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Electricity generation

January 19, 2023

Electricity generation is the process of generating electric power from sources of primary energy. For utilities in the electric power industry, it is the stage prior to its delivery (transmission, distribution, etc.) to end users or its storage (using, for example, the pumped-storage method).

Electricity is not freely available in nature, so it must be "produced" (that is, transforming other forms of energy to electricity). Production is carried out in power stations (also called "power plants"). Electricity is most often generated at a power plant by electromechanical generators, primarily driven by heat engines fueled by combustion or nuclear fission but also by other means such as the kinetic energy of flowing water and wind. Other energy sources include solar photovoltaics and geothermal power. There are also exotic and speculative methods to recover energy, such as proposed fusion reactor designs which aim to directly extract energy from intense magnetic fields generated by fast-moving charged particles generated by the fusion reaction (see magnetohydrodynamics).

Phasing out coal-fired power stations and eventually gas-fired power stations,[1] or capturing their greenhouse gas emissions, is an important part of the energy transformation required to limit climate change. Vastly more solar power[2] and wind power[3] is forecast to be required, with electricity demand increasing strongly[4] with further electrification of transport, homes and industry.[5]

History

 
Past costs of producing renewable energy have declined significantly, with 62% of total renewable power generation added in 2020 having lower costs than the cheapest new fossil fuel option.[6]
 
Levelized cost: With increasingly widespread implementation of renewable energy sources, costs for renewables have declined, most notably for energy generated by solar panels.[7]
Levelized cost of energy (LCOE) is a measure of the average net present cost of electricity generation for a generating plant over its lifetime.
 
Dynamos and engine installed at Edison General Electric Company, New York 1895

The fundamental principles of electricity generation were discovered in the 1820s and early 1830s by British scientist Michael Faraday. His method, still used today, is for electricity to be generated by the movement of a loop of wire, or Faraday disc, between the poles of a magnet. Central power stations became economically practical with the development of alternating current (AC) power transmission, using power transformers to transmit power at high voltage and with low loss.

Commercial electricity production started with the coupling of the dynamo to the hydraulic turbine. The mechanical production of electric power began the Second Industrial Revolution and made possible several inventions using electricity, with the major contributors being Thomas Alva Edison and Nikola Tesla. Previously the only way to produce electricity was by chemical reactions or using battery cells, and the only practical use of electricity was for the telegraph.

Electricity generation at central power stations started in 1882, when a steam engine driving a dynamo at Pearl Street Station produced a DC current that powered public lighting on Pearl Street, New York. The new technology was quickly adopted by many cities around the world, which adapted their gas-fueled street lights to electric power. Soon after electric lights would be used in public buildings, in businesses, and to power public transport, such as trams and trains.

The first power plants used water power or coal.[8] Today a variety of energy sources are used, such as coal, nuclear, natural gas, hydroelectric, wind, and oil, as well as solar energy, tidal power, and geothermal sources.

In the 1880s the popularity of electricity grew massively with the introduction of the Incandescent light bulb. Although there are 22 recognised inventors of the light bulb prior to Joseph Swan and Thomas Edison, Edison and Swan's invention became by far the most successful and popular of all. During the early years of the 19th century, massive jumps in electrical sciences were made. And by the later 19th century the advancement of electrical technology and engineering led to electricity being part of everyday life. With the introduction of many electrical inventions and their implementation into everyday life, the demand for electricity within homes grew dramatically. With this increase in demand, the potential for profit was seen by many entrepreneurs who began investing into electrical systems to eventually create the first electricity public utilities. This process in history is often described as electrification.[9]

The earliest distribution of electricity came from companies operating independently of one another. A consumer would purchase electricity from a producer, and the producer would distribute it through their own power grid. As technology improved so did the productivity and efficiency of its generation. Inventions such as the steam turbine had a massive impact on the efficiency of electrical generation but also the economics of generation as well. This conversion ofheat energy into mechanical work was similar to that of steam engines, however at a significantly larger scale and far more productively. The improvements of these large-scale generation plants were critical to the process of centralised generation as they would become vital to the entire power system that we now use today.

Throughout the middle of the 20th century many utilities began merging their distribution networks due to economic and efficiency benefits. Along with the invention of long-distance power transmission, the coordination of power plants began to form. This system was then secured by regional system operators to ensure stability and reliability. The electrification of homes began in Northern Europe and in the Northern America in the 1920s in large cities and urban areas. It wasn't until the 1930s that rural areas saw the large-scale establishment of electrification.[10]

Methods of generation

2019 world electricity generation by source (total generation was 27 petawatt-hours)[11][12]

  Coal (37%)
  Natural gas (24%)
  Hydro (16%)
  Nuclear (10%)
  Wind (5%)
  Solar (3%)
  Other (5%)

Several fundamental methods exist to convert other forms of energy into electrical energy. Utility-scale generation is achieved by rotating electric generators or by photovoltaic systems. A small proportion of electric power distributed by utilities is provided by batteries. Other forms of electricity generation used in niche applications include the triboelectric effect, the piezoelectric effect, the thermoelectric effect, and betavoltaics.

Generators

Main article: Electric generator
 
Wind turbines usually provide electrical generation in conjunction with other methods of producing power.

Electric generators transform kinetic energy into electricity. This is the most used form for generating electricity and is based on Faraday's law. It can be seen experimentally by rotating a magnet within closed loops of conducting material (e.g. copper wire). Almost all commercial electrical generation is done using electromagnetic induction, in which mechanical energy forces a generator to rotate.

Electrochemistry

 
Large dams, such as Hoover Dam in the United States, can provide large amounts of hydroelectric power. It has an installed capacity of 2.07 GW.

Electrochemistry is the direct transformation of chemical energy into electricity, as in a battery. Electrochemical electricity generation is important in portable and mobile applications. Currently, most electrochemical power comes from batteries.[13] Primary cells, such as the common zinc–carbon batteries, act as power sources directly, but secondary cells (i.e. rechargeable batteries) are used for storage systems rather than primary generation systems. Open electrochemical systems, known as fuel cells, can be used to extract power either from natural fuels or from synthesized fuels. Osmotic power is a possibility at places where salt and fresh water merge.

Photovoltaic effect

The photovoltaic effect is the transformation of light into electrical energy, as in solar cells. Photovoltaic panels convert sunlight directly to DC electricity. Power inverters can then convert that to AC electricity if needed. Although sunlight is free and abundant, solar power electricity is still usually more expensive to produce than large-scale mechanically generated power due to the cost of the panels.[citation needed] Low-efficiency silicon solar cells have been decreasing in cost and multijunction cells with close to 30% conversion efficiency are now commercially available. Over 40% efficiency has been demonstrated in experimental systems.[14] Until recently, photovoltaics were most commonly used in remote sites where there is no access to a commercial power grid, or as a supplemental electricity source for individual homes and businesses. Recent advances in manufacturing efficiency and photovoltaic technology, combined with subsidies driven by environmental concerns, have dramatically accelerated the deployment of solar panels. Installed capacity is growing by around 20% per year[2] led by increases in Germany, Japan, United States, China, and India.

Economics

See also: Cost of electricity by source and Electricity pricing

The selection of electricity production modes and their economic viability varies in accordance with demand and region. The economics vary considerably around the world, resulting in widespread residential selling prices. Hydroelectric plants, nuclear power plants, thermal power plants and renewable sources have their own pros and cons, and selection is based upon the local power requirement and the fluctuations in demand. All power grids have varying loads on them but the daily minimum[citation needed] is the base load, often supplied by plants which run continuously. Nuclear, coal, oil, gas and some hydro plants can supply base load. If well construction costs for natural gas are below $10 per MWh, generating electricity from natural gas is cheaper than generating power by burning coal.[15]

Nuclear power plants can produce a huge amount of power from a single unit. However, nuclear disasters have raised concerns over the safety of nuclear power, and the capital cost of nuclear plants is very high. Hydroelectric power plants are located in areas where the potential energy from falling water can be harnessed for moving turbines and the generation of power. It may not be an economically viable single source of production where the ability to store the flow of water is limited and the load varies too much during the annual production cycle.

Generating equipment

Main article: Electric generator
 
A large generator with the rotor removed

Electric generators were known in simple forms from the discovery of electromagnetic induction in the 1830s. In general, some form of prime mover such as an engine or the turbines described above, drives a rotating magnetic field past stationary coils of wire thereby turning mechanical energy into electricity.[16] The only commercial scale electricity production that does not employ a generator is solar PV.

Turbines

 
Large dams such as Three Gorges Dam in China can provide large amounts of hydroelectric power; it has a 22.5 GW capability.

Almost all commercial electrical power on Earth is generated with a turbine, driven by wind, water, steam or burning gas. The turbine drives a generator, thus transforming its mechanical energy into electrical energy by electromagnetic induction. There are many different methods of developing mechanical energy, including heat engines, hydro, wind and tidal power. Most electric generation is driven by heat engines. The combustion of fossil fuels supplies most of the energy to these engines, with a significant fraction from nuclear fission and some from renewable sources. The modern steam turbine (invented by Sir Charles Parsons in 1884) currently generates about 80% of the electric power in the world using a variety of heat sources. Turbine types include:

  • Steam
  • Natural gas: turbines are driven directly by gases produced by combustion. Combined cycle are driven by both steam and natural gas. They generate power by burning natural gas in a gas turbine and use residual heat to generate steam. At least 20% of the world's electricity is generated by natural gas.
  • Water Energy is captured by a water turbine from the movement of water - from falling water, the rise and fall of tides or ocean thermal currents (see ocean thermal energy conversion). Currently, hydroelectric plants provide approximately 16% of the world's electricity.
  • The windmill was a very early wind turbine. In 2018 around 5% of the world's electricity was produced from wind

Turbines can also use other heat-transfer liquids than steam. Supercritical carbon dioxide based cycles can provide higher conversion efficiency due to faster heat exchange, higher energy density and simpler power cycle infrastructure. Supercritical carbon dioxide blends, that are currently in development, can further increase efficiency by optimizing its critical pressure and temperature points.

Although turbines are most common in commercial power generation, smaller generators can be powered by gasoline or diesel engines. These may used for backup generation or as a prime source of power within isolated villages.

Production

Total worldwide gross production of electricity in 2016 was 25 082 TWh. Sources of electricity were coal and peat 38.3%, natural gas 23.1%, hydroelectric 16.6%, nuclear power 10.4%, oil 3.7%, solar/wind/geothermal/tidal/other 5.6%, biomass and waste 2.3%.[18]

In 2021, Wind and solar generated electricity reached 10% of globally produced electricity. Clean sources (Solar and wind and other) generated 38% of the world's electricity.[19]

 
Energy flow of power plant

Historical results of production of electricity

 [20]

Production by country

Main article: List of countries by electricity production
See also: Electric energy consumption

The United States has long been the largest producer and consumer of electricity, with a global share in 2005 of at least 25%, followed by China, Japan, Russia, and India. In 2011, China overtook the United States to become the largest producer of electricity.

Environmental concerns

Main article: Environmental impact of electricity generation
See also: Global warming and Coal phase out

Variations between countries generating electrical power affect concerns about the environment. In France only 10% of electricity is generated from fossil fuels, the US is higher at 70% and China is at 80%.[21] The cleanliness of electricity depends on its source. Methane leaks (from natural gas to fuel gas-fired power plants)[22] and carbon dioxide emissions from fossil fuel-based electricity generation account for a significant portion of world greenhouse gas emissions.[23] In the United States, fossil fuel combustion for electric power generation is responsible for 65% of all emissions of sulfur dioxide, the main component of acid rain.[24] Electricity generation is the fourth highest combined source of NOx, carbon monoxide, and particulate matter in the US.[25]

According to the International Energy Agency (IEA), low-carbon electricity generation needs to account for 85% of global electrical output by 2040 in order to ward off the worst effects of climate change.[26] Like other organizations including the Energy Impact Center (EIC)[27] and the United Nations Economic Commission for Europe (UNECE),[28] the IEA has called for the expansion of nuclear and renewable energy to meet that objective.[29] Some, like EIC founder Bret Kugelmass, believe that nuclear power is the primary method for decarbonizing electricity generation because it can also power direct air capture that removes existing carbon emissions from the atmosphere.[30] Nuclear power plants can also create district heating and desalination projects, limiting carbon emissions and the need for expanded electrical output.[31]

A fundamental issue regarding centralised generation and the current electrical generation methods in use today is the significant negative environmental effects that many of the generation processes have. Processes such as coal and gas not only release carbon dioxide as they combust, but their extraction from the ground also impacts the environment. Open pit coal mines use large areas of land to extract coal and limit the potential for productive land use after the excavation. Natural gas extraction releases large amounts of methane into the atmosphere when extracted from the ground greatly increase global greenhouse gases. Although nuclear power plants do not release carbon dioxide through electricity generation, there are significant risks associated with nuclear waste and safety concerns associated with the use of nuclear sources. This fear of nuclear power stems from large-scale nuclear catastrophes such as the Chernobyl Disaster and the Fukushima Daiichi nuclear disaster. Both tragedies led to significant casualties and the radioactive contamination of large areas.[32]

Per unit of electricity generated coal and gas-fired power life-cycle greenhouse gas emissions are almost always at least ten times that of other generation methods.[33]

Centralised and distributed generation

Centralised generation is electricity generation by large-scale centralised facilities, sent through transmission lines to consumers. These facilities are usually located far away from consumers and distribute the electricity through high voltage transmission lines to a substation, where it is then distributed to consumers; the basic concept being that multi-megawatt or gigawatt scale large stations create electricity for a large number of people. The vast majority of electricity used is created from centralised generation. Most centralised power generation comes from large power plants run by fossil fuels such as coal or natural gas, though nuclear or large hydroelectricity plants are also commonly used.[34] Centralised generation is fundamentally the opposite of distributed generation. Distributed generation is the small-scale generation of electricity to smaller groups of consumers. This can also include independently producing electricity by either solar or wind power. In recent years distributed generation as has seen a spark in popularity due to its propensity to use renewable energy generation methods such as rooftop solar.[35]

Technologies

Centralised energy sources are large power plants that produce huge amounts of electricity to a large number of consumers. Most power plants used in centralised generation are thermal power plants meaning that they use a fuel to heat steam to produce a pressurised gas which in turn spins a turbine and generates electricity. This is the traditional way of producing energy. This process relies on several forms of technology to produce widespread electricity, these being natural coal, gas and nuclear forms of thermal generation. More recently solar and wind have become large scale.

Solar

This section is an excerpt from Photovoltaic power station.[edit]
 
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 decentralised solar power because they supply power at the utility level, rather than to a local user or users. The generic expression utility-scale solar is sometimes used to describe this type of project.

The solar power source is solar panels that convert light directly to electricity. However, this differs from and should not be confused with 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.[36][37]

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.[36]

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.[38] 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.

Wind

This section is an excerpt from Wind farm.[edit]
 
The San Gorgonio Pass wind farm in California, United States.
 
The Gansu Wind Farm in China is the largest wind farm in the world, with a target capacity of 20,000 MW by 2020.

A wind farm or wind park, also called a wind power station or wind power plant,[39] is a group of wind turbines in the same location used to produce electricity. Wind farms vary in size from a small number of turbines to several hundred wind turbines covering an extensive area. Wind farms can be either onshore or offshore.

Many of the largest operational onshore wind farms are located in China, India, and the United States. For example, the largest wind farm in the world, Gansu Wind Farm in China had a capacity of over 6,000 MW by 2012,[40] with a goal of 20,000 MW[41] by 2020.[42] As of December 2020, the 1218 MW Hornsea Wind Farm in the UK is the largest offshore wind farm in the world.[43] Individual wind turbine designs continue to increase in power, resulting in fewer turbines being needed for the same total output.

Because they require no fuel, wind farms have less impact on the environment than many other forms of power generation and are often referred to as a good source of green energy. Wind farms have, however, been criticised for their visual impact and impact on the landscape. Typically they need to be spread over more land than other power stations and need to be built in wild and rural areas, which can lead to "industrialization of the countryside", habitat loss, and a drop in tourism. Some critics claim that wind farms have adverse health effects, but most researchers consider these claims to be pseudoscience (see wind turbine syndrome). Wind farms can interfere with radar, although in most cases, according to the US Department of Energy, "siting and other mitigations have resolved conflicts and allowed wind projects to co-exist effectively with radar".[44]

Coal

This section is an excerpt from Coal-fired power station.[edit]
 
Coal-fired power station diagram
 
Share of electricity production from coal

A coal-fired power station or coal power plant is a thermal power station which burns coal to generate electricity. Worldwide there are over 2,400 coal-fired power stations, totaling over 2,000 gigawatts capacity.[45] They generate about a third of the world's electricity,[46] but cause many illnesses and the most early deaths,[47] mainly from air pollution.[48][49]

A coal-fired power station is a type of fossil fuel power station. The coal is usually pulverized and then burned in a pulverized coal-fired boiler. The furnace heat converts boiler water to steam, which is then used to spin turbines that turn generators. Thus chemical energy stored in coal is converted successively into thermal energy, mechanical energy and, finally, electrical energy.

Coal-fired power stations emit over 10 Gt of carbon dioxide each year,[50] about one fifth of world greenhouse gas emissions, so are the single largest cause of climate change.[51] More than half of all the coal-fired electricity in the world is generated in China.[52] In 2020 the total number of plants started falling[53][54] as they are being retired in Europe[55] and America[56] although still being built in Asia, almost all in China.[57] Some remain profitable because costs to other people due to the health and environmental impact of the coal industry are not priced into the cost of generation,[58][59] but there is the risk newer plants may become stranded assets.[60] The UN Secretary General has said that OECD countries should stop generating electricity from coal by 2030, and the rest of the world by 2040.[61]

Natural gas

Natural gas is ignited to create pressurised gas which is used to spin turbines to generate electricity. Natural gas plants use a gas turbine where natural gas is added along with oxygen which in turn combusts and expands through the turbine to force a generator to spin.

Natural gas power plants are more efficient than coal power generation, they however contribute to climate change but not as highly as coal generation. Not only do they produce carbon dioxide from the ignition of natural gas, but also the extraction of gas when mined releases a significant amount of methane into the atmosphere.[62]

Nuclear

Nuclear power plants create electricity through steam turbines where the heat input is from the process of nuclear fission. Currently, nuclear power produces 11% of all electricity in the world. Most nuclear reactors use uranium as a source of fuel. In a process called nuclear fission, energy, in the form of heat, is released when nuclear atoms are split. Electricity is created through the use of a nuclear reactor where heat produced by nuclear fission is used to produce steam which in turn spins turbines and powers the generators. Although there are several types of nuclear reactors, all fundamentally use this process.[63]

Normal emissions due to nuclear power plants are primarily waste heat and radioactive spent fuel. In a reactor accident, significant amounts of radioisotopes can be released to the environment, posing a long term hazard to life. This hazard has been a continuing concern of environmentalists. Accidents such as the Three Mile Island accident, Chernobyl disaster and the Fukushima nuclear disaster illustrate this problem. [64]

See also

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January 19, 2023
electricity, generation, process, generating, electric, power, from, sources, primary, energy, utilities, electric, power, industry, stage, prior, delivery, transmission, distribution, users, storage, using, example, pumped, storage, method, turbo, generator, . Electricity generation is the process of generating electric power from sources of primary energy For utilities in the electric power industry it is the stage prior to its delivery transmission distribution etc to end users or its storage using for example the pumped storage method Turbo generator Electricity is not freely available in nature so it must be produced that is transforming other forms of energy to electricity Production is carried out in power stations also called power plants Electricity is most often generated at a power plant by electromechanical generators primarily driven by heat engines fueled by combustion or nuclear fission but also by other means such as the kinetic energy of flowing water and wind Other energy sources include solar photovoltaics and geothermal power There are also exotic and speculative methods to recover energy such as proposed fusion reactor designs which aim to directly extract energy from intense magnetic fields generated by fast moving charged particles generated by the fusion reaction see magnetohydrodynamics Phasing out coal fired power stations and eventually gas fired power stations 1 or capturing their greenhouse gas emissions is an important part of the energy transformation required to limit climate change Vastly more solar power 2 and wind power 3 is forecast to be required with electricity demand increasing strongly 4 with further electrification of transport homes and industry 5 Contents 1 History 2 Methods of generation 2 1 Generators 2 2 Electrochemistry 2 3 Photovoltaic effect 3 Economics 4 Generating equipment 4 1 Turbines 5 Production 5 1 Historical results of production of electricity 5 2 Production by country 6 Environmental concerns 7 Centralised and distributed generation 8 Technologies 8 1 Solar 8 2 Wind 8 3 Coal 8 4 Natural gas 8 5 Nuclear 9 See also 10 ReferencesHistory Edit Past costs of producing renewable energy have declined significantly with 62 of total renewable power generation added in 2020 having lower costs than the cheapest new fossil fuel option 6 Levelized cost With increasingly widespread implementation of renewable energy sources costs for renewables have declined most notably for energy generated by solar panels 7 Levelized cost of energy LCOE is a measure of the average net present cost of electricity generation for a generating plant over its lifetime Dynamos and engine installed at Edison General Electric Company New York 1895 The fundamental principles of electricity generation were discovered in the 1820s and early 1830s by British scientist Michael Faraday His method still used today is for electricity to be generated by the movement of a loop of wire or Faraday disc between the poles of a magnet Central power stations became economically practical with the development of alternating current AC power transmission using power transformers to transmit power at high voltage and with low loss Commercial electricity production started with the coupling of the dynamo to the hydraulic turbine The mechanical production of electric power began the Second Industrial Revolution and made possible several inventions using electricity with the major contributors being Thomas Alva Edison and Nikola Tesla Previously the only way to produce electricity was by chemical reactions or using battery cells and the only practical use of electricity was for the telegraph Electricity generation at central power stations started in 1882 when a steam engine driving a dynamo at Pearl Street Station produced a DC current that powered public lighting on Pearl Street New York The new technology was quickly adopted by many cities around the world which adapted their gas fueled street lights to electric power Soon after electric lights would be used in public buildings in businesses and to power public transport such as trams and trains The first power plants used water power or coal 8 Today a variety of energy sources are used such as coal nuclear natural gas hydroelectric wind and oil as well as solar energy tidal power and geothermal sources In the 1880s the popularity of electricity grew massively with the introduction of the Incandescent light bulb Although there are 22 recognised inventors of the light bulb prior to Joseph Swan and Thomas Edison Edison and Swan s invention became by far the most successful and popular of all During the early years of the 19th century massive jumps in electrical sciences were made And by the later 19th century the advancement of electrical technology and engineering led to electricity being part of everyday life With the introduction of many electrical inventions and their implementation into everyday life the demand for electricity within homes grew dramatically With this increase in demand the potential for profit was seen by many entrepreneurs who began investing into electrical systems to eventually create the first electricity public utilities This process in history is often described as electrification 9 The earliest distribution of electricity came from companies operating independently of one another A consumer would purchase electricity from a producer and the producer would distribute it through their own power grid As technology improved so did the productivity and efficiency of its generation Inventions such as the steam turbine had a massive impact on the efficiency of electrical generation but also the economics of generation as well This conversion ofheat energy into mechanical work was similar to that of steam engines however at a significantly larger scale and far more productively The improvements of these large scale generation plants were critical to the process of centralised generation as they would become vital to the entire power system that we now use today Throughout the middle of the 20th century many utilities began merging their distribution networks due to economic and efficiency benefits Along with the invention of long distance power transmission the coordination of power plants began to form This system was then secured by regional system operators to ensure stability and reliability The electrification of homes began in Northern Europe and in the Northern America in the 1920s in large cities and urban areas It wasn t until the 1930s that rural areas saw the large scale establishment of electrification 10 Methods of generation Edit2019 world electricity generation by source total generation was 27 petawatt hours 11 12 Coal 37 Natural gas 24 Hydro 16 Nuclear 10 Wind 5 Solar 3 Other 5 Several fundamental methods exist to convert other forms of energy into electrical energy Utility scale generation is achieved by rotating electric generators or by photovoltaic systems A small proportion of electric power distributed by utilities is provided by batteries Other forms of electricity generation used in niche applications include the triboelectric effect the piezoelectric effect the thermoelectric effect and betavoltaics Generators Edit Main article Electric generator Wind turbines usually provide electrical generation in conjunction with other methods of producing power Electric generators transform kinetic energy into electricity This is the most used form for generating electricity and is based on Faraday s law It can be seen experimentally by rotating a magnet within closed loops of conducting material e g copper wire Almost all commercial electrical generation is done using electromagnetic induction in which mechanical energy forces a generator to rotate Electrochemistry Edit Large dams such as Hoover Dam in the United States can provide large amounts of hydroelectric power It has an installed capacity of 2 07 GW Electrochemistry is the direct transformation of chemical energy into electricity as in a battery Electrochemical electricity generation is important in portable and mobile applications Currently most electrochemical power comes from batteries 13 Primary cells such as the common zinc carbon batteries act as power sources directly but secondary cells i e rechargeable batteries are used for storage systems rather than primary generation systems Open electrochemical systems known as fuel cells can be used to extract power either from natural fuels or from synthesized fuels Osmotic power is a possibility at places where salt and fresh water merge Photovoltaic effect Edit The photovoltaic effect is the transformation of light into electrical energy as in solar cells Photovoltaic panels convert sunlight directly to DC electricity Power inverters can then convert that to AC electricity if needed Although sunlight is free and abundant solar power electricity is still usually more expensive to produce than large scale mechanically generated power due to the cost of the panels citation needed Low efficiency silicon solar cells have been decreasing in cost and multijunction cells with close to 30 conversion efficiency are now commercially available Over 40 efficiency has been demonstrated in experimental systems 14 Until recently photovoltaics were most commonly used in remote sites where there is no access to a commercial power grid or as a supplemental electricity source for individual homes and businesses Recent advances in manufacturing efficiency and photovoltaic technology combined with subsidies driven by environmental concerns have dramatically accelerated the deployment of solar panels Installed capacity is growing by around 20 per year 2 led by increases in Germany Japan United States China and India Economics EditSee also Cost of electricity by source and Electricity pricing The selection of electricity production modes and their economic viability varies in accordance with demand and region The economics vary considerably around the world resulting in widespread residential selling prices Hydroelectric plants nuclear power plants thermal power plants and renewable sources have their own pros and cons and selection is based upon the local power requirement and the fluctuations in demand All power grids have varying loads on them but the daily minimum citation needed is the base load often supplied by plants which run continuously Nuclear coal oil gas and some hydro plants can supply base load If well construction costs for natural gas are below 10 per MWh generating electricity from natural gas is cheaper than generating power by burning coal 15 Nuclear power plants can produce a huge amount of power from a single unit However nuclear disasters have raised concerns over the safety of nuclear power and the capital cost of nuclear plants is very high Hydroelectric power plants are located in areas where the potential energy from falling water can be harnessed for moving turbines and the generation of power It may not be an economically viable single source of production where the ability to store the flow of water is limited and the load varies too much during the annual production cycle Generating equipment EditMain article Electric generator A large generator with the rotor removed Electric generators were known in simple forms from the discovery of electromagnetic induction in the 1830s In general some form of prime mover such as an engine or the turbines described above drives a rotating magnetic field past stationary coils of wire thereby turning mechanical energy into electricity 16 The only commercial scale electricity production that does not employ a generator is solar PV Turbines Edit Large dams such as Three Gorges Dam in China can provide large amounts of hydroelectric power it has a 22 5 GW capability Almost all commercial electrical power on Earth is generated with a turbine driven by wind water steam or burning gas The turbine drives a generator thus transforming its mechanical energy into electrical energy by electromagnetic induction There are many different methods of developing mechanical energy including heat engines hydro wind and tidal power Most electric generation is driven by heat engines The combustion of fossil fuels supplies most of the energy to these engines with a significant fraction from nuclear fission and some from renewable sources The modern steam turbine invented by Sir Charles Parsons in 1884 currently generates about 80 of the electric power in the world using a variety of heat sources Turbine types include Steam Water is boiled by coal burned in a thermal power plant About 41 of all electricity is generated this way 17 Nuclear fission heat created in a nuclear reactor creates steam Less than 15 of electricity is generated this way Renewable energy The steam is generated by biomass solar thermal energy or geothermal power Natural gas turbines are driven directly by gases produced by combustion Combined cycle are driven by both steam and natural gas They generate power by burning natural gas in a gas turbine and use residual heat to generate steam At least 20 of the world s electricity is generated by natural gas Water Energy is captured by a water turbine from the movement of water from falling water the rise and fall of tides or ocean thermal currents see ocean thermal energy conversion Currently hydroelectric plants provide approximately 16 of the world s electricity The windmill was a very early wind turbine In 2018 around 5 of the world s electricity was produced from windTurbines can also use other heat transfer liquids than steam Supercritical carbon dioxide based cycles can provide higher conversion efficiency due to faster heat exchange higher energy density and simpler power cycle infrastructure Supercritical carbon dioxide blends that are currently in development can further increase efficiency by optimizing its critical pressure and temperature points Although turbines are most common in commercial power generation smaller generators can be powered by gasoline or diesel engines These may used for backup generation or as a prime source of power within isolated villages Production EditThis section needs to be updated Please help update this article to reflect recent events or newly available information March 2015 Total worldwide gross production of electricity in 2016 was 25 082 TWh Sources of electricity were coal and peat 38 3 natural gas 23 1 hydroelectric 16 6 nuclear power 10 4 oil 3 7 solar wind geothermal tidal other 5 6 biomass and waste 2 3 18 In 2021 Wind and solar generated electricity reached 10 of globally produced electricity Clean sources Solar and wind and other generated 38 of the world s electricity 19 Energy flow of power plant Historical results of production of electricity Edit 20 Production by country Edit Main article List of countries by electricity production See also Electric energy consumption The United States has long been the largest producer and consumer of electricity with a global share in 2005 of at least 25 followed by China Japan Russia and India In 2011 China overtook the United States to become the largest producer of electricity Environmental concerns EditMain article Environmental impact of electricity generation See also Global warming and Coal phase out Variations between countries generating electrical power affect concerns about the environment In France only 10 of electricity is generated from fossil fuels the US is higher at 70 and China is at 80 21 The cleanliness of electricity depends on its source Methane leaks from natural gas to fuel gas fired power plants 22 and carbon dioxide emissions from fossil fuel based electricity generation account for a significant portion of world greenhouse gas emissions 23 In the United States fossil fuel combustion for electric power generation is responsible for 65 of all emissions of sulfur dioxide the main component of acid rain 24 Electricity generation is the fourth highest combined source of NOx carbon monoxide and particulate matter in the US 25 According to the International Energy Agency IEA low carbon electricity generation needs to account for 85 of global electrical output by 2040 in order to ward off the worst effects of climate change 26 Like other organizations including the Energy Impact Center EIC 27 and the United Nations Economic Commission for Europe UNECE 28 the IEA has called for the expansion of nuclear and renewable energy to meet that objective 29 Some like EIC founder Bret Kugelmass believe that nuclear power is the primary method for decarbonizing electricity generation because it can also power direct air capture that removes existing carbon emissions from the atmosphere 30 Nuclear power plants can also create district heating and desalination projects limiting carbon emissions and the need for expanded electrical output 31 A fundamental issue regarding centralised generation and the current electrical generation methods in use today is the significant negative environmental effects that many of the generation processes have Processes such as coal and gas not only release carbon dioxide as they combust but their extraction from the ground also impacts the environment Open pit coal mines use large areas of land to extract coal and limit the potential for productive land use after the excavation Natural gas extraction releases large amounts of methane into the atmosphere when extracted from the ground greatly increase global greenhouse gases Although nuclear power plants do not release carbon dioxide through electricity generation there are significant risks associated with nuclear waste and safety concerns associated with the use of nuclear sources This fear of nuclear power stems from large scale nuclear catastrophes such as the Chernobyl Disaster and the Fukushima Daiichi nuclear disaster Both tragedies led to significant casualties and the radioactive contamination of large areas 32 Per unit of electricity generated coal and gas fired power life cycle greenhouse gas emissions are almost always at least ten times that of other generation methods 33 Centralised and distributed generation EditCentralised generation is electricity generation by large scale centralised facilities sent through transmission lines to consumers These facilities are usually located far away from consumers and distribute the electricity through high voltage transmission lines to a substation where it is then distributed to consumers the basic concept being that multi megawatt or gigawatt scale large stations create electricity for a large number of people The vast majority of electricity used is created from centralised generation Most centralised power generation comes from large power plants run by fossil fuels such as coal or natural gas though nuclear or large hydroelectricity plants are also commonly used 34 Centralised generation is fundamentally the opposite of distributed generation Distributed generation is the small scale generation of electricity to smaller groups of consumers This can also include independently producing electricity by either solar or wind power In recent years distributed generation as has seen a spark in popularity due to its propensity to use renewable energy generation methods such as rooftop solar 35 Technologies EditCentralised energy sources are large power plants that produce huge amounts of electricity to a large number of consumers Most power plants used in centralised generation are thermal power plants meaning that they use a fuel to heat steam to produce a pressurised gas which in turn spins a turbine and generates electricity This is the traditional way of producing energy This process relies on several forms of technology to produce widespread electricity these being natural coal gas and nuclear forms of thermal generation More recently solar and wind have become large scale Solar Edit This section is an excerpt from Photovoltaic power station edit The 40 5 MW Jannersdorf 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 decentralised solar power because they supply power at the utility level rather than to a local user or users The generic expression utility scale solar is sometimes used to describe this type of project The solar power source is solar panels that convert light directly to electricity However this differs from and should not be confused with 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 update about 97 of utility scale solar power capacity was PV 36 37 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 36 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 38 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 Wind Edit This section is an excerpt from Wind farm edit The San Gorgonio Pass wind farm in California United States The Gansu Wind Farm in China is the largest wind farm in the world with a target capacity of 20 000 MW by 2020 A wind farm or wind park also called a wind power station or wind power plant 39 is a group of wind turbines in the same location used to produce electricity Wind farms vary in size from a small number of turbines to several hundred wind turbines covering an extensive area Wind farms can be either onshore or offshore Many of the largest operational onshore wind farms are located in China India and the United States For example the largest wind farm in the world Gansu Wind Farm in China had a capacity of over 6 000 MW by 2012 40 with a goal of 20 000 MW 41 by 2020 42 As of December 2020 the 1218 MW Hornsea Wind Farm in the UK is the largest offshore wind farm in the world 43 Individual wind turbine designs continue to increase in power resulting in fewer turbines being needed for the same total output Because they require no fuel wind farms have less impact on the environment than many other forms of power generation and are often referred to as a good source of green energy Wind farms have however been criticised for their visual impact and impact on the landscape Typically they need to be spread over more land than other power stations and need to be built in wild and rural areas which can lead to industrialization of the countryside habitat loss and a drop in tourism Some critics claim that wind farms have adverse health effects but most researchers consider these claims to be pseudoscience see wind turbine syndrome Wind farms can interfere with radar although in most cases according to the US Department of Energy siting and other mitigations have resolved conflicts and allowed wind projects to co exist effectively with radar 44 Coal Edit This section is an excerpt from Coal fired power station edit Belchatow Power Station in Belchatow Poland Frimmersdorf Power Station in Grevenbroich Germany Coal fired power station diagram Share of electricity production from coal A coal fired power station or coal power plant is a thermal power station which burns coal to generate electricity Worldwide there are over 2 400 coal fired power stations totaling over 2 000 gigawatts capacity 45 They generate about a third of the world s electricity 46 but cause many illnesses and the most early deaths 47 mainly from air pollution 48 49 A coal fired power station is a type of fossil fuel power station The coal is usually pulverized and then burned in a pulverized coal fired boiler The furnace heat converts boiler water to steam which is then used to spin turbines that turn generators Thus chemical energy stored in coal is converted successively into thermal energy mechanical energy and finally electrical energy Coal fired power stations emit over 10 Gt of carbon dioxide each year 50 about one fifth of world greenhouse gas emissions so are the single largest cause of climate change 51 More than half of all the coal fired electricity in the world is generated in China 52 In 2020 the total number of plants started falling 53 54 as they are being retired in Europe 55 and America 56 although still being built in Asia almost all in China 57 Some remain profitable because costs to other people due to the health and environmental impact of the coal industry are not priced into the cost of generation 58 59 but there is the risk newer plants may become stranded assets 60 The UN Secretary General has said that OECD countries should stop generating electricity from coal by 2030 and the rest of the world by 2040 61 Natural gas Edit Natural gas is ignited to create pressurised gas which is used to spin turbines to generate electricity Natural gas plants use a gas turbine where natural gas is added along with oxygen which in turn combusts and expands through the turbine to force a generator to spin Natural gas power plants are more efficient than coal power generation they however contribute to climate change but not as highly as coal generation Not only do they produce carbon dioxide from the ignition of natural gas but also the extraction of gas when mined releases a significant amount of methane into the atmosphere 62 Nuclear Edit Nuclear power plants create electricity through steam turbines where the heat input is from the process of nuclear fission Currently nuclear power produces 11 of all electricity in the world Most nuclear reactors use uranium as a source of fuel In a process called nuclear fission energy in the form of heat is released when nuclear atoms are split Electricity is created through the use of a nuclear reactor where heat produced by nuclear fission is used to produce steam which in turn spins turbines and powers the generators Although there are several types of nuclear reactors all fundamentally use this process 63 Normal emissions due to nuclear power plants are primarily waste heat and radioactive spent fuel In a reactor accident significant amounts of radioisotopes can be released to the environment posing a long term hazard to life This hazard has been a continuing concern of environmentalists Accidents such as the Three Mile Island accident Chernobyl disaster and the Fukushima nuclear disaster illustrate this problem 64 See also Edit Energy portal Renewable energy portal Engineering portalCogeneration the use of a heat engine or power station to generate electricity and useful heat at the same time Cost of electricity by source Diesel generator Electric generator Engine generator Electric power transmission World energy consumption the total energy used by all of human civilization Electrification Nuclear fission Generation expansion planning Distributed generation Power stationReferences Edit Chestney Nina 2021 05 14 Factbox Getting out of gas the sold and scrapped projects Reuters Retrieved 2021 11 27 a b Solar PV Analysis IEA Retrieved 2021 11 27 What would a world powered entirely by offshore wind look like The Economist 2021 11 04 ISSN 0013 0613 Retrieved 2021 11 27 Electricity Global Energy Review 2021 Analysis IEA Retrieved 2021 11 27 SelectScience Accelerated renewables based electrification for the future www selectscience net Retrieved 2021 11 27 Majority of New Renewables Undercut Cheapest Fossil Fuel on Cost IRENA org International Renewable Energy Agency 22 June 2021 Archived from the original on 22 June 2021 Infographic with numerical data and archive thereof Chrobak Ula 28 January 2021 Solar power got cheap So why aren t we using it more Popular Science Infographic by Sara Chodosh Archived from the original on 29 January 2021 Chodosh s graphic is derived from data in Lazard s Levelized Cost of Energy Version 14 0 PDF Lazard com Lazard 19 October 2020 Archived PDF from the original on 28 January 2021 Pearl Street Station Engineering and Technology History Wiki ethw org Retrieved 2016 08 14 History of Electrification Sites 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Retrieved November 23 2021 Takahashi Dean February 25 2020 Last Energy raises 3 million to fight climate change with nuclear energy VentureBeat Retrieved November 23 2021 Global climate objectives fall short without nuclear power in the mix UNECE United Nations Economic Commission for Europe August 11 2021 Retrieved November 23 2021 Chestney Nina May 18 2021 End new oil gas and coal funding to reach net zero says IEA Reuters Retrieved November 23 2021 Kugelmass Bret January 22 2020 Want to stop climate change Embrace the nuclear option USA Today Retrieved November 23 2021 Patel Sonal November 1 2021 How an AP1000 Plant Is Changing the Nuclear Power Paradigm Through District Heating Desalination Power Magazine Retrieved November 23 2021 The Worst Nuclear Disasters of All Time WorldAtlas 13 September 2018 Retrieved 8 June 2019 Scarlat Nicolae Prussi Matteo Padella Monica 2022 01 01 Quantification of the carbon intensity of electricity produced and used in Europe Applied Energy 305 117901 doi 10 1016 j apenergy 2021 117901 ISSN 0306 2619 S2CID 244177261 US EPA OAR 4 August 2015 Centralized Generation of Electricity and its Impacts on the Environment US EPA Retrieved 21 May 2019 Joshi Siddharth Mittal Shivika Holloway Paul Shukla Priyadarshi Ramprasad o Gallachoir Brian Glynn James 2021 10 05 High resolution global spatiotemporal assessment of rooftop solar photovoltaics potential for renewable electricity generation Nature Communications 12 1 5738 Bibcode 2021NatCo 12 5738J doi 10 1038 s41467 021 25720 2 ISSN 2041 1723 PMC 8492708 PMID 34611151 a b Wolfe Philip 17 March 2020 Utility scale solar sets new record PDF Wiki Solar Retrieved 11 May 2010 Concentrated solar power had a global total installed capacity of 6 451 MW in 2019 HelioCSP 2 February 2020 Retrieved 11 May 2020 Expanding Renewable Energy in Pakistan s Electricity Mix World Bank Retrieved 2022 07 17 Robert Gasch Jochen Twele editors Wind Power Plants Fundamentals Design Construction and Operation Springer 2011 p 11 Watts Jonathan amp Huang Cecily Winds Of Change Blow Through China As Spending On Renewable Energy Soars The Guardian 19 March 2012 revised on 20 March 2012 Retrieved 4 January 2012 Fahey Jonathan In Pictures The World s Biggest Green Energy Projects Forbes 9 January 2010 Retrieved 19 June 2019 Kanter Doug Gansu Wind Farm Forbes Retrieved 19 June 2019 World s largest offshore wind farm fully up and running offshorewind biz 30 January 2020 Retrieved 27 December 2020 WINDExchange Wind Turbine Radar Interference WINDExchange Retrieved 19 June 2019 Too many new coal fired plants planned for 1 5C climate goal report concludes the Guardian 2022 04 26 Retrieved 2022 12 26 Birol Fatih Malpass David It s critical to tackle coal emissions Analysis International Energy Agency Retrieved 9 October 2021 How safe is nuclear energy The Economist ISSN 0013 0613 Retrieved 2022 12 26 Cropper Maureen Cui Ryna Guttikunda Sarath Hultman Nate Jawahar Puja Park Yongjoon Yao Xinlu Song Xiao Peng 2 February 2021 The mortality impacts of current and planned coal fired power plants in India Proceedings of the National Academy of Sciences 118 5 Bibcode 2021PNAS 11817936C doi 10 1073 pnas 2017936118 ISSN 0027 8424 PMC 7865184 PMID 33495332 Killed by coal Air pollution deaths in Jakarta may double by 2030 The Jakarta Post Retrieved 8 April 2022 CO2 emissions Global Energy Review 2021 Analysis IEA Retrieved 7 July 2021 It s critical to tackle coal emissions Analysis IEA Retrieved 9 October 2021 China generated over half world s coal fired power in 2020 study Reuters 28 March 2021 Retrieved 14 September 2021 China generated 53 of the world s total coal fired power in 2020 nine percentage points more that five years earlier Morton Adam 3 August 2020 More coal power generation closed than opened around the world this year research finds The Guardian ISSN 0261 3077 Retrieved 4 August 2020 The dirtiest fossil fuel is on the back foot The Economist 3 December 2020 ISSN 0013 0613 Retrieved 12 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power plant Energy Education energyeducation ca Retrieved 8 June 2019 Nuclear power Energy Education energyeducation ca Retrieved 8 June 2019 Nuclear Power and the Environment Energy Explained Your Guide To Understanding Energy Energy Information Administration www eia gov Retrieved 8 June 2019 Retrieved from https en wikipedia org w index php title Electricity generation amp oldid 1132935835, wikipedia, wiki, book, books, library,

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