of the light that hits it into electricity. However, it was only under the concentrated energy of 326 suns that this was achieved. The inverted metamorphic triple-junction solar cell was designed, fabricated and independently measured at NREL.[32]
2010 − IKAROS becomes the first spacecraft to successfully demonstrate solar sail technology in interplanetary space.[33][34]
2010 - US President Barack Obama orders installation of additional solar panels and a solar water heater at the White House[35]
2011 - Fast-growing factories in China push manufacturing costs down to about $1.25 per watt for silicon photovoltaic modules. Installations double worldwide.[36]
2013 - After three years, the solar panels ordered by President Barack Obama were installed on the White House.[37]
2016 - University of New South Wales engineers established a new world record for unfocused sunlight conversion to electricity with an efficiency increase to 34.5% [3]. The record was set by UNSW's Australian Centre for Advanced Photovoltaics (ACAP) using a 28 cm2 four-junction mini-module – embedded in a prism – that extracts the maximum energy from sunlight. It does this by splitting the incoming rays into four bands, using a four-junction receiver to squeeze even more electricity from each beam of sunlight.[38]
2016 - First Solar says it has converted 22.1 percent of the energy in sunlight into electricity using experimental cells made from cadmium telluride—a technology that today represents around 5 percent of the worldwide solar power market.[39]
6 March – Scientists show that adding a layer of perovskite crystals on top of textured or planar silicon to create a tandem solar cell enhances its performance up to a power conversion efficiency of 26%. This could be a low cost way to increase efficiency of solar cells.[49][50]
13 July – The first global assessment into promising approaches of solar photovoltaic modules recycling is published. Scientists recommend "research and development to reduce recycling costs and environmental impacts compared to disposal while maximizing material recovery" as well as facilitation and use of techno–economic analyses.[51][52]
3 July – Scientists show that adding an organic-based ionic solid into perovskites can result in substantial improvement in solar cell performance and stability. The study also reveals a complex degradation route that is responsible for failures in aged perovskite solar cells. The understanding could help the future development of photovoltaic technologies with industrially relevant longevity.[53][54][importance?]
2021
12 April – Scientists develop a prototype and design rules for both-sides-contacted siliconsolar cells with conversion efficiencies of 26% and above, Earth's highest for this type of solar cell.[55][56][importance?]
21 May – The first industrial commercial production line of perovskite solar panels, using an inkjet printing procedure, is launched in Poland.[59]
13 December – Researchers report the development of a database and analysis tool about perovskite solar cells which systematically integrates over 15,000 publications, in particular device-data about over 42,400 of such photovoltaic devices.[60][61]
16 December – ML System from Jasionka, Poland, opens first quantum glass production line. The factory started the production of windows integrating a transparent quantum-dots layer that can produce electricity while also capable of cooling buildings.[62][importance?]
2022
30 May - A team at Fraunhofer ISE led by Frank Dimroth developed a 4-junction solar cell with an efficiency of 47.6% - a new world record for solar energy conversion.[63][importance?]
13 July – Researchers report the development of semitransparent solar cells that are as large as windows,[64] after team members achieved record efficiency with high transparency in 2020.[65][66] On 4 July, researchers report the fabrication of solar cells with a record average visible transparency of 79%, being nearly invisible.[67][68]
19 December – A new world record solar cell efficiency for a silicon-perovskite tandem solar cell is achieved, with a German team of scientists converting 32.5% of sunlight into electrical energy.[71][importance?]
2024
12 March – Scientists demonstrate the first monolithically integrated tandem solar cell using selenium as the photoabsorbing layer in the top cell, and silicon as the photoabsorbing layer in the bottom cell.[72]
^D. M. Chapin; C. S. Fuller & G. L. Pearson (May 1954). "A New Silicon p-n Junction Photocell for Converting Solar Radiation into Electrical Power". Journal of Applied Physics. 25 (5): 676–677. Bibcode:1954JAP....25..676C. doi:10.1063/1.1721711.
^Alferov, Zh. I., V. M. Andreev, M. B. Kagan, I. I. Protasov, and V. G. Trofim, 1970, Solar-energy converters based on p-n AlxGa12xAs-GaAs heterojunctions, Fiz. Tekh. Poluprovodn. 4, 2378 (Sov. Phys. Semicond. 4, 2047 (1971))]
^Catalano, A.; D'Aiello, R. V.; Dresner, J.; Faughnan, B.; Firester, A.; Kane, J.; Schade, H.; Smith, Z. E.; Schwartz, G.; Triano, A. (1982). "Attainment of 10% Conversion Efficiency in Amorphous Silicon Solar Cells". Proceedings of the 16th IEEE Photovoltaic Specialists Conference, San Diego, California: 1421.
^Switching To Solar, Bob Johnstone, 2011, Prometheus Books
^Simone Pulver, Barry G. Rabe, Peter J. Stoett, Changing Climates in North American Politics: Institutions, Policymaking, and Multilevel Governance, MIT Press, 2009, ISBN0262012995 p. 67
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