Solar power

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The first three concentrated solar power (CSP) units of Spain's Solnova Solar Power Station in the foreground, with the PS10 and PS20 solar power towers in the background

Solar power, also known as solar electricity, is the conversion of energy from sunlight into electricity, either directly using photovoltaics (PV) or indirectly using concentrated solar power. Solar panels use the photovoltaic effect to convert light into an electric current.[2] Concentrated solar power systems use lenses or mirrors and solar tracking systems to focus a large area of sunlight to a hot spot, often to drive a steam turbine.

Photovoltaics (PV) were initially solely used as a source of electricity for small and medium-sized applications, from the calculator powered by a single solar cell to remote homes powered by an off-grid rooftop PV system. Commercial concentrated solar power plants were first developed in the 1980s. Since then, as the cost of solar panels has fallen, grid-connected solar PV systems' capacity and production has doubled about every three years. Three-quarters of new generation capacity is solar,[3] with both millions of rooftop installations and gigawatt-scale photovoltaic power stations continuing to be built.

In 2023, solar power generated 5.5% (1,631 TWh) of global electricity and over 1% of primary energy, adding twice as much new electricity as coal.[4][5] Along with onshore wind power, utility-scale solar is the source with the cheapest levelised cost of electricity for new installations in most countries.[6][7] As of 2023, 33 countries generated more than a tenth of their electricity from solar, with China making up more than half of solar growth.[8] Almost half the solar power installed in 2022 was mounted on rooftops.[9]

Much more low-carbon power is needed for electrification and to limit climate change.[3] The International Energy Agency said in 2022 that more effort was needed for grid integration and the mitigation of policy, regulation and financing challenges.[10] Nevertheless solar may greatly cut the cost of energy.[5]

Potential

Geography affects solar energy potential because different locations receive different amounts of solar radiation. In particular, with some variations, areas that are closer to the equator generally receive higher amounts of solar radiation. However, solar panels that can follow the position of the Sun can significantly increase the solar energy potential in areas that are farther from the equator.[11] Daytime cloud cover can reduce the light available for solar cells. Land availability also has a large effect on the available solar energy.

Technologies

Solar power plants use one of two technologies:

Photovoltaic cells

Schematics of a grid-connected residential PV power system[12]

A solar cell, or photovoltaic cell, is a device that converts light into electric current using the photovoltaic effect. The first solar cell was constructed by Charles Fritts in the 1880s.[13] The German industrialist Ernst Werner von Siemens was among those who recognized the importance of this discovery.[14] In 1931, the German engineer Bruno Lange developed a photo cell using silver selenide in place of copper oxide,[15] although the prototype selenium cells converted less than 1% of incident light into electricity. Following the work of Russell Ohl in the 1940s, researchers Gerald Pearson, Calvin Fuller and Daryl Chapin created the silicon solar cell in 1954.[16] These early solar cells cost US$286/watt and reached efficiencies of 4.5–6%.[17] In 1957, Mohamed M. Atalla developed the process of silicon surface passivation by thermal oxidation at Bell Labs.[18][19] The surface passivation process has since been critical to solar cell efficiency.[20]

As of 2022 over 90% of the market is crystalline silicon.[21] The array of a photovoltaic system, or PV system, produces direct current (DC) power which fluctuates with the sunlight's intensity. For practical use this usually requires conversion to alternating current (AC), through the use of inverters.[12] Multiple solar cells are connected inside panels. Panels are wired together to form arrays, then tied to an inverter, which produces power at the desired voltage, and for AC, the desired frequency/phase.[12]

Many residential PV systems are connected to the grid when available, especially in developed countries with large markets.[22] In these grid-connected PV systems, use of energy storage is optional. In certain applications such as satellites, lighthouses, or in developing countries, batteries or additional power generators are often added as back-ups. Such stand-alone power systems permit operations at night and at other times of limited sunlight.

In "vertical agrivoltaics" system, solar cells are oriented vertically on farmland, to allow the land to both grow crops and generate renewable energy.[23] Other configurations include floating solar farms, placing solar canopies over parking lots, and installing solar panels on roofs.[23]

Thin-film solar

A thin-film solar cell is a second generation solar cell that is made by depositing one or more thin layers, or thin film (TF) of photovoltaic material on a substrate, such as glass, plastic or metal. Thin-film solar cells are commercially used in several technologies, including cadmium telluride (CdTe), copper indium gallium diselenide (CIGS), and amorphous thin-film silicon (a-Si, TF-Si).[24]

Perovskite solar cells

A perovskite solar cell (PSC) is a type of solar cell that includes a perovskite-structured compound, most commonly a hybrid organic–inorganic lead or tin halide-based material as the light-harvesting active layer.[25][26] Perovskite materials, such as methylammonium lead halides and all-inorganic cesium lead halide, are cheap to produce and simple to manufacture.

Solar-cell efficiencies of laboratory-scale devices using these materials have increased from 3.8% in 2009[27] to 25.7% in 2021 in single-junction architectures,[28][29] and, in silicon-based tandem cells, to 29.8%,[28][30] exceeding the maximum efficiency achieved in single-junction silicon solar cells. Perovskite solar cells have therefore been the fastest-advancing solar technology as of 2016.[25] With the potential of achieving even higher efficiencies and very low production costs, perovskite solar cells have become commercially attractive. Core problems and research subjects include their short- and long-term stability.[31]

Concentrated solar power

A parabolic collector concentrates sunlight onto a tube in its focal point.

Concentrated solar power (CSP), also called "concentrated solar thermal", uses lenses or mirrors and tracking systems to concentrate sunlight, then uses the resulting heat to generate electricity from conventional steam-driven turbines.[32]

A wide range of concentrating technologies exists: among the best known are the parabolic trough, the compact linear Fresnel reflector, the dish Stirling and the solar power tower. Various techniques are used to track the sun and focus light. In all of these systems a working fluid is heated by the concentrated sunlight and is then used for power generation or energy storage.[33] Thermal storage efficiently allows overnight electricity generation,[34] thus complementing PV.[35] CSP generates a very small share of solar power and in 2022 the IEA said that CSP should be better paid for its storage.[36]

As of 2021 the levelized cost of electricity from CSP is over twice that of PV.[37] However, their very high temperatures may prove useful to help decarbonize industries (perhaps via hydrogen) which need to be hotter than electricity can provide.[38]

Hybrid systems

A hybrid system combines solar with energy storage and/or one or more other forms of generation. Hydro,[39][40] wind[41][42] and batteries[43] are commonly combined with solar. The combined generation may enable the system to vary power output with demand, or at least smooth the solar power fluctuation.[44][45] There is much hydro worldwide, and adding solar panels on or around existing hydro reservoirs is particularly useful, because hydro is usually more flexible than wind and cheaper at scale than batteries,[46] and existing power lines can sometimes be used.[47][48]

Development and deployment

The share of electricity production from solar, 2023[49]
Yearly solar generation by continent
Benefitting from favorable policies and declining costs of modules, photovoltaic solar installation has grown consistently.[50][51] In 2023, China added 60% of the world's new capacity.[52]
The growth of solar PV on a semi-log scale since 1996
Electricity production by source

Early days

The early development of solar technologies starting in the 1860s was driven by an expectation that coal would soon become scarce, such as experiments by Augustin Mouchot.[53] Charles Fritts installed the world's first rooftop photovoltaic solar array, using 1%-efficient selenium cells, on a New York City roof in 1884.[54] However, development of solar technologies stagnated in the early 20th century in the face of the increasing availability, economy, and utility of coal and petroleum.[55] Bell Telephone Laboratories’ 1950s research used silicon wafers with a thin coating of boron. The “Bell Solar Battery” was described as 6% efficient, with a square yard of the panels generating 50 watts.[56] The first satellite with solar panels was launched in 1957.[57]

By the 1970s, solar panels were still too expensive for much other than satellites.[58] In 1974 it was estimated that only six private homes in all of North America were entirely heated or cooled by functional solar power systems.[59] However, the 1973 oil embargo and 1979 energy crisis caused a reorganization of energy policies around the world and brought renewed attention to developing solar technologies.[60][61]

Deployment strategies focused on incentive programs such as the Federal Photovoltaic Utilization Program in the US and the Sunshine Program in Japan. Other efforts included the formation of research facilities in the United States (SERI, now NREL), Japan (NEDO), and Germany (Fraunhofer ISE).[62] Between 1970 and 1983 installations of photovoltaic systems grew rapidly. In the United States, President Jimmy Carter set a target of producing 20% of U.S. energy from solar by the year 2000, but his successor, Ronald Reagan, removed the funding for research into renewables.[58] Falling oil prices in the early 1980s moderated the growth of photovoltaics from 1984 to 1996.

Mid-1990s to 2010

In the mid-1990s development of both, residential and commercial rooftop solar as well as utility-scale photovoltaic power stations began to accelerate again due to supply issues with oil and natural gas, global warming concerns, and the improving economic position of PV relative to other energy technologies.[58][63] In the early 2000s, the adoption of feed-in tariffs—a policy mechanism, that gives renewables priority on the grid and defines a fixed price for the generated electricity—led to a high level of investment security and to a soaring number of PV deployments in Europe.

2010s

For several years, worldwide growth of solar PV was driven by European deployment, but it then shifted to Asia, especially China and Japan, and to a growing number of countries and regions all over the world. The largest manufacturers of solar equipment were based in China.[64][65] Although concentrated solar power capacity grew more than tenfold, it remained a tiny proportion of the total,[66]: 51  because the cost of utility-scale solar PV fell by 85% between 2010 and 2020, while CSP costs only fell 68% in the same timeframe.[67]

2020s

Despite the rising cost of materials, such as polysilicon, during the 2021–2022 global energy crisis,[68] utility scale solar was still the least expensive energy source in many countries due to the rising costs of other energy sources, such as natural gas.[69] In 2022, global solar generation capacity exceeded 1 TW for the first time.[70] However, fossil-fuel subsidies have slowed the growth of solar generation capacity.[71]

Current status

About half of installed capacity is utility scale.[72]

Map of solar resources from World bank

Forecasts

Actual annual deployments of solar PV vs predictions by the IEA for the period 2002–2016. Predictions have largely and consistently underestimated actual growth.

Most new renewable capacity between 2022 and 2027 is forecast to be solar, surpassing coal as the largest source of installed power capacity.[73]: 26  Utility scale is forecast to become the largest source of electricity in all regions except sub-Saharan Africa by 2050.[72]

According to a 2021 study, global electricity generation potential of rooftop solar panels is estimated at 27 PWh per year at costs ranging from $40 (Asia) to $240 per MWh (US, Europe). Its practical realization will however depend on the availability and cost of scalable electricity storage solutions.[74]

Photovoltaic power stations

Solar park
The 40.5 MW Jännersdorf Solar Park in Prignitz, Germany

A photovoltaic power station, also known as a solar park, solar farm, or solar power plant, is a large-scale grid-connected photovoltaic power system (PV system) designed for the supply of merchant power. They are different from most building-mounted and other decentralized solar power because they supply power at the utility level, rather than to a local user or users. Utility-scale solar is sometimes used to describe this type of project.

This approach differs from concentrated solar power, the other major large-scale solar generation technology, which uses heat to drive a variety of conventional generator systems. Both approaches have their own advantages and disadvantages, but to date, for a variety of reasons, photovoltaic technology has seen much wider use. As of 2019, about 97% of utility-scale solar power capacity was PV.[75][76]

In some countries, the nameplate capacity of photovoltaic power stations is rated in megawatt-peak (MWp), which refers to the solar array's theoretical maximum DC power output. In other countries, the manufacturer states the surface and the efficiency. However, Canada, Japan, Spain, and the United States often specify using the converted lower nominal power output in MWAC, a measure more directly comparable to other forms of power generation. Most solar parks are developed at a scale of at least 1 MWp. As of 2018, the world's largest operating photovoltaic power stations surpassed 1 gigawatt. At the end of 2019, about 9,000 solar farms were larger than 4 MWAC (utility scale), with a combined capacity of over 220 GWAC.[75]

Most of the existing large-scale photovoltaic power stations are owned and operated by independent power producers, but the involvement of community and utility-owned projects is increasing.[77] Previously, almost all were supported at least in part by regulatory incentives such as feed-in tariffs or tax credits, but as levelized costs fell significantly in the 2010s and grid parity has been reached in most markets, external incentives are usually not needed.

Concentrating solar power stations

Ivanpah Solar Electric Generating System with all three towers under load
Part of the 354 MW Solar Energy Generating Systems (SEGS) parabolic trough solar complex in northern San Bernardino County, California

Commercial concentrating solar power (CSP) plants, also called "solar thermal power stations", were first developed in the 1980s. The 377 MW Ivanpah Solar Power Facility, located in California's Mojave Desert, is the world's largest solar thermal power plant project. Other large CSP plants include the Solnova Solar Power Station (150 MW), the Andasol solar power station (150 MW), and Extresol Solar Power Station (150 MW), all in Spain. The principal advantage of CSP is the ability to efficiently add thermal storage, allowing the dispatching of electricity over up to a 24-hour period. Since peak electricity demand typically occurs at about 5 pm, many CSP power plants use 3 to 5 hours of thermal storage.[78]

Economics

Cost per watt

The typical cost factors for solar power include the costs of the modules, the frame to hold them, wiring, inverters, labour cost, any land that might be required, the grid connection, maintenance and the solar insolation that location will receive.

Photovoltaic systems use no fuel, and modules typically last 25 to 40 years.[79] Thus upfront capital and financing costs make up 80% to 90% of the cost of solar power,[73]: 165  which is a problem for countries where contracts may not be honoured, such as some African countries.[5] Some countries are considering price caps,[80] whereas others prefer contracts for difference.[81]

In many countries, solar power is the lowest cost source of electricity.[82] In Saudi Arabia, a power purchase agreement (PPA) was signed in April 2021 for a new solar power plant in Al-Faisaliah. The project has recorded the world's lowest cost for solar PV electricity production of USD 1.04 cents/ kWh.[83]

Installation prices

Expenses of high-power band solar modules has greatly decreased over time. Beginning in 1982, the cost per kW was approximately 27,000 American dollars, and in 2006 the cost dropped to approximately 4,000 American dollars per kW. The PV system in 1992 cost approximately 16,000 American dollars per kW and it dropped to approximately 6,000 American dollars per kW in 2008.[84] In 2021 in the US, residential solar cost from 2 to 4 dollars/watt (but solar shingles cost much more)[85] and utility solar costs were around $1/watt.[86]

Productivity by location

The productivity of solar power in a region depends on solar irradiance, which varies through the day and year and is influenced by latitude and climate. PV system output power also depends on ambient temperature, wind speed, solar spectrum, the local soiling conditions, and other factors.

Onshore wind power tends to be the cheapest source of electricity in Northern Eurasia, Canada, some parts of the United States, and Patagonia in Argentina whereas in other parts of the world mostly solar power (or less often a combination of wind, solar and other low carbon energy) is thought to be best.[87]: 8  Modelling by Exeter University suggests that by 2030, solar will be least expensive in all countries except for some in north-eastern Europe.[88]

The locations with highest annual solar irradiance lie in the arid tropics and subtropics. Deserts lying in low latitudes usually have few clouds and can receive sunshine for more than ten hours a day.[89][90] These hot deserts form the Global Sun Belt circling the world. This belt consists of extensive swathes of land in Northern Africa, Southern Africa, Southwest Asia, Middle East, and Australia, as well as the much smaller deserts of North and South America.[91]

Thus solar is (or is predicted to become) the cheapest source of energy in all of Central America, Africa, the Middle East, India, South-east Asia, Australia, and several other regions.[87]: 8 

Different measurements of solar irradiance (direct normal irradiance, global horizontal irradiance) are mapped below:

  • North America
    North America
  • South America
    South America
  • Europe
    Europe
  • Africa and Middle East
    Africa and Middle East
  • South and South-East Asia
    South and South-East Asia
  • Australia
    Australia
  • World
    World

Self-consumption

In cases of self-consumption of solar energy, the payback time is calculated based on how much electricity is not purchased from the grid.[92] However, in many cases, the patterns of generation and consumption do not coincide, and some or all of the energy is fed back into the grid. The electricity is sold, and at other times when energy is taken from the grid, electricity is bought. The relative costs and prices obtained affect the economics. In many markets, the price paid for sold PV electricity is significantly lower than the price of bought electricity, which incentivizes self-consumption.[93] Moreover, separate self-consumption incentives have been used in e.g., Germany and Italy.[93] Grid interaction regulation has also included limitations of grid feed-in in some regions in Germany with high amounts of installed PV capacity.[93][94] By increasing self-consumption, the grid feed-in can be limited without curtailment, which wastes electricity.[95]

A good match between generation and consumption is key for high self-consumption. The match can be improved with batteries or controllable electricity consumption.[95] However, batteries are expensive, and profitability may require the provision of other services from them besides self-consumption increase,[96] for example avoiding power outages.[97] Hot water storage tanks with electric heating with heat pumps or resistance heaters can provide low-cost storage for self-consumption of solar power.[95] Shiftable loads, such as dishwashers, tumble dryers and washing machines, can provide controllable consumption with only a limited effect on the users, but their effect on self-consumption of solar power may be limited.[95]

Energy pricing, incentives and taxes

The original political purpose of incentive policies for PV was to facilitate an initial small-scale deployment to begin to grow the industry, even where the cost of PV was significantly above grid parity, to allow the industry to achieve the economies of scale necessary to reach grid parity. Since reaching grid parity, some policies are implemented to promote national energy independence,[98] high tech job creation[99] and reduction of CO2 emissions.[98]

Financial incentives for photovoltaics differ across countries, including Australia,[100] China,[101] Germany,[102] India,[103] Japan, and the United States and even across states within the US.

Net metering

Net metering, unlike a feed-in tariff, requires only one meter, but it must be bi-directional.

In net metering the price of the electricity produced is the same as the price supplied to the consumer, and the consumer is billed on the difference between production and consumption. Net metering can usually be done with no changes to standard electricity meters, which accurately measure power in both directions and automatically report the difference, and because it allows homeowners and businesses to generate electricity at a different time from consumption, effectively using the grid as a giant storage battery. With net metering, deficits are billed each month while surpluses are rolled over to the following month. Best practices call for perpetual roll over of kWh credits.[104] Excess credits upon termination of service are either lost or paid for at a rate ranging from wholesale to retail rate or above, as can be excess annual credits.[105]

Community solar

Community solar farm in the town of Wheatland, Wisconsin[106]

A community solar project is a solar power installation that accepts capital from and provides output credit and tax benefits to multiple customers, including individuals, businesses, nonprofits, and other investors. Participants typically invest in or subscribe to a certain kW capacity or kWh generation of remote electrical production.[107]

Taxes

In some countries tariffs (import taxes) are imposed on imported solar panels.[108][109]

Grid integration

Energy from sunlight or other renewable energy is converted to potential energy for storage in devices such as electric batteries or higher-elevation water reservoirs. The stored potential energy is later converted to electricity that is added to the power grid, even when the original energy source is not available.
Salt Tanks provide thermal energy storage[110] so that output can be provided after sunset, and output can be scheduled to meet demand requirements.[111] The 280 MW Solana Generating Station is designed to provide six hours of energy storage. This allows the plant to generate about 38% of its rated capacity over the course of a year.[112]
Thermal energy storage. The Andasol CSP plant uses tanks of molten salt to store solar energy.
Pumped-storage hydroelectricity (PSH). This facility in Geesthacht, Germany, also includes a solar array.

Variability

The overwhelming majority of electricity produced worldwide is used immediately because traditional generators can adapt to demand and storage is usually more expensive. Both solar power and wind power are sources of variable renewable power, meaning that all available output must be used locally, carried on transmission lines to be used elsewhere, or stored (e.g., in a battery). Since solar energy is not available at night, storing it so as to have continuous electricity availability is potentially an important issue, particularly in off-grid applications and for future 100% renewable energy scenarios.[113]

Solar is intermittent due to the day/night cycles and variable weather conditions. However solar power can be forecast somewhat by time of day, location, and seasons. The challenge of integrating solar power in any given electric utility varies significantly. In places with hot summers and mild winters, solar tends to be well matched to daytime cooling demands.[114]

Energy storage

Concentrated solar power plants may use thermal storage to store solar energy, such as in high-temperature molten salts. These salts are an effective storage medium because they are low-cost, have a high specific heat capacity, and can deliver heat at temperatures compatible with conventional power systems. This method of energy storage is used, for example, by the Solar Two power station, allowing it to store 1.44 TJ in its 68 m3 storage tank, enough to provide full output for close to 39 hours, with an efficiency of about 99%.[115]

In stand alone PV systems, batteries are traditionally used to store excess electricity. With grid-connected photovoltaic power systems, excess electricity can be sent to the electrical grid. Net metering and feed-in tariff programs give these systems a credit for the electricity they produce. This credit offsets electricity provided from the grid when the system cannot meet demand, effectively trading with the grid instead of storing excess electricity.[116] When wind and solar are a small fraction of the grid power, other generation techniques can adjust their output appropriately, but as these forms of variable power grow, additional balance on the grid is needed. As prices are rapidly declining, PV systems increasingly use rechargeable batteries to store a surplus to be used later at night. Batteries used for grid-storage can stabilize the electrical grid by leveling out peak loads for a few hours. In the future, less expensive batteries could play an important role on the electrical grid, as they can charge during periods when generation exceeds demand and feed their stored energy into the grid when demand is higher than generation.

Common battery technologies used in today's home PV systems include nickel-cadmium, lead-acid, nickel metal hydride, and lithium-ion.[117][118][better source needed]Lithium-ion batteries have the potential to replace lead-acid batteries in the near future, as they are being intensively developed and lower prices are expected due to economies of scale provided by large production facilities such as the Tesla Gigafactory 1. In addition, the Li-ion batteries of plug-in electric cars may serve as future storage devices in a vehicle-to-grid system. Since most vehicles are parked an average of 95% of the time, their batteries could be used to let electricity flow from the car to the power lines and back.

Retired electric vehicle (EV) batteries can be repurposed.[119] Other rechargeable batteries used for distributed PV systems include, sodium–sulfur and vanadium redox batteries, two prominent types of a molten salt and a flow battery, respectively.[120][121][122]

Seasonal cycle of capacity factors for wind and photovoltaics in Europe shown under idealized assumptions. The figure illustrates the balancing effects of wind and solar energy at the seasonal scale (Kaspar et al., 2019).[123]

Other technologies

Solar power plants, while they can be curtailed, usually simply output as much power as possible. Therefore in an electricity system without sufficient grid energy storage, generation from other sources (coal, biomass, natural gas, nuclear, hydroelectricity) generally go up and down in reaction to the rise and fall of solar electricity and variations in demand (see load following power plant).

Conventional hydroelectric dams work very well in conjunction with solar power; water can be held back or released from a reservoir as required. Where suitable geography is not available, pumped-storage hydroelectricity can use solar power to pump water to a high reservoir on sunny days, then the energy is recovered at night and in bad weather by releasing water via a hydroelectric plant to a low reservoir where the cycle can begin again.[124]

While hydroelectric and natural gas plants can quickly respond to changes in load; coal, biomass and nuclear plants usually take considerable time to respond to load and can only be scheduled to follow the predictable variation. Depending on local circumstances, beyond about 20–40% of total generation, grid-connected intermittent sources like solar tend to require investment in some combination of grid interconnections, energy storage or demand side management. In countries with high solar generation, such as Australia, electricity prices may become negative in the middle of the day when solar generation is high, thus incentivizing new battery storage.[125][126]

The combination of wind and solar PV has the advantage that the two sources complement each other because the peak operating times for each system occur at different times of the day and year.[127] The power generation of such solar hybrid power systems is therefore more constant and fluctuates less than each of the two component subsystems.[128] Solar power is seasonal, particularly in northern/southern climates, away from the equator, suggesting a need for long term seasonal storage in a medium such as hydrogen or pumped hydroelectric.[129]

Environmental effects

Greenhouse gas emissions per energy source. Solar power is one of the sources with the least greenhouse gas emissions.
Part of the Senftenberg Solarpark, a solar photovoltaic power plant located on former open-pit mining areas close to the city of Senftenberg, in Eastern Germany. The 78 MW Phase 1 of the plant was completed within three months.

Solar power is cleaner than electricity from fossil fuels,[21] so can be better for the environment.[130] Solar power does not lead to harmful emissions during operation, but the production of the panels creates some pollution. The carbon footprint of manufacturing is less than 1kg CO2/Wp,[131] and this is expected to fall as manufacturers use more clean electricity and recycled materials.[132] Solar power carries an upfront cost to the environment via production with a carbon payback time of several years as of 2022,[132] but offers clean energy for the remainder of their 30-year lifetime.[133]

The life-cycle greenhouse-gas emissions of solar farms are less than 50 gram (g) per kilowatt-hour (kWh),[134][135][136] but with battery storage could be up to 150 g/kWh.[137] In contrast, a combined cycle gas-fired power plant without carbon capture and storage emits around 500 g/kWh, and a coal-fired power plant about 1000 g/kWh.[138] Similar to all energy sources where their total life cycle emissions are mostly from construction, the switch to low carbon power in the manufacturing and transportation of solar devices would further reduce carbon emissions.[136]

Lifecycle surface power density of solar power varies[139] but averages about 7 W/m2, compared to about 240 for nuclear power and 480 for gas.[140] However, when the land required for gas extraction and processing is accounted for, gas power is estimated to have not much higher power density than solar.[21] PV requires much larger amounts of land surface to produce the same nominal amount of energy as sources[which?] with higher surface power density and capacity factor. According to a 2021 study, obtaining 25% to 80% of electricity from solar farms in their own territory by 2050 would require the panels to cover land ranging from 0.5% to 2.8% of the European Union, 0.3% to 1.4% in India, and 1.2% to 5.2% in Japan and South Korea.[141] Occupation of such large areas for PV farms could drive residential opposition as well as lead to deforestation, removal of vegetation and conversion of farm land.[142] However some countries, such as South Korea and Japan, use land for agriculture under PV,[143][144] or floating solar,[145] together with other low-carbon power sources.[146][147] Worldwide land use has minimal ecological impact.[148] Land use can be reduced to the level of gas power by installing on buildings and other built up areas.[139]

Harmful materials are used in the production of solar panels, but generally in small amounts.[149] As of 2022, the environmental impact of perovskite is difficult to estimate, but there is some concern that lead may be a problem.[21]

A 2021 International Energy Agency study projects the demand for copper will double by 2040. The study cautions that supply needs to increase rapidly to match demand from large-scale deployment of solar and required grid upgrades.[150][151] More tellurium and indium may also be needed.[21]

Recycling may help.[21] As solar panels are sometimes replaced with more efficient panels, the second-hand panels are sometimes reused in developing countries, for example in Africa.[152] Several countries have specific regulations for the recycling of solar panels.[153][154][155] Although maintenance cost is already low compared to other energy sources,[156] some academics have called for solar power systems to be designed to be more repairable.[157][158]

Solar panels can increase local temperature. In large installation in the desert, the effect can be stronger than the urban heat island.[159]

A very small proportion of solar power is concentrated solar power. Concentrated solar power may use much more water than gas-fired power. This can be a problem, as this type of solar power needs strong sunlight so is often built in deserts.[160]

Politics

Acceptance of wind and solar facilities in one's community is stronger among U.S. Democrats (blue), while acceptance of nuclear power plants is stronger among U.S. Republicans (red).[161]

Solar generation cannot be cut off by geopolitics once installed, unlike oil and gas, which contributes to energy security.[162]

As of 2022 over 40% of global polysilicon manufacturing capacity is in Xinjiang in China,[163] which raises concerns about human rights violations (Xinjiang internment camps).[164]

According to the International Solar Energy Society China's dominance of manufacturing is not a problem, both because they estimate solar manufacturing cannot grow to more than 400b USD per year, and because if Chinese supply was cut off other countries would have years to create their own industry.[165]

See also

References

  1. ^ "Global Solar Atlas". globalsolaratlas.info. Retrieved 12 August 2022.
  2. ^ "Energy Sources: Solar". Department of Energy. Archived from the original on 14 April 2011. Retrieved 19 April 2011.
  3. ^ a b Gabbatiss, Josh (12 January 2024). "Analysis: World will add enough renewables in five years to power US and Canada". Carbon Brief. Retrieved 11 February 2024.
  4. ^ "Global Electricity Review 2024". Ember. 7 May 2024. Retrieved 2 September 2024.
  5. ^ a b c "Sun Machines". The Economist. ISSN 0013-0613. Retrieved 26 June 2024.
  6. ^ "2023 Levelized Cost Of Energy+". Lazard. Retrieved 14 June 2023.
  7. ^ "Executive summary – Renewable Energy Market Update – Analysis". IEA. June 2023. Retrieved 14 June 2023.
  8. ^ "Global Electricity Review 2024". Ember. 7 May 2024. Retrieved 2 September 2024.
  9. ^ Norman, Will (13 June 2023). "Through the roof: 49.5% of world's PV additions were rooftop in 2022 – SolarPower Europe". PV Tech. Retrieved 14 June 2023.
  10. ^ "Solar PV – Analysis". IEA. Retrieved 10 November 2022.
  11. ^ Goldemberg, José; UNDP, eds. (2000). World energy assessment: energy and the challenge of sustainability (1. print ed.). New York, New York: United Nations Development Programme. ISBN 978-92-1-126126-4.
  12. ^ a b c Lewis Fraas, Larry Partain. Solar Cells and their Applications, Second Edition, Wiley, 2010, ISBN 978-0-470-44633-1, Section10.2.
  13. ^ Perlin 1999, p. 147.
  14. ^ Perlin 1999, pp. 18–20.
  15. ^ Corporation, Bonnier (June 1931). "Magic Plates, Tap Sun For Power". Popular Science: 41. Retrieved 19 April 2011.
  16. ^ Perlin 1999, p. 29.
  17. ^ Perlin 1999, pp. 29–30, 38.
  18. ^ Black, Lachlan E. (2016). New Perspectives on Surface Passivation: Understanding the Si-Al2O3 Interface (PDF). Springer. p. 13. ISBN 9783319325217.
  19. ^ Lojek, Bo (2007). History of Semiconductor Engineering. Springer Science & Business Media. pp. 120& 321–323. ISBN 9783540342588.
  20. ^ Black, Lachlan E. (2016). New Perspectives on Surface Passivation: Understanding the Si-Al2O3 Interface (PDF). Springer. ISBN 9783319325217.
  21. ^ a b c d e f Urbina, Antonio (26 October 2022). "Sustainability of photovoltaic technologies in future net-zero emissions scenarios". Progress in Photovoltaics: Research and Applications. 31 (12): 1255–1269. doi:10.1002/pip.3642. ISSN 1062-7995. S2CID 253195560. the apparent contradiction that can arise from the fact that large PV plants occupy more land than the relatively compact coal or gas plants is due to the inclusion in the calculation of impacts in land occupation arising from coal mining and oil or gas extraction; if they are included, the impact on land occupation is larger for fossil fuels.
  22. ^ "Trends in Photovoltaic Applications Survey report of selected IEA countries between 1992 and 2009, IEA-PVPS". Archived from the original on 25 May 2017. Retrieved 8 November 2011.
  23. ^ a b Budin, Jeremiah (17 January 2024). "Game-Changing Solar Power Technology to Get First US Installation: Valuable Land is almost Completely Preserved". The Cooldown. Archived from the original on 17 January 2024.
  24. ^ "Thin-Film Solar Panels | American Solar Energy Society".
  25. ^ a b Manser, Joseph S.; Christians, Jeffrey A.; Kamat, Prashant V. (2016). "Intriguing Optoelectronic Properties of Metal Halide Perovskites". Chemical Reviews. 116 (21): 12956–13008. doi:10.1021/acs.chemrev.6b00136. PMID 27327168.
  26. ^ Hamers, Laurel (26 July 2017). "Perovskites power up the solar industry". Science News.
  27. ^ Kojima, Akihiro; Teshima, Kenjiro; Shirai, Yasuo; Miyasaka, Tsutomu (6 May 2009). "Organometal Halide Perovskites as Visible-Light Sensitizers for Photovoltaic Cells". Journal of the American Chemical Society. 131 (17): 6050–6051. doi:10.1021/ja809598r. PMID 19366264.
  28. ^ a b "Best Research-Cell Efficiencies" (PDF). National Renewable Energy Laboratory. 30 June 2022. Archived from the original (PDF) on 3 August 2022. Retrieved 12 July 2022.
  29. ^ Min, Hanul; Lee, Do Yoon; Kim, Junu; Kim, Gwisu; Lee, Kyoung Su; Kim, Jongbeom; Paik, Min Jae; Kim, Young Ki; Kim, Kwang S.; Kim, Min Gyu; Shin, Tae Joo; Il Seok, Sang (21 October 2021). "Perovskite solar cells with atomically coherent interlayers on SnO2 electrodes". Nature. 598 (7881): 444–450. Bibcode:2021Natur.598..444M. doi:10.1038/s41586-021-03964-8. PMID 34671136. S2CID 239052065.
  30. ^ Helmholtz-Zentrum Berlin für Materialien und Energie. "World record again at HZB: Almost 30 % efficiency for next-generation tandem solar cells". HZB Website.
  31. ^ Sun, Kai; Wang, Yanyan; Xu, Haoyuan; Zhang, Jing; Zhu, Yuejin; Hu, Ziyang (2019). "Short-Term Stability of Perovskite Solar Cells Affected by In Situ Interface Modification". Solar RRL. 3 (9): 1900089. doi:10.1002/solr.201900089. S2CID 202229877.
  32. ^ "How CSP Works: Tower, Trough, Fresnel or Dish". Solarpaces. 11 June 2018. Retrieved 14 March 2020.
  33. ^ Martin and Goswami (2005), p. 45.
  34. ^ Lacey, Stephen (6 July 2011). "Spanish CSP Plant with Storage Produces Electricity for 24 Hours Straight". Archived from the original on 12 October 2012.
  35. ^ "More countries are turning to this technology for clean energy. It's coming to Australia". ABC News. 5 October 2022. Retrieved 4 November 2022.
  36. ^ "Renewable Electricity – Analysis". IEA. Retrieved 4 November 2022.
  37. ^ "Renewable Power Generation Costs in 2021". irena.org. 13 July 2022. Retrieved 4 November 2022.
  38. ^ Casey, Tina (30 September 2022). "US Energy Dept. Still Holds Torch For Concentrating Solar Power". CleanTechnica. Retrieved 4 November 2022.
  39. ^ Garanovic, Amir (10 November 2021). "World's largest hydro-floating solar hybrid comes online in Thailand". Offshore Energy. Retrieved 7 November 2022.
  40. ^ Ming, Bo; Liu, Pan; Guo, Yi (1 January 2022), Jurasz, Jakub; Beluco, Alexandre (eds.), "Chapter 20 – Operations management of large hydro–PV hybrid power plants: case studies in China", Complementarity of Variable Renewable Energy Sources, Academic Press, pp. 439–502, ISBN 978-0-323-85527-3, retrieved 7 November 2022
  41. ^ "World's largest wind-solar hybrid complex goes online in India". Renewablesnow.com. Retrieved 7 November 2022.
  42. ^ Todorović, Igor (4 November 2022). "China completes world's first hybrid offshore wind-solar power plant". Balkan Green Energy News. Retrieved 7 November 2022.
  43. ^ Which?. "Solar panel battery storage". Which?. Retrieved 7 November 2022.
  44. ^ Brumana, Giovanni; Franchini, Giuseppe; Ghirardi, Elisa; Perdichizzi, Antonio (1 May 2022). "Techno-economic optimization of hybrid power generation systems: A renewables community case study". Energy. 246: 123427. Bibcode:2022Ene...24623427B. doi:10.1016/j.energy.2022.123427. ISSN 0360-5442. S2CID 246695199.
  45. ^ Wang, Zhenni; Wen, Xin; Tan, Qiaofeng; Fang, Guohua; Lei, Xiaohui; Wang, Hao; Yan, Jinyue (1 August 2021). "Potential assessment of large-scale hydro-photovoltaic-wind hybrid systems on a global scale". Renewable and Sustainable Energy Reviews. 146: 111154. doi:10.1016/j.rser.2021.111154. ISSN 1364-0321. S2CID 235925315.
  46. ^ Todorović, Igor (22 July 2022). "Portugal, Switzerland launch pumped storage hydropower plants of over 2 GW in total". Balkan Green Energy News. Retrieved 8 November 2022.
  47. ^ Bank (ADB), Asian Development. "ADB Partnership Report 2019: Building Strong Partnerships for Shared Progress". Asian Development Bank. Retrieved 7 November 2022.
  48. ^ Merlet, Stanislas; Thorud, Bjørn (18 November 2020). "Floating solar power connected to hydropower might be the future for renewable energy". sciencenorway.no. Retrieved 7 November 2022.
  49. ^ "Share of electricity production from solar". Our World in Data. Retrieved 20 June 2024.
  50. ^ "Chart: Solar installations set to break global, US records in 2023". Canary Media. 15 September 2023. Archived from the original on 17 September 2023. For relevant chart, Canary Media credits: "Source: BloombergNEF, September 2023"
  51. ^ Chase, Jenny (5 September 2023). "3Q 2023 Global PV Market Outlook". BloombergNEF. Archived from the original on 21 September 2023.
  52. ^ 2023 data: Chase, Jenny (4 March 2024). "1Q 2024 Global PV Market Outlook". BNEF.com. BloombergNEF. Archived from the original on 13 June 2024.
  53. ^ Scientific American. Munn & Company. 10 April 1869. p. 227.
  54. ^ "Photovoltaic Dreaming 1875–1905: First Attempts At Commercializing PV". cleantechnica.com. 31 December 2014. Archived from the original on 25 May 2017. Retrieved 30 April 2018.
  55. ^ Butti and Perlin (1981), pp. 63, 77, 101.
  56. ^ ”The Bell Solar Battery” (advertisement). Audio, July 1964, 15.
  57. ^ "Vanguard I The World's Oldest Satellite Still in Orbit". Archived from the original on 21 March 2015. Retrieved 24 September 2007. Public Domain This article incorporates text from this source, which is in the public domain.
  58. ^ a b c Levy, Adam (13 January 2021). "The dazzling history of solar power". Knowable Magazine. doi:10.1146/knowable-011321-1. S2CID 234124275. Retrieved 25 March 2022.
  59. ^ "The Solar Energy Book—Once More." Mother Earth News 31: 16–17, January 1975.
  60. ^ Butti and Perlin (1981), p. 249.
  61. ^ Yergin (1991), pp. 634, 653–673.
  62. ^ "Chronicle of Fraunhofer-Gesellschaft". Fraunhofer-Gesellschaft. Archived from the original on 12 December 2007. Retrieved 4 November 2007.
  63. ^ Solar: photovoltaic: Lighting Up The World retrieved 19 May 2009 Archived 13 August 2010 at the Wayback Machine.
  64. ^ Colville, Finlay (30 January 2017). "Top-10 solar cell producers in 2016". PV-Tech. Archived from the original on 2 February 2017.
  65. ^ Ball, Jeffrey; et al. (21 March 2017). "The New Solar System – Executive Summary" (PDF). Stanford University Law School, Steyer-Taylor Center for Energy Policy and Finance. Archived (PDF) from the original on 20 April 2017. Retrieved 27 June 2017.
  66. ^ REN21 (2014). "Renewables 2014: Global Status Report" (PDF). Archived (PDF) from the original on 15 September 2014.{{cite web}}: CS1 maint: numeric names: authors list (link)
  67. ^ Santamarta, Jose. "The cost of Concentrated Solar Power declined by 16%". HELIOSCSP. Retrieved 15 September 2022.
  68. ^ "What is the impact of increasing commodity and energy prices on solar PV, wind and biofuels? – Analysis". IEA. December 2021. Retrieved 4 April 2022.
  69. ^ "Levelized Cost Of Energy, Levelized Cost Of Storage, and Levelized Cost Of Hydrogen". Lazard.com. Retrieved 4 April 2022.
  70. ^ "World Installs a Record 168 GW of Solar Power in 2021, enters Solar Terawatt Age". SolarPower Europe.
  71. ^ McDonnell, Tim (29 August 2022). "Soaring fossil fuel subsidies are holding back clean energy". Quartz. Retrieved 4 September 2022.
  72. ^ a b Olson, Dana; Bakken, Bent Erik. "Utility-scale solar PV: From big to biggest". Det Norske Veritas. Retrieved 15 January 2024.
  73. ^ a b "Renewable electricity – Renewables 2022 – Analysis". IEA. Retrieved 12 December 2022.
  74. ^ Cork, University College. "Assessing global electricity generation potential from rooftop solar photovoltaics". techxplore.com. Retrieved 11 October 2021.
  75. ^ a b Wolfe, Philip (17 March 2020). "Utility-scale solar sets new record" (PDF). Wiki-Solar. Retrieved 11 May 2010.
  76. ^ "Concentrated solar power had a global total installed capacity of 6,451 MW in 2019". HelioCSP. 2 February 2020. Retrieved 11 May 2020.
  77. ^ "Expanding Renewable Energy in Pakistan's Electricity Mix". World Bank. Retrieved 17 July 2022.
  78. ^ What is peak demand? Archived 11 August 2012 at the Wayback Machine, Energex.com.au website.
  79. ^ Nian, Victor; Mignacca, Benito; Locatelli, Giorgio (15 August 2022). "Policies toward net-zero: Benchmarking the economic competitiveness of nuclear against wind and solar energy". Applied Energy. 320: 119275. Bibcode:2022ApEn..32019275N. doi:10.1016/j.apenergy.2022.119275. hdl:11311/1227558. ISSN 0306-2619. S2CID 249223353.
  80. ^ "EU expects to raise €140bn from windfall tax on energy firms". the Guardian. 14 September 2022. Retrieved 15 September 2022.
  81. ^ "The EU's energy windfall tax gives UK ministers a yardstick for their talks". The Guardian. 14 September 2022. Retrieved 15 September 2022.
  82. ^ "Why wind and solar are key solutions to combat climate change". Ember. 9 February 2024. Retrieved 11 February 2024.
  83. ^ "Saudi Arabia signed Power Purchase Agreement for 2,970MW Solar PV Projects". saudigulfprojects.com. 8 April 2021. Retrieved 28 August 2022.
  84. ^ Timilsina, Govinda R.; Kurdgelashvili, Lado; Narbel, Patrick A. (1 January 2012). "Solar energy: Markets, economics and policies". Renewable and Sustainable Energy Reviews. 16 (1): 449–465. doi:10.1016/j.rser.2011.08.009. ISSN 1364-0321.
  85. ^ "Solar Shingles Vs. Solar Panels: Cost, Efficiency & More (2021)". EcoWatch. 8 August 2021. Retrieved 25 August 2021.
  86. ^ "Solar Farms: What Are They and How Much Do They Cost? | EnergySage". Solar News. 18 June 2021. Retrieved 25 August 2021.
  87. ^ a b Bogdanov, Dmitrii; Ram, Manish; Aghahosseini, Arman; Gulagi, Ashish; Oyewo, Ayobami Solomon; Child, Michael; Caldera, Upeksha; Sadovskaia, Kristina; Farfan, Javier; De Souza Noel Simas Barbosa, Larissa; Fasihi, Mahdi (15 July 2021). "Low-cost renewable electricity as the key driver of the global energy transition towards sustainability". Energy. 227: 120467. Bibcode:2021Ene...22720467B. doi:10.1016/j.energy.2021.120467. ISSN 0360-5442. S2CID 233706454.
  88. ^ "Is a solar future inevitable?" (PDF). University of Exeter. Retrieved 2 October 2023.
  89. ^ "Daytime Cloud Fraction Coast lines evident". Archived from the original on 22 August 2017. Retrieved 22 August 2017.
  90. ^ "Sunshine". Archived from the original on 23 September 2015. Retrieved 6 September 2015.
  91. ^ "Living in the Sun Belt : The Solar Power Potential for the Middle East". 27 July 2016. Archived from the original on 26 August 2017. Retrieved 22 August 2017.
  92. ^ "Money saved by producing electricity from PV and Years for payback". Archived from the original on 28 December 2014.
  93. ^ Stetz, T.; Marten, F.; Braun, M. (2013). "Improved Low Voltage Grid-Integration of Photovoltaic Systems in Germany". IEEE Transactions on Sustainable Energy. 4 (2): 534–542. Bibcode:2013ITSE....4..534S. doi:10.1109/TSTE.2012.2198925. S2CID 47032066.
  94. ^ a b c d Salpakari, Jyri; Lund, Peter (2016). "Optimal and rule-based control strategies for energy flexibility in buildings with PV". Applied Energy. 161: 425–436. Bibcode:2016ApEn..161..425S. doi:10.1016/j.apenergy.2015.10.036. S2CID 59037572.
  95. ^ Fitzgerald, Garrett; Mandel, James; Morris, Jesse; Touati, Hervé (2015). The Economics of Battery Energy Storage (PDF) (Report). Rocky Mountain Institute. Archived from the original (PDF) on 30 November 2016.
  96. ^ "The Value of Electricity Reliability: Evidence from Battery Adoption". Resources for the Future. Retrieved 14 June 2023.
  97. ^ a b "Germany boosts renewables with "biggest energy policy reform in decades"". Clean Energy Wire. 6 April 2022. Retrieved 8 November 2022.
  98. ^ "Indigenizing Solar Manufacturing: Charting the Course to a Solar Self-Sufficient India". www.saurenergy.com. Retrieved 8 November 2022.
  99. ^ "Renewable power incentives".
  100. ^ China Racing Ahead of America in the Drive to Go Solar. Archived 6 July 2013 at the Wayback Machine.
  101. ^ "Power & Energy Technology – IHS Technology". Archived from the original on 2 January 2010.
  102. ^ Shankar, Ravi (20 July 2022). "What is the solar rooftop subsidy scheme/yojana?". The Times of India. Retrieved 8 November 2022.
  103. ^ "Net Metering original on 21 October 2012". dsireusa.org. 16 June 2010. Retrieved 12 October 2021.
  104. ^ "Net Metering and Interconnection – NJ OCE Web Site". Archived from the original on 12 May 2012.
  105. ^ Mentzel, Dashal (25 October 2023). "Partnership brings benefits of community solar to Vernon County". WEAU. Retrieved 22 November 2023.
  106. ^ "Community Solar Basics". Energy.gov. Retrieved 17 September 2021.
  107. ^ Philipp, Jennifer (7 September 2022). "Solar Power in Africa on the Rise". BORGEN. Retrieved 15 September 2022.
  108. ^ Busch, Marc L. (2 September 2022). "The mystery of India's new solar tariffs". The Hill. Retrieved 15 September 2022.
  109. ^ Wright, matthew; Hearps, Patrick; et al. Australian Sustainable Energy: Zero Carbon Australia Stationary Energy Plan Archived 24 November 2015 at the Wayback Machine, Energy Research Institute, University of Melbourne, October 2010, p. 33. Retrieved from BeyondZeroEmissions.org website.
  110. ^ Palgrave, Robert (1 December 2008). "Innovation in CSP". Renewable Energy Focus. 9 (6). Elsevier: 44–49. doi:10.1016/S1755-0084(08)70066-8. Archived from the original on 24 September 2015.
  111. ^ Ray Stern (10 October 2013). "Solana: 10 Facts You Didn't Know About the Concentrated Solar Power Plant Near Gila Bend". Phoenix New Times. Archived from the original on 11 October 2013.
  112. ^ Carr (1976), p. 85.
  113. ^ Ruggles, Tyler H.; Caldeira, Ken (1 January 2022). "Wind and solar generation may reduce the inter-annual variability of peak residual load in certain electricity systems". Applied Energy. 305: 117773. Bibcode:2022ApEn..30517773R. doi:10.1016/j.apenergy.2021.117773. ISSN 0306-2619. S2CID 239113921.
  114. ^ "Advantages of Using Molten Salt". Sandia National Laboratory. Archived from the original on 5 June 2011. Retrieved 29 September 2007.
  115. ^ "PV Systems and Net Metering". Department of Energy (United States). Archived from the original on 4 July 2008. Retrieved 31 July 2008.
  116. ^ Mohanty, Parimita; Muneer, Tariq; Kolhe, Mohan (30 October 2015). Solar Photovoltaic System Applications: A Guidebook for Off-Grid Electrification. Springer. p. 91. ISBN 978-3-319-14663-8. Retrieved 22 August 2022.
  117. ^ Xiao, Weidong (24 July 2017). Photovoltaic Power System: Modeling, Design, and Control. John Wiley & Sons. p. 288. ISBN 978-1-119-28034-7. Retrieved 22 August 2022.
  118. ^ Al-Alawi, Mohammed Khalifa; Cugley, James; Hassanin, Hany (1 December 2022). "Techno-economic feasibility of retired electric-vehicle batteries repurpose/reuse in second-life applications: A systematic review". Energy and Climate Change. 3: 100086. doi:10.1016/j.egycc.2022.100086. ISSN 2666-2787.
  119. ^ Hoppmann, Joern; Volland, Jonas; Schmidt, Tobias S.; Hoffmann, Volker H. (July 2014). "The Economic Viability of Battery Storage for Residential Solar Photovoltaic Systems – A Review and a Simulation Model". ETH Zürich, Harvard University. Archived from the original on 3 April 2015.
  120. ^ Gerdes, Justin. "Solar Energy Storage About To Take Off In Germany and California". Forbes. Archived from the original on 29 July 2017. Retrieved 8 February 2023.
  121. ^ "Tesla launches Powerwall home battery with aim to revolutionize energy consumption". Associated Press. 1 May 2015. Archived from the original on 7 June 2015.
  122. ^ Kaspar, Frank; Borsche, Michael; Pfeifroth, Uwe; Trentmann, Jörg; Drücke, Jaqueline; Becker, Paul (2 July 2019). "A climatological assessment of balancing effects and shortfall risks of photovoltaics and wind energy in Germany and Europe". Advances in Science and Research. 16. Copernicus GmbH: 119–128. Bibcode:2019AdSR...16..119K. doi:10.5194/asr-16-119-2019. S2CID 198316727. Archived from the original on 24 November 2021.
  123. ^ "Pumped Hydro Storage". Electricity Storage Association. Archived from the original on 21 June 2008. Retrieved 31 July 2008.
  124. ^ Parkinson, Giles (23 October 2022). ""We don't need solar technology breakthroughs, we just need connections"". RenewEconomy. Retrieved 8 November 2022.
  125. ^ Vorrath, Sophie (17 October 2022). "MPower gets green light to connect solar battery projects, cash in on negative pricing". RenewEconomy. Retrieved 8 November 2022.
  126. ^ Nyenah, Emmanuel; Sterl, Sebastian; Thiery, Wim (1 May 2022). "Pieces of a puzzle: solar-wind power synergies on seasonal and diurnal timescales tend to be excellent worldwide". Environmental Research Communications. 4 (5): 055011. Bibcode:2022ERCom...4e5011N. doi:10.1088/2515-7620/ac71fb. ISSN 2515-7620. S2CID 249227821.
  127. ^ "Hybrid Wind and Solar Electric Systems". United States Department of Energy. 2 July 2012. Archived from the original on 26 May 2015.
  128. ^ Converse, Alvin O. (2012). "Seasonal Energy Storage in a Renewable Energy System" (PDF). Proceedings of the IEEE. 100 (2): 401–409. doi:10.1109/JPROC.2011.2105231. S2CID 9195655. Archived from the original (PDF) on 8 November 2016. Retrieved 30 April 2018.
  129. ^ "Solar energy and the environment – U.S. Energy Information Administration (EIA)". www.eia.gov. Retrieved 31 May 2023.
  130. ^ Müller, Amelie; Friedrich, Lorenz; Reichel, Christian; Herceg, Sina; Mittag, Max; Neuhaus, Dirk Holger (15 September 2021). "A comparative life cycle assessment of silicon PV modules: Impact of module design, manufacturing location and inventory". Solar Energy Materials and Solar Cells. 230: 111277. doi:10.1016/j.solmat.2021.111277.
  131. ^ a b "Solar power's potential limited unless "you do everything perfectly" says solar scientist". Dezeen. 21 September 2022. Retrieved 15 October 2022.
  132. ^ "Aging Gracefully: How NREL Is Extending the Lifetime of Solar Modules". www.nrel.gov. Retrieved 15 October 2022.
  133. ^ Zhu, Xiaonan; Wang, Shurong; Wang, Lei (April 2022). "Life cycle analysis of greenhouse gas emissions of China's power generation on spatial and temporal scale". Energy Science & Engineering. 10 (4): 1083–1095. Bibcode:2022EneSE..10.1083Z. doi:10.1002/ese3.1100. ISSN 2050-0505. S2CID 247443046.
  134. ^ "Carbon Neutrality in the UNECE Region: Integrated Life-cycle Assessment of Electricity Sources" (PDF). p. 49.
  135. ^ a b "Life Cycle Greenhouse Gas Emissions from Solar Photovoltaics" (PDF).
  136. ^ Mehedi, Tanveer Hassan; Gemechu, Eskinder; Kumar, Amit (15 May 2022). "Life cycle greenhouse gas emissions and energy footprints of utility-scale solar energy systems". Applied Energy. 314: 118918. Bibcode:2022ApEn..31418918M. doi:10.1016/j.apenergy.2022.118918. ISSN 0306-2619. S2CID 247726728.
  137. ^ "Life Cycle Assessment Harmonization". www.nrel.gov. Retrieved 4 December 2021.
  138. ^ a b "How does the land use of different electricity sources compare?". Our World in Data. Retrieved 3 November 2022.
  139. ^ Van Zalk, John; Behrens, Paul (1 December 2018). "The spatial extent of renewable and non-renewable power generation: A review and meta-analysis of power densities and their application in the U.S." Energy Policy. 123: 83–91. Bibcode:2018EnPol.123...83V. doi:10.1016/j.enpol.2018.08.023. hdl:1887/64883. ISSN 0301-4215.
  140. ^ van de Ven, Dirk-Jan; Capellan-Peréz, Iñigo; Arto, Iñaki; Cazcarro, Ignacio; de Castro, Carlos; Patel, Pralit; Gonzalez-Eguino, Mikel (3 February 2021). "The potential land requirements and related land use change emissions of solar energy". Scientific Reports. 11 (1): 2907. Bibcode:2021NatSR..11.2907V. doi:10.1038/s41598-021-82042-5. ISSN 2045-2322. PMC 7859221. PMID 33536519.
  141. ^ Diab, Khaled. "There are grounds for concern about solar power". www.aljazeera.com. Retrieved 15 April 2021.
  142. ^ Staff, Carbon Brief (25 August 2022). "Factcheck: Is solar power a 'threat' to UK farmland?". Carbon Brief. Retrieved 15 September 2022.
  143. ^ Oda, Shoko (21 May 2022). "Electric farms in Japan are using solar power to grow profits and crops". The Japan Times. Retrieved 14 October 2022.
  144. ^ Gerretsen, Isabelle. "The floating solar panels that track the Sun". www.bbc.com. Retrieved 29 November 2022.
  145. ^ Pollard, Jim (29 May 2023). "Wind Power Body Plans to Provide a Third of Japan's Electricity". Asia Financial. Retrieved 31 May 2023.
  146. ^ "Clean power in South Korea" (PDF).
  147. ^ Dunnett, Sebastian; Holland, Robert A.; Taylor, Gail; Eigenbrod, Felix (8 February 2022). "Predicted wind and solar energy expansion has minimal overlap with multiple conservation priorities across global regions". Proceedings of the National Academy of Sciences. 119 (6). Bibcode:2022PNAS..11904764D. doi:10.1073/pnas.2104764119. ISSN 0027-8424. PMC 8832964. PMID 35101973.
  148. ^ Rabaia, Malek Kamal Hussien; Abdelkareem, Mohammad Ali; Sayed, Enas Taha; Elsaid, Khaled; Chae, Kyu-Jung; Wilberforce, Tabbi; Olabi, A. G. (2021). "Environmental impacts of solar energy systems: A review". Science of the Total Environment. 754: 141989. Bibcode:2021ScTEn.75441989R. doi:10.1016/j.scitotenv.2020.141989. ISSN 0048-9697. PMID 32920388. S2CID 221671774.
  149. ^ "Renewable revolution will drive demand for critical minerals". RenewEconomy. 5 May 2021. Retrieved 5 May 2021.
  150. ^ "Clean energy demand for critical minerals set to soar as the world pursues net zero goals – News". IEA. 5 May 2021. Retrieved 5 May 2021.
  151. ^ "Used Solar Panels Are Powering the Developing World". Bloomberg.com. 25 August 2021. Retrieved 15 September 2022.
  152. ^ US EPA, OLEM (23 August 2021). "End-of-Life Solar Panels: Regulations and Management". www.epa.gov. Retrieved 15 September 2022.
  153. ^ "The Proposed Legal Framework On Responsibility Of Producers And..." www.roedl.com. Retrieved 15 September 2022.
  154. ^ Majewski, Peter; Al-shammari, Weam; Dudley, Michael; Jit, Joytishna; Lee, Sang-Heon; Myoung-Kug, Kim; Sung-Jim, Kim (1 February 2021). "Recycling of solar PV panels – product stewardship and regulatory approaches". Energy Policy. 149: 112062. Bibcode:2021EnPol.14912062M. doi:10.1016/j.enpol.2020.112062. ISSN 0301-4215. S2CID 230529644.
  155. ^ Gürtürk, Mert (15 March 2019). "Economic feasibility of solar power plants based on PV module with levelized cost analysis". Energy. 171: 866–878. Bibcode:2019Ene...171..866G. doi:10.1016/j.energy.2019.01.090. ISSN 0360-5442. S2CID 116733543.
  156. ^ Cross, Jamie; Murray, Declan (1 October 2018). "The afterlives of solar power: Waste and repair off the grid in Kenya". Energy Research & Social Science. 44: 100–109. Bibcode:2018ERSS...44..100C. doi:10.1016/j.erss.2018.04.034. ISSN 2214-6296. S2CID 53058260.
  157. ^ Jang, Esther; Barela, Mary Claire; Johnson, Matt; Martinez, Philip; Festin, Cedric; Lynn, Margaret; Dionisio, Josephine; Heimerl, Kurtis (19 April 2018). "Crowdsourcing Rural Network Maintenance and Repair via Network Messaging". Proceedings of the 2018 CHI Conference on Human Factors in Computing Systems. CHI '18. New York, New York, US: Association for Computing Machinery. pp. 1–12. doi:10.1145/3173574.3173641. ISBN 978-1-4503-5620-6. S2CID 4950067.
  158. ^ "The Photovoltaic Heat Island Effect: Larger solar power plants increase local temperatures". Scientific Reports. 6. 13 October 2016. Retrieved 2 September 2024.
  159. ^ "Water consumption solution for efficient concentrated solar power | Research and Innovation". ec.europa.eu. Retrieved 4 December 2021.
  160. ^ Chiu, Allyson; Guskin, Emily; Clement, Scott (3 October 2023). "Americans don't hate living near solar and wind farms as much as you might think". The Washington Post. Archived from the original on 3 October 2023.
  161. ^ "Making solar a source of EU energy security | Think Tank | European Parliament". www.europarl.europa.eu. Retrieved 3 November 2022.
  162. ^ Blunt, Katherine; Dvorak, Phred (9 August 2022). "WSJ News Exclusive | U.S. Solar Shipments Are Hit by Import Ban on China's Xinjiang Region". The Wall Street Journal. ISSN 0099-9660. Retrieved 8 September 2022.
  163. ^ "Fears over China's Muslim forced labor loom over EU solar power". Politico. 10 February 2021. Retrieved 15 April 2021.
  164. ^ "China's solar dominance not an issue". 24 July 2024.

Bibliography

Further reading

  • Sivaram, Varun (2018). Taming the Sun: Innovation to Harness Solar Energy and Power the Planet. Cambridge, Massachusetts: MIT Press. ISBN 978-0-262-03768-6.