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Saturday, August 7, 2021

Sustainable energy

From Wikipedia, the free encyclopedia

Sustainable energy involves increasing production of renewable energy, making safe energy universally available, and energy conservation. Clockwise from top left: Concentrated solar power with molten salt heat storage in Spain, wind energy in South Africa, clean cooking in Ethiopia, public transport in Singapore

The use of energy is considered sustainable if it meets the needs of the present without compromising the needs of future generations. Definitions of sustainable energy typically include environmental aspects such as greenhouse gas emissions, and social and economic aspects such as energy poverty.

Meeting the world's need for energy in a sustainable way is one of the greatest challenges facing humanity in the 21st century. The global energy system, which is 85% based on fossil fuels, is responsible for over 70% of the greenhouse gas emissions that cause climate change. Burning fossil fuels and biomass is a major contributor to air pollution, which causes an estimated 7 million deaths each year. More than 750 million people lack access to electricity and over 2.6 billion rely on polluting fuels such as wood or charcoal to cook.

Renewable energy sources such as wind, hydroelectric power, solar, and geothermal energy are generally far more sustainable than fossil fuel sources. However, some renewable energy projects, such as the clearing of forests to produce biofuels, can cause severe environmental damage. The role of non-renewable energy sources has been controversial. For example, nuclear power is a low-carbon source and has a safety record comparable to wind and solar, but its sustainability has been debated because of concerns about nuclear proliferation, radioactive waste and accidents. Switching from coal to natural gas has environmental benefits but may lead to a delay in switching to more sustainable options. Carbon capture and storage technology can be built into power plants to remove their carbon dioxide emissions but is expensive and has seldom been implemented.

Reducing greenhouse gas emissions to levels consistent with the Paris Agreement will require a system-wide transformation of the way energy is produced, distributed, stored, and consumed. To accommodate larger shares of variable renewable energy, electrical grids require flexibility through infrastructure such as energy storage. A sustainable energy system is likely to see a shift towards far more electricity use in sectors such as transport and heating, energy conservation, and the use of hydrogen produced from low-emission energy sources. Some critical technologies for eliminating energy-related greenhouse gas emissions are not yet mature.

Wind and solar energy sources generated 8.5% of worldwide electricity in 2019, a share that has grown rapidly while costs have fallen and are projected to continue falling. The IPCC estimates that to limit global warming to 1.5 °C, US$2.4 trillion, equivalent to 2.5 percent of world GDP, would need to be invested in the energy system each year between 2016 and 2035. Pathways exist to provide universal access to electricity and clean cooking technologies in ways that are compatible with climate goals while bringing major health and economic benefits to developing countries. Well-designed government policies that promote energy system transformation can lower greenhouse gas emissions and improve air quality simultaneously, and in many cases can also increase energy security. Policy approaches can include carbon-pricing and energy-specific policies such as renewable portfolio standards and phase-outs of fossil fuel subsidies.

Definitions and background

"Energy is the golden thread that connects economic growth, increased social equity, and an environment that allows the world to thrive. Development is not possible without energy, and sustainable development is not possible without sustainable energy."

UN Secretary-General Ban Ki-moon

Definitions

The United Nations Brundtland Commission in its 1987 report, Our Common Future, described the concept of sustainable development, for which energy is a key component. It defined sustainable development as development that "meets the needs of the present without compromising the ability of future generations to meet their own needs". This description of sustainable development has since been referenced in many definitions and explanations of sustainable energy.

No single interpretation of how the concept of sustainability applies to energy has gained worldwide acceptance. Working definitions of sustainable energy encompass multiple dimensions of sustainability, such as environmental, economic, and social dimensions.

The environmental dimension includes greenhouse gas emissions, impacts on biodiversity and ecosystems, the production of hazardous waste and toxic emissions, water consumption, and depletion of non-renewable resources. Energy sources with low environmental impact are sometimes referred to as 'green energy' or 'clean energy'. Definitions of sustainable energy also cover social issues such as having reliable energy be affordable for all people, and economic issues such as energy security to ensure that each country has constant access to sufficient energy.

Sustainable development goals

Meeting the world's need for energy in a sustainable way is one of the greatest challenges facing humanity in the 21st century, both to meet the needs of the present and in terms of effects on future generations. Improving energy access in the least-developed countries and making energy cleaner are key to achieving most of the United Nations 2030 Sustainable Development Goals, which cover issues ranging from climate action to gender equality. Sustainable Development Goal 7 calls for "access to affordable, reliable, sustainable and modern energy for all" by 2030.

Environmental issues

Graph showing growth of energy technologies. Coal shrank lightly between 2014 and 2019, whereas oil and gas grew. Nuclear and hydro had a slow growth, in contrast to other renewables.
The use of modern renewable energy sources increased from 2000 to 2019 but coal, oil, and natural gas remain the most-used global energy sources.

The current energy system contributes to many environmental problems, including climate change, air pollution, biodiversity loss, the release of toxins into the environment, and water scarcity. Energy production and consumption are responsible for 72% of annual human-caused greenhouse gas emissions as of 2014.

The burning of fossil fuels and biomass is a major source of air pollutants harmful to human health. Coal combustion releases sulphur dioxide and volatile organic compounds which form into ground-level ozone, both of which can cause respiratory disease. The World Health Organization (WHO) estimates that outdoor air pollution causes 4.2 million deaths per year, and indoor air pollution causes 3.8 million deaths per year. Air pollution is the second-leading cause of death from non-communicable disease. Around 91% of the world's population lives with levels of air pollution that exceed WHO recommended limits.

Multiple analyses of strategies to reduce greenhouse gas emissions have found that the quantified health benefits of reduced air pollution can significantly offset the costs of implementing these strategies. Efforts to limit global warming to 1.5 °C could save millions of lives per year from air pollution alone, while increasing energy security and reducing poverty.

Environmental impacts extend beyond the by-products of combustion. Oil spills at sea harm marine life and may cause fires which release toxic emissions. Around 10% of global water use goes to energy production, mainly for cooling in thermal energy plants. In dry regions, this contributes to water scarcity. Bioenergy production, coal mining and processing, and oil extraction also require large amounts of water.

Energy poverty

Map of people with access to energy. Lack of access is most pronounced in India, Sub-Saharan Africa and South-East Asia.
World map showing where people without access to electricity lived in 2016 – mainly in sub-Saharan Africa

As of 2019, 770 million people, three-quarters of whom live in sub-Saharan Africa, do not have access to electricity. As of 2020, more than 2.6 billion people in developing countries rely on burning polluting fuels such as wood, animal dung, coal, or kerosene for cooking. A large fraction of the world population, including many in richer countries, cannot afford sufficient heating or cooling for their homes.

Cooking with polluting fuels is responsible for nearly all indoor air pollution, which causes in an estimated 1.6 to 3.8 million deaths annually, and also contributes significantly to outdoor air pollution. Health effects are concentrated among women, who are likely to be responsible for cooking, and young children. The work of gathering fuel exposes women and children to safety risks and often consumes 15 or more hours per week, constraining their available time for education, rest and paid work. Excessive harvesting of wood and other combustible material can cause serious local environmental damage, including desertification.

Reliable and affordable energy, particularly electricity, is essential for health care, education, and economic development. Health clinics require electricity to operate medical equipment, refrigerate vaccines and medications, and for lighting, but a 2018 survey in six Asian and African countries found that half of health facilities had no or poor access to electricity. Households without electricity typically use kerosene lamps for lighting, which creates toxic fumes.

Energy conservation

Countries such as the U.S. and Canada use twice as much energy per capita as Japan or western Europe, and 100 times as much commercial energy per capita as some African countries.
Global energy usage is highly unequal. High income countries such as the United States and Canada use 100 times as much energy per capita as some of the least developed countries in Africa.

The International Energy Agency (IEA) estimates that increasing energy efficiency can achieve 40% of greenhouse gas emission reductions needed to fulfil the Paris agreement. Climate change mitigation pathways that are in line with these goals show energy usage remaining around the same between 2010 and 2030, and then increasing slightly by 2050. Reducing overall energy demand would allow the growth in renewable energy sources to more rapidly displace fossil fuels.

One approach to conserving energy is increasing the technical efficiency of appliances, vehicles, industrial processes and buildings. Another approach is to reduce usage of materials, for example through better product lifecycle design and recycling. Behavioural changes such as using videoconferencing rather than business flights, or making urban trips by cycling, walking or public transport rather than by car, are another way to conserve energy. Consumer preferences for larger cars and SUVs, more air travel, and more Government policies to improve efficiency can include building codes, performance standards, carbon pricing, and the development of energy-efficient infrastructure to encourage changes in transport modes.

The energy intensity of the global economy (the amount of energy needed per unit of GDP) is a rough indicator of the energy efficiency of economic production. Energy intensity has been gradually decreasing for decades, however improvements have slowed in recent years, and faster rate of efficiency improvement would be necessary to meet global targets for 2030. Efficiency improvements often lead to a rebound effect in which consumers use the money they save to buy more energy-intensive goods and services. Recent technical efficiency improvements in transport and buildings have been largely offset by trends in consumer behaviour, such as purchasing larger vehicles and homes.

Energy sources

Renewable energy sources

Graph showing the expansion of wind and solar renewable energy capacity from 2011q to 2020
Renewable energy capacity additions in 2020 expanded by more than 45% from 2019, including a 90% rise in global wind capacity (green) and a 23% expansion of new solar photovoltaic installations (yellow).

Renewable energy technologies are essential contributors to sustainable energy, as they generally contribute to global energy security and reduce dependence on fossil fuel resources, thus mitigating greenhouse gas emissions. The terms sustainable energy and renewable energy are often used interchangeably. However, renewable energy projects sometimes raise significant sustainability concerns, such as risks to biodiversity when areas of high ecological value are converted to bioenergy production, wind or solar farms.

Hydropower is the largest source of renewable electricity while solar and wind energy have seen substantial growth over the last few years. Photovoltaic solar and onshore wind are the cheapest forms of new power generation capacity in most countries. For more than half of the 770 million people who currently lack access to electricity, decentralised renewable energy solutions such as solar-powered mini-grids are likely to be the cheapest method of providing access by 2030.

Solar

refer to caption
Solar power plant in California, United States

Solar energy is Earth's primary source of energy, a clean and abundantly available resource in many regions. In 2019, solar power provided around 3% of global electricity, mostly through solar panels based on photovoltaic cells (PV). The panels are mounted on top of buildings or used in solar parks connected to the electrical grid. Costs of solar photovoltaic cells have dropped rapidly, driving a strong growth in worldwide capacity. The cost of electricity from new solar farms is competitive with, or in many places, cheaper than electricity from existing coal plants. Various projections of future energy use identify solar PV as one of the main sources of energy generation in a sustainable mix.

Most components of solar panels can be easily recycled, but it is not always done in the absence of regulation. Panels typically contain heavy metals, so they pose environmental risks if put in landfill. Solar panels require energy for their production, equivalent to under two years of their own generation. Module recycling could reduce the energy payback time to around one month.

Concentrated solar power uses mirrors to produce heat, which drives a heat engine. Because the heat is typically stored, this type of solar power is dispatchable: it can be produced when needed. In addition to electricity production, solar energy is also used more directly; solar thermal heating systems are applied for hot water production, heating buildings, drying and desalination. Globally in 2018, solar energy fulfilled 1.5% of final energy demand for heating and cooling.

Wind power

Photograph of numerous wind turbines in ChinaWind turbines in Xinjiang, China

As a clean energy source, wind has been an important driver of development over millennia, providing transportation on water and mechanical energy for industrial processes and land reclamation. In 2019, wind turbines provided approximately 6% of global electricity. Electricity from onshore wind farms is often cheaper than existing coal plants, and competitive with natural gas and nuclear. Wind turbines can be placed in the ocean where winds are steadier and stronger than on land but construction and maintenance costs are higher. According to some analyst forecasts, offshore wind power will become cheaper than onshore wind by the mid-2030s.

Onshore wind farms, often built in wild or rural areas, have a visual impact on the landscape. While collisions kill both bats and to a lesser extent birds, these impacts are fewer than from other infrastructure such as windows and transmission lines. The noise and flickering light created by the turbines can be annoying, and constrain construction near densely populated areas. Wind power, in contrast to nuclear and fossil fuel plants does not consume water to produce power. Little energy is needed for wind turbine construction compared to the energy produced by the wind power plant itself. Turbine blades are not fully recyclable and research into methods of manufacturing easier-to-recycle blades is ongoing.

Hydropower

Photograph of the hydroelectric dam in Guri, Venezuela
Guri Dam, a hydroelectric dam in Venezuela

Hydroelectric plants convert the energy of moving water into electricity. On average, hydropower ranks among the energy sources with the lowest levels of greenhouse gas emissions per unit of energy produced, but levels of emissions vary enormously between projects. In 2019, hydropower supplied 16% of the world's electricity, down from a high of nearly 20% in the mid-to-late 20th century. It produced 60% of the electricity used in Canada and nearly 80% in Brazil.

In conventional hydropower, a reservoir is created behind a dam. Conventional hydropower plants provide a highly flexible, dispatchable electricity supply and can be combined with wind and solar power to provide peak load and to compensate when wind and sun are less available.

In most conventional hydropower projects, the biological matter that becomes submerged in the reservoir's flooding decomposes, becoming a source of carbon dioxide and methane. Levels of these emissions are particularly high in tropical regions. Deforestation and climate change can reduce energy generation from hydroelectric dams. Depending on location, the implementing large-scale dams can displace residents and cause significant local environmental damage; potential dam failure could place the surrounding population at risk.

Run-of-the-river hydroelectricity facilities generally have less environmental impact than reservoir-based facilities, but their ability to generate power depends on river flow which can vary with daily and seasonal weather. Reservoirs provide water quantity controls that are used for flood control and flexible electricity generation output while also providing security during drought for drinking water supply and irrigation.

Geothermal

refer to caption
Cooling towers at a geothermal power plant in Larderello, Italy

Geothermal energy is produced by tapping into the heat that exists below the earth's crust. Heat can be obtained by drilling into the ground and then carried by a heat-transfer fluid such as water, brine or steam. Geothermal energy can be harnessed for electricity generation and for heating. The use of geothermal energy is concentrated in regions where heat extraction is economical: a combination of heat, flow and high permeability is needed. Together with solar thermal, geothermal energy provided 2.2% of worldwide demand for heating in buildings in 2019.

Geothermal energy is a renewable resource because thermal energy is constantly replenished from neighbouring hotter regions and radioactive decay of naturally occurring isotopes. The median life-cycle greenhouse gas emissions of geothermal electric stations are 38 grams of carbon dioxide equivalent per kilowatt-hour of electricity, less than 5% of carbon intensity of coal, and in some geothermal plants it's as low as 6 grams gCO
2
eq/kWh. Geothermal energy carries a risk of inducing earthquakes, needs effective protection to avoid water pollution, and emits toxic emissions, which can be captured.

Bioenergy

Kenyan dairy farmer lighting a biogas lamp
Kenyan farmer lighting a biogas lamp. Biogas produced from biomass is a renewable energy source that can be used for cooking or to provide light.
 
A field of sugarcane for ethanol production
A sugarcane plantation to produce ethanol in Brazil

Biomass is a versatile and common source of renewable energy. If the production of biomass is well-managed, carbon emissions can be significantly offset by the absorption of carbon dioxide by the plants during their lifespans. Biomass can either be burned to produce heat and to generate electricity or converted to modern biofuels such as biodiesel and ethanol. Biofuels are often produced from corn or sugar cane. They are used to power transport, often blended with liquid fossil fuels.

Use of farmland for growing biomass can result in less land being available for growing food. Since photosynthesis captures only a small fraction of the energy in sunlight and crops require significant amounts of energy to harvest, dry, and transport, a lot of land is needed to produce biomass. If biomass is harvested from crops such as tree plantations, the cultivation of these crops can displace natural ecosystems, degrade soils and consume water resources and synthetic fertilisers. Approximately one-third of all wood used for fuel is harvested unsustainably. In some cases, these impacts can actually result in higher overall carbon emissions compared to using petroleum-based fuels.

In the United States, corn-based ethanol has replaced around 10% of motor gasoline, which requires a significant proportion of the yearly corn harvest. In Malaysia and Indonesia, clearing forests to produce palm oil for biodiesel has led to serious social and environmental effects, as these forests are critical carbon sinks and habitats for endangered species.

More sustainable sources of biomass include crops grown on soil unsuitable for food production, algae and waste. If the biomass source is agricultural or municipal waste, burning it or converting it into biogas provides a way to dispose of this waste. Second-generation biofuels which are produced from non-food plants reduce competition with food production, but may have other negative effects including trade-offs with conservation areas and local air pollution.

Carbon capture and storage technology can be used to capture emissions from bioenergy power plants. This process is known as bioenergy with carbon capture and storage (BECCS) and can result in net carbon dioxide removal from the atmosphere. However, the BECCS process can also result in net positive emissions depending on how the biomass material is grown, harvested, and transported. Deployment of BECCS at scales described in some climate change mitigation pathways would also require converting large amounts of cropland.

Marine energy

Marine energy represents the smallest share of the energy market. It encompasses tidal power, which is approaching maturity and wave power, which is earlier in its development. Two tidal barrage systems, in France and in Korea make up 90% of total production. While single marine energy devices pose little risk to the environment, the impacts of multi-array devices are less well known.

Non-renewable energy sources

Fossil fuel switching and mitigation

For a given unit of energy produced, the life-cycle greenhouse-gas emissions of natural gas are around 40 times the emissions of wind or nuclear energy, but are much less than coal. Natural gas produces around half the emissions of coal when used to generate electricity and around two-thirds the emissions of coal when used to produce heat. Reducing methane leaks in the process of extracting and transporting natural gas could further decrease its climate impact. Natural gas produces less air pollution than coal.

Building gas-fired power plants and gas pipelines is promoted as a way to phase out coal and wood burning pollution and increase energy supply in some African countries with fast growing populations and economies, but this practice is controversial. Developing natural gas infrastructure risks the creation of carbon lock-in and stranded assets, where new fossil infrastructure either commits to decades of carbon emissions, or has to be written off prematurely.

The greenhouse gas emissions of fossil fuel and biomass power plants can be significantly reduced through carbon capture and storage (CCS), however deployment of this technology is still very limited, with only 21 large-scale CCS plants in operation worldwide as of 2020. The CCS process is expensive, with costs depending considerably on the location's proximity to suitable geology for carbon dioxide storage. CCS can be retrofitted to existing power plants, but is more energy intensive. Most studies use a working assumption that CCS can capture 85–90% of the CO
2
emissions from a power plant. If 90% of emitted CO
2
is captured from a coal-fired power plant, its uncaptured emissions would still be many times greater than the emissions of nuclear, solar or wind energy per unit of electricity produced. Since coal plants using CCS would be less efficient, they would require more coal and thus increase the pollution associated with mining and transporting coal.

Nuclear power

Since 1985, the proportion of electricity generated from low-carbon sources has barely increased. Advances in deploying renewables have been mostly offset by retirement of nuclear power plants.

Nuclear power plants have been used since the 1950s as a low-carbon source of baseload electricity. Nuclear power plants in over 30 countries generate about 10% of global electricity, and as of 2019, over a quarter of all low-carbon energy, the second largest source after hydropower.

Nuclear power's lifecycle greenhouse gas emissions—including the mining and processing of uranium—are similar to the emissions from renewable energy sources. Nuclear power uses little land per unit of energy produced, compared to the major renewables, and does not create local air pollution. The uranium ore used to fuel nuclear fission plants is a non-renewable resource, but sufficient quantities exist to provide a supply for hundreds to thousands of years. Climate change mitigation pathways consistent with ambitious goals typically see an increase in power supply from nuclear.

There is controversy over whether nuclear power can be considered sustainable. The perceived risk of nuclear accidents has a major influence on public opinion of nuclear energy, although for each unit of energy produced, nuclear energy is far safer than fossil fuel energy and comparable to renewable sources. Radioactive nuclear waste must be managed over multi-generation timescales. Nuclear power plants can create fissile material that could be used for nuclear weapon proliferation. Reducing the time and the cost of building new nuclear plants have been goals for decades, but progress has been limited. Public opposition often makes nuclear plants politically difficult to implement. Experts from the Joint Research Centre (JRC), the scientific expert arm of the EU, stated in April 2021 that nuclear power is "sustainable". Two other groups of experts—SCHEER (Scientific Committee on Health, Environmental and Emerging Risks) and "Article 31"—largely confirmed JRC findings in July 2021.

Various new forms of nuclear energy are in development, hoping to address the drawbacks of conventional plants. Fast breeder reactors are capable of recycling nuclear waste and therefore can significantly reduce the amount of waste that requires geological disposal but have not yet been deployed on a large-scale commercial basis. Nuclear power based on thorium, rather than uranium, may be able to provide higher energy security for countries that do not have a large supply of uranium. Small modular reactors may have several advantages over current large reactors: it should be possible to build them faster, and their modularization would allow for cost reductions via learning-by-doing. Several countries are attempting to develop nuclear fusion reactors, which would generate small amounts of waste and no risk of explosions.

Energy system transformation

Energy-related emissions produced by sector in decreasing order: industry, land use, building, transport and other
Greenhouse gas emissions from the production and use of energy as of 2020. The "Other" category includes fugitive emissions from the energy industry itself.

The emissions reductions necessary to keep global warming below 2 °C will require a system-wide transformation of the way energy is produced, distributed, stored, and consumed. As of 2019, 85% of the world's energy needs are met by burning fossil fuels. To maximize the use of renewable energy sources, energy usage technologies such as vehicles must become powered by electricity or hydrogen. Electricity systems will need to become more flexible to accommodate variable renewable energy sources.

The International Energy Agency states that further innovation in the energy sector, such as in battery technologies and carbon-neutral fuels, is needed to reach net-zero emissions in 2050. Development of new technologies requires research and development, demonstration and cost reductions via deployment.

Generation of electricity and heat contributes 31% of human-caused greenhouse gas emissions, use of energy in transport contributes 15%, and use of energy in manufacturing and construction contributes 12%. An additional 5% is released through processes associated with fossil fuel production and another 8% through various other forms of fuel combustion.

Electrification

Photograph two fans, the outdoor section of a heat pump
The outdoor section of a heat pump

Electrification is a key part of using energy sustainably. Many options exist to produce electricity sustainably, but producing fuels or heat on a large scale sustainably is relatively difficult. As of 2018, about a quarter of all electricity generation came from renewable sources other than biomass. Electricity generation has seen a much faster uptake of renewables than the heat and transport sectors.

Massive electrification in the heat and transport sector may be needed to make these sectors sustainable, with heat pumps and electric vehicles playing important roles. Ambitious climate policy would see a doubling of energy consumed as electricity by 2050, from 20% in 2020.

Infrastructure for generating and storing renewable electricity requires minerals and metals, such as cobalt and lithium for batteries and copper for solar panels. Recycling can meet some of this demand if product lifecycles are well-designed, however achieving net zero emissions would still require major increases in mining for 17 types of metals and minerals. A small group of countries or companies sometimes dominate the markets for these commodities raising geopolitical concerns. Cobalt, for instance, is mined in Congo, a politically unstable region where mining is often associated with human rights risks. More diverse geographical sourcing may ensure the stability of the supply chain.

Managing variable energy sources

Photograph of buildings incorporating rooftop solar panels
Buildings in the Solar Settlement at Schlierberg, Germany, produce more energy than they consume. They incorporate rooftop solar panels and are built for maximum energy efficiency.

Solar and wind are variable renewable energy sources that supply electricity intermittently depending on the weather and the time of day. Most electrical grids were constructed for non-intermittent energy sources such as coal-fired power plants. As larger amounts of solar and wind energy are integrated into the grid, changes have to be made to the energy system to ensure that the supply of electricity is matched to demand. In 2019, these sources generated 8.5% of worldwide electricity, a share that has grown rapidly.

There are various ways to make the electricity system more flexible. In many places, wind and solar production are complementary on a daily and a seasonal scale: There is more wind during the night and in winter when solar energy production is low. Linking different geographical regions through long-distance transmission lines allows for further cancelling out of variability. Energy demand can be shifted in time through energy demand management and the use of smart grids, matching the times when variable energy production is highest. With grid energy storage, energy produced in excess can be released when needed. Further flexibility could be provided from sector coupling, i.e. coupling the electricity sector to the heat and mobility sector via power-to-heat-systems and electric vehicles.

Building overcapacity for wind and solar generation can help to ensure that enough electricity is produced even during poor weather – during optimal weather energy generation may have to be curtailed, if excess electricity cannot be used or stored. The final demand-supply mismatch may be covered by using dispatchable energy sources such as hydropower, bioenergy, or natural gas.

Energy storage

refer to caption
Construction of salt tanks to store thermal energy

Energy storage helps overcome barriers for intermittent renewable energy and is an important aspect of a sustainable energy system. The most commonly used storage method is pumped-storage hydroelectricity, which requires locations with large differences in height and access to water. Batteries, and specifically lithium-ion batteries whose costs have been coming down rapidly, are also deployed widely. Batteries typically store electricity for short periods; research is ongoing into technology with sufficient capacity to last through seasons. Pumped hydro storage and power-to-gas (converting electricity to gas, and back) with capacity for multi-month usage has been implemented in some locations.

Hydrogen

Hydrogen can be burned to produce heat or can power fuel cells to generate electricity, with zero emissions at the point of usage. The overall lifecycle emissions of hydrogen depend on how it is produced. Very little of the world's current supply of hydrogen is currently created from sustainable sources. The predominant reaction route is steam methane reforming in which hydrogen is produced from a chemical reaction between steam and methane. Producing one tonne of hydrogen through this process emits 6.6–9.3 tonnes of carbon dioxide. With carbon capture and storage technologies, a large fraction of these emissions could be removed.

Another more sustainable approach for hydrogen production is through electrolysis, by using electricity to split water molecules into hydrogen and oxygen; if the electricity is generated sustainably, the resultant fuel will also be sustainable. This process is currently more expensive than creating hydrogen from fossil fuels, and the efficiency of energy conversion is inherently low. Hydrogen can be produced when there is a surplus of intermittent renewable electricity, then stored and used to generate heat or to re-generate electricity. It can be further transformed into synthetic fuels such as ammonia and methanol, or into feedstock for the chemical industry, indirectly electrifying those applications. This dual character of hydrogen, both a chemical reagent and as an energy carrier, makes it likely hydrogen use will expand in the coming decades.

Innovation in hydrogen electrolysers could make large-scale production of hydrogen from electricity more cost-competitive. There is potential for hydrogen to play a significant role in decarbonising energy systems because in certain sectors, replacing fossil fuels with direct use of electricity would be very difficult. Hydrogen fuel can produce the intense heat required for industrial production of steel, cement, glass, and chemicals. For steelmaking, hydrogen can function as a clean energy carrier and simultaneously as a low-carbon catalyst replacing coal-derived coke.

Energy usage technologies

Transport

Group of cyclists using a bike lane in Vancouver, Canada
People using a bike lane in Vancouver, Canada; cycling is a sustainable method of transport

There are multiple ways to make transport more sustainable. Public transport frequently emits fewer greenhouse gases per passenger than personal vehicles, especially with high occupancy. High-speed rail journeys, which use much less fuel, can replace short-distance flights. Stimulating non-motorised transport such as walking and cycling, particularly in cities, can make transport cleaner and healthier.

The energy efficiency of cars has increased because of technological progress, but shifting to electric vehicles is an important further step towards decarbonising transport and reducing air pollution. A substantial proportion of traffic-related air pollution consists of particulate matter from road dust and the wearing-down of tyres and brake pads. Reducing pollution from these sources cannot be achieved by electrification; it requires measures such as making vehicles lighter and driving them less.

Making freight transport sustainable is challenging. Hydrogen vehicles may be an option for larger vehicles such as lorries which have not yet been widely electrified because of the weight of batteries needed for long-distance travel. Many of the techniques needed to lower emissions from shipping and aviation are still early in their development, with clean ammonia a promising candidate for shipping fuel. Aviation biofuel may be one of the better uses of bioenergy, providing some carbon is captured and stored during manufacture of the fuel.

Buildings

Electric induction oven
For cooking, electric induction stoves are one of the most energy-efficient and safest options.

For heating buildings, alternatives to burning fossil fuels and biomass include electrification (heat pumps, or the less efficient electric heater), geothermal, solar thermal, and waste heat. Seasonal thermal energy storage has been implemented in some high-latitude regions for household heating. Heat pumps currently provide only 5% of space and water heating requirements globally, but the IEA estimates they could provide over 90%.

In densely populated urban areas, space for heat pumps may be limited and district heating may better meet demand. While traditionally using mostly fossil fuels, modern and cold district heating systems are designed to use lower temperatures, high shares of renewable energy such as central solar heating and geothermal energy and waste heat to provide low-carbon heating. The costs of all these technologies strongly depend on location, and uptake of the technology sufficient for deep decarbonisation requires stringent policy interventions.

Efficient cooling of buildings requires passive building design and urban planning, in addition to air conditioning, which requires electrification and additional power demand and is therefore not always accessible for poorer households. Some air conditioning units use refrigerants which warm the climate: replacing those with climate-friendly refrigerants, as required under the internationally agreed Kigali Amendment, would reduce the climate impacts of cooling.

Industry

Over one-third of energy use is by industry. Most of that energy is deployed in thermal processes: generating steam, drying, and refrigeration. The share of renewable energy in industry was 14.5% in 2017—mostly low-temperature heat supplied by bioenergy and electricity. The more energy-intensive activities in industry have the lowest shares of renewable energy, as they face limitations in generating heat at temperatures over 200 °C (390 °F).

For some industrial processes, such as steel production, commercialisation of technologies that have not yet been built or operated at full scale will be needed to eliminate greenhouse gas emissions. The production of plastic, cement and fertilizers also requires significant amounts of energy, with limited possibilities available to decarbonise. A switch to a circular economy would make industry more sustainable, as it involves recycling more and thereby using less energy compared to extracting new raw materials.

Universal access to energy

Photograph of a woman carrying firewood she has gathered on her head
A woman in rural Rajasthan (India) collects firewood for cooking. Firewood is labour-intensive to gather and causes harmful indoor and outdoor air pollution.

With responsible planning and management, pathways exist to provide universal access to electricity and clean cooking by 2030 in ways that are consistent with climate goals. Off-grid and mini-grid systems based on renewable energy, such as small solar PV installations that generate and store enough electricity for a village, are important solutions for rural areas. Wider access to reliable electricity would lead to less use of kerosene lighting and diesel generators, which are currently common in the developing world.

A goal in global sustainable development is to reduce the health and environmental problems caused by cooking with biomass, coal, and kerosene. Alternatives include electric stoves, solar cookers, stoves that use clean fuels, and improved cookstoves that burn biomass more efficiently and with less pollution. Depending on location, clean fuels for cooking are typically liquified petroleum gas (LPG), locally produced biogas, piped natural gas (PNG), or alcohol. The World Health Organization encourages further research into biomass stove technology, as no widely available biomass stoves meet recommended emissions limits.

Transitioning to cleaner cooking methods is expected to either raise greenhouse gas emissions by a minimal amount or decrease them, even if the replacement fuels are fossil gases. There is evidence that LPG and PNG have a smaller climate effect than the combustion of solid fuels, which emits methane and black carbon. The Intergovernmental Panel on Climate Change (IPCC) stated in 2018, "The costs of achieving nearly universal access to electricity and clean fuels for cooking and heating are projected to be between 72 and 95 billion USD per year until 2030 with minimal effects on GHG emissions."

According to a 2020 report by the IEA, current and planned policies would still leave over 660 million people without electricity by 2030. Efforts to improve access to clean cooking fuels and stoves have barely kept up with population growth, and current and planned policies would still leave 2.4 billion people without access in 2030. Historically, several countries have made rapid economic gains through coal usage, particularly in Asia. However, there remains a window of opportunity for many poor countries and regions to "leapfrog" fossil fuel dependency by developing their energy systems based on renewables, given adequate international investment and knowledge transfer.

Finance

Graph of global investment for renewable energy, electrified heat and transport, and other non-fossil-fuel energy sources
Electrified heat and transport are key parts of investment for the renewable energy transition.

Mobilising sufficient finance for innovation and investment is a prerequisite for the energy transition. The IPCC estimates that to limit global warming to 1.5 °C, US$2.4 trillion would need to be invested in the energy system each year between 2016 and 2035. Most studies project that these costs, equivalent to 2.5 percent of world GDP, would be small compared to the economic and health benefits. Average annual investment in low-carbon energy technologies and energy efficiency would need to be upscaled by roughly a factor of six by 2050 compared to 2015. Underfunding is particularly acute in the least developed countries.

The UNFCCC estimates that climate financing totalled $681 billion in 2016, with most of this being private-sector investment in renewable energy deployment, public-sector investment in sustainable transport and private-sector investment in energy efficiency. Fossil fuel funding and subsidies form a significant barrier to the energy transition. Direct global fossil fuel subsidies reached $319 billion in 2017, and $5.2 trillion when indirect costs such as air pollution are priced in. Ending these could lead to a 28% reduction in global carbon emissions and a 46% reduction in air pollution deaths. Funding for clean energy has been largely unaffected by the COVID-19 pandemic and required economic stimulus packages offer possibilities for a green recovery.

The International Labour Organization estimates that efforts to limit global warming to 2 °C would result in net job creation in most sectors of the economy. It predicts that 24 million new jobs would be created in areas such as renewable electricity generation, improving energy-efficiency in buildings and the transition to electric vehicles, while 6 million jobs in the fossil fuel industry would be lost.

Government policies

Photograph of a row of electric cars
For new cars, China will allow sales of only new energy vehicles such as electric vehicles, beginning in 2035.

Well-designed government policies that promote energy system transformation can lower greenhouse gas emissions and improve air quality simultaneously, and in many cases can also increase energy security. Carbon pricing, energy-specific policies, or a mixture of both are necessary to limit global warming to 1.5 °C.

Carbon taxes provide a source of revenue that can be used to lower other taxes or to help lower-income households afford higher energy costs. Carbon taxes have encountered strong political pushback in some jurisdictions, whereas energy-specific policies tend to be politically safer. As of 2019, carbon pricing covers about 20% of global greenhouse gas emissions; in most of these cases the price on carbon is lower than what would be needed to achieve the goals of the Paris Agreement.

Energy-specific programs and regulations have historically been the mainstays of efforts to reduce fossil fuel emissions. Some governments have committed to dates for phasing out coal-fired power plants, ending new fossil fuel exploration, requiring that new passenger vehicles produce zero emissions, and requiring new buildings to be heated by electricity instead of gas. Renewable portfolio standards have been enacted in several countries requiring utilities to increase the percentage of electricity they generate from renewable sources.

Governments can accelerate energy system transformation by leading the development of infrastructure such as electrical distribution grids, smart grids and hydrogen pipelines. In transport, appropriate infrastructure and incentives can make travel more efficient and less car-dependent. Urban planning to discourage sprawl can reduce energy use in local transport and buildings while enhancing quality-of-life.

The scale and pace of policy reforms that have been initiated as of 2020 are far less than needed to fulfil the climate goals of the Paris Agreement. Governments can make the transition to sustainable energy more politically and socially feasible by ensuring a just transition for workers and regions that depend on the fossil fuel industry to ensure they have alternative economic opportunities. In addition to domestic policies, greater international cooperation will be required to accelerate innovation and to assist poorer countries in establishing a sustainable path to full energy access.

 

Economies of scale

From Wikipedia, the free encyclopedia
 
As quantity of production increases from Q to Q2, the average cost of each unit decreases from C to C1. LRAC is the long-run average cost

In microeconomics, economies of scale are the cost advantages that enterprises obtain due to their scale of operation, and are typically measured by the amount of output produced. A decrease in cost per unit of output enables an increase in scale. At the basis of economies of scale there may be technical, statistical, organizational or related factors to the degree of market control.

Economies of scale apply to a variety of the organizational and business situations and at various levels, such as a production, plant or an entire enterprise. When average costs start falling as output increases, then economies of scale occur. Some economies of scale, such as capital cost of manufacturing facilities and friction loss of transportation and industrial equipment, have a physical or engineering basis.

The economic concept dates back to Adam Smith and the idea of obtaining larger production returns through the use of division of labor. Diseconomies of scale are the opposite.

Economies of scale often have limits, such as passing the optimum design point where costs per additional unit begin to increase. Common limits include exceeding the nearby raw material supply, such as wood in the lumber, pulp and paper industry. A common limit for a low cost per unit weight commodities is saturating the regional market, thus having to ship product uneconomic distances. Other limits include using energy less efficiently or having a higher defect rate.

Large producers are usually efficient at long runs of a product grade (a commodity) and find it costly to switch grades frequently. They will, therefore, avoid specialty grades even though they have higher margins. Often smaller (usually older) manufacturing facilities remain viable by changing from commodity-grade production to specialty products.

Economies of scale must be distinguished from economies stemming from an increase in the production of a given plant. When a plant is used below its optimal production capacity, increases in its degree of utilization bring about decreases in the total average cost of production. As noticed, among the others, by Nicholas Georgescu-Roegen (1966) and Nicholas Kaldor (1972) these economies are not economies of scale.

Overview

The simple meaning of economies of scale is doing things more efficiently with increasing size. Common sources of economies of scale are purchasing (bulk buying of materials through long-term contracts), managerial (increasing the specialization of managers), financial (obtaining lower-interest charges when borrowing from banks and having access to a greater range of financial instruments), marketing (spreading the cost of advertising over a greater range of output in media markets), and technological (taking advantage of returns to scale in the production function). Each of these factors reduces the long run average costs (LRAC) of production by shifting the short-run average total cost (SRATC) curve down and to the right.

Economies of scale is a concept that may explain patterns in international trade or in the number of firms in a given market. The exploitation of economies of scale helps explain why companies grow large in some industries. It is also a justification for free trade policies, since some economies of scale may require a larger market than is possible within a particular country—for example, it would not be efficient for Liechtenstein to have its own carmaker if they only sold to their local market. A lone carmaker may be profitable, but even more so if they exported cars to global markets in addition to selling to the local market. Economies of scale also play a role in a "natural monopoly". There is a distinction between two types of economies of scale: internal and external. An industry that exhibits an internal economy of scale is one where the costs of production fall when the number of firms in the industry drops, but the remaining firms increase their production to match previous levels. Conversely, an industry exhibits an external economy of scale when costs drop due to the introduction of more firms, thus allowing for more efficient use of specialized services and machinery.

Determinants of economies of scale

Physical and engineering basis: economies of increased dimension

Some of the economies of scale recognized in engineering have a physical basis, such as the square–cube law, by which the surface of a vessel increases by the square of the dimensions while the volume increases by the cube. This law has a direct effect on the capital cost of such things as buildings, factories, pipelines, ships and airplanes.

In structural engineering, the strength of beams increases with the cube of the thickness.

Drag loss of vehicles like aircraft or ships generally increases less than proportional with increasing cargo volume, although the physical details can be quite complicated. Therefore, making them larger usually results in less fuel consumption per ton of cargo at a given speed.

Heat loss from industrial processes vary per unit of volume for pipes, tanks and other vessels in a relationship somewhat similar to the square–cube law. In some productions, an increase in the size of the plant reduces the average variable cost, thanks to the energy savings resulting from the lower dispersion of heat.

Economies of increased dimension are often misinterpreted because of the confusion between indivisibility and three-dimensionality of space. This confusion arises from the fact that three-dimensional production elements, such as pipes and ovens, once installed and operating, are always technically indivisible. However, the economies of scale due to the increase in size do not depend on indivisibility but exclusively on the three-dimensionality of space. Indeed, indivisibility only entails the existence of economies of scale produced by the balancing of productive capacities, considered above; or of increasing returns in the utilisation of a single plant, due to its more efficient use as the quantity produced increases. However, this latter phenomenon has nothing to do with the economies of scale which, by definition, are linked to the use of a larger plant.

Economies in holding stocks and reserves

At the base of economies of scale there are also returns to scale linked to statistical factors. In fact, the greater of the number of resources involved, the smaller, in proportion, is the quantity of reserves necessary to cope with unforeseen contingencies (for instance, machine spare parts, inventories, circulating capital, etc.).

Transaction economies

A larger scale generally determines greater bargaining power over input prices and therefore benefits from pecuniary economies in terms of purchasing raw materials and intermediate goods compared to companies that make orders for smaller amounts. In this case, we speak of pecuniary economies, to highlight the fact that nothing changes from the "physical" point of view of the returns to scale. Furthermore, supply contracts entail fixed costs which lead to decreasing average costs if the scale of production increases.

Economies deriving from the balancing of production capacity

Economies of productive capacity balancing derives from the possibility that a larger scale of production involves a more efficient use of the production capacities of the individual phases of the production process. If the inputs are indivisible and complementary, a small scale may be subject to idle times or to the underutilization of the productive capacity of some sub-processes. A higher production scale can make the different production capacities compatible. The reduction in machinery idle times is crucial in the case of a high cost of machinery.

Economies resulting from the division of labour and the use of superior techniques

A larger scale allows for a more efficient division of labour. The economies of division of labour derive from the increase in production speed, from the possibility of using specialized personnel and adopting more efficient techniques. An increase in the division of labour inevitably leads to changes in the quality of inputs and outputs.

Managerial economics

Many administrative and organizational activities are mostly cognitive and, therefore, largely independent of the scale of production. When the size of the company and the division of labour increase, there are a number of advantages due to the possibility of making organizational management more effective and perfecting accounting and control techniques. Furthermore, the procedures and routines that turned out to be the best can be reproduced by managers at different times and places.

Learning and growth economies

Learning and growth economies are at the base of dynamic economies of scale, associated with the process of growth of the scale dimension and not to the dimension of scale per se. Learning by doing implies improvements in the ability to perform and promotes the introduction of incremental innovations with a progressive lowering of average costs. Learning economies are directly proportional to the cumulative production (experience curve). Growth economies occur when a company acquires an advantage by increasing its size. These economies are due to the presence of some resource or competence that is not fully utilized, or to the existence of specific market positions that create a differential advantage in expanding the size of the firms. That growth economies disappear once the scale size expansion process is completed. For example, a company that owns a supermarket chain benefits from an economy of growth if, opening a new supermarket, it gets an increase in the price of the land it owns around the new supermarket. The sale of these lands to economic operators, who wish to open shops near the supermarket, allows the company in question to make a profit, making a profit on the revaluation of the value of building land.

Capital and operating cost

Overall costs of capital projects are known to be subject to economies of scale. A crude estimate is that if the capital cost for a given sized piece of equipment is known, changing the size will change the capital cost by the 0.6 power of the capacity ratio (the point six to the power rule).

In estimating capital cost, it typically requires an insignificant amount of labor, and possibly not much more in materials, to install a larger capacity electrical wire or pipe having significantly greater capacity.

The cost of a unit of capacity of many types of equipment, such as electric motors, centrifugal pumps, diesel and gasoline engines, decreases as size increases. Also, the efficiency increases with size.

Crew size and other operating costs for ships, trains and airplanes

Operating crew size for ships, airplanes, trains, etc., does not increase in direct proportion to capacity. (Operating crew consists of pilots, co-pilots, navigators, etc. and does not include passenger service personnel.) Many aircraft models were significantly lengthened or "stretched" to increase payload.

Many manufacturing facilities, especially those making bulk materials like chemicals, refined petroleum products, cement and paper, have labor requirements that are not greatly influenced by changes in plant capacity. This is because labor requirements of automated processes tend to be based on the complexity of the operation rather than production rate, and many manufacturing facilities have nearly the same basic number of processing steps and pieces of equipment, regardless of production capacity.

Economical use of byproducts

Karl Marx noted that large scale manufacturing allowed economical use of products that would otherwise be waste. Marx cited the chemical industry as an example, which today along with petrochemicals, remains highly dependent on turning various residual reactant streams into salable products. In the pulp and paper industry it is economical to burn bark and fine wood particles to produce process steam and to recover the spent pulping chemicals for conversion back to a usable form.

Economies of scale and the size of exporter

Large and more productive firms typically generate enough net revenues abroad to cover the fixed costs associated with exporting. However, in the event of trade liberalization, resources will have to be reallocated toward the more productive firm, which raises the average productivity within the industry.

Firms differ in their labor productivity and the quality of their goods produced. It is because of this that more efficient firms are more likely to generate more net income abroad and thus become exporters of their goods or services. There is a correlating relationship between a firms' total sales and underlying efficiency. Firms with higher productivity will always outperform a firm with lower productivity which will lead to lower sales. Through trade liberalization, organizations are able to drop their trade costs due to export growth. However, trade liberalization does not account for any tariff reduction or shipping logistics improvement. However, total economies of scale is based on the exporters individual frequency and size. So large-scale companies are more likely to have a lower cost per unit as opposed to small-scale companies. Likewise, high trade frequency companies are able to reduce their overall cost attributed per unit when compared to those of low-trade frequency companies. 

Economies of scale and returns to scale

Economies of scale is related to and can easily be confused with the theoretical economic notion of returns to scale. Where economies of scale refer to a firm's costs, returns to scale describe the relationship between inputs and outputs in a long-run (all inputs variable) production function. A production function has constant returns to scale if increasing all inputs by some proportion results in output increasing by that same proportion. Returns are decreasing if, say, doubling inputs results in less than double the output, and increasing if more than double the output. If a mathematical function is used to represent the production function, and if that production function is homogeneous, returns to scale are represented by the degree of homogeneity of the function. Homogeneous production functions with constant returns to scale are first degree homogeneous, increasing returns to scale are represented by degrees of homogeneity greater than one, and decreasing returns to scale by degrees of homogeneity less than one.

If the firm is a perfect competitor in all input markets, and thus the per-unit prices of all its inputs are unaffected by how much of the inputs the firm purchases, then it can be shown that at a particular level of output, the firm has economies of scale if and only if it has increasing returns to scale, has diseconomies of scale if and only if it has decreasing returns to scale, and has neither economies nor diseconomies of scale if it has constant returns to scale. In this case, with perfect competition in the output market the long-run equilibrium will involve all firms operating at the minimum point of their long-run average cost curves (i.e., at the borderline between economies and diseconomies of scale).

If, however, the firm is not a perfect competitor in the input markets, then the above conclusions are modified. For example, if there are increasing returns to scale in some range of output levels, but the firm is so big in one or more input markets that increasing its purchases of an input drives up the input's per-unit cost, then the firm could have diseconomies of scale in that range of output levels. Conversely, if the firm is able to get bulk discounts of an input, then it could have economies of scale in some range of output levels even if it has decreasing returns in production in that output range.

In essence, returns to scale refer to the variation in the relationship between inputs and output. This relationship is therefore expressed in "physical" terms. But when talking about economies of scale, the relation taken into consideration is that between the average production cost and the dimension of scale. Economies of scale therefore are affected by variations in input prices. If input prices remain the same as their quantities purchased by the firm increase, the notions of increasing returns to scale and economies of scale can be considered equivalent. However, if input prices vary in relation to their quantities purchased by the company, it is necessary to distinguish between returns to scale and economies of scale. The concept of economies of scale is more general than that of returns to scale since it includes the possibility of changes in the price of inputs when the quantity purchased of inputs varies with changes in the scale of production.

The literature assumed that due to the competitive nature of reverse auctions, and in order to compensate for lower prices and lower margins, suppliers seek higher volumes to maintain or increase the total revenue. Buyers, in turn, benefit from the lower transaction costs and economies of scale that result from larger volumes. In part as a result, numerous studies have indicated that the procurement volume must be sufficiently high to provide sufficient profits to attract enough suppliers, and provide buyers with enough savings to cover their additional costs.

However, surprisingly enough, Shalev and Asbjornse found, in their research based on 139 reverse auctions conducted in the public sector by public sector buyers, that the higher auction volume, or economies of scale, did not lead to better success of the auction. They found that auction volume did not correlate with competition, nor with the number of bidders, suggesting that auction volume does not promote additional competition. They noted, however, that their data included a wide range of products, and the degree of competition in each market varied significantly, and offer that further research on this issue should be conducted to determine whether these findings remain the same when purchasing the same product for both small and high volumes. Keeping competitive factors constant, increasing auction volume may further increase competition.

Economies of scale in the history of economic analysis

Economies of scale in classical economists

The first systematic analysis of the advantages of the division of labour capable of generating economies of scale, both in a static and dynamic sense, was that contained in the famous First Book of Wealth of Nations (1776) by Adam Smith, generally considered the founder of political economy as an autonomous discipline.

John Stuart Mill, in Chapter IX of the First Book of his Principles, referring to the work of Charles Babbage (On the economics of machines and manufactories), widely analyses the relationships between increasing returns and scale of production all inside the production unit.

Economies of scale in Marx and distributional consequences

In Das Kapital (1867), Karl Marx, referring to Charles Babbage, extensively analyses economies of scale and concludes that they are one of the factors underlying the ever-increasing concentration of capital. Marx observes that in the capitalist system the technical conditions of the work process are continuously revolutionized in order to increase the surplus by improving the productive force of work. According to Marx, with the cooperation of many workers brings about an economy in the use of the means of production and an increase in productivity due to the increase in the division of labour. Furthermore, the increase in the size of the machinery allows significant savings in construction, installation and operation costs. The tendency to exploit economies of scale entails a continuous increase in the volume of production which, in turn, requires a constant expansion of the size of the market. However, if the market does not expand at the same rate as production increases, overproduction crises can occur. According to Marx the capitalist system is therefore characterized by two tendencies, connected to economies of scale: towards a growing concentration and towards economic crises due to overproduction.

In his 1844 Economic and Philosophic Manuscripts, Karl Marx observes that economies of scale have historically been associated with an increasing concentration of private wealth and have been used to justify such concentration. Marx points out that concentrated private ownership of large-scale economic enterprises is a historically contingent fact, and not essential to the nature of such enterprises. In the case of agriculture, for example, Marx calls attention to the sophistical nature of the arguments used to justify the system of concentrated ownership of land:

As for large landed property, its defenders have always sophistically identified the economic advantages offered by large-scale agriculture with large-scale landed property, as if it were not precisely as a result of the abolition of property that this advantage, for one thing, received its greatest possible extension, and, for another, only then would be of social benefit.

Instead of concentrated private ownership of land, Marx recommends that economies of scale should instead be realized by associations:

Association, applied to land, shares the economic advantage of large-scale landed property, and first brings to realization the original tendency inherent in land-division, namely, equality. In the same way association re-establishes, now on a rational basis, no longer mediated by serfdom, overlordship and the silly mysticism of property, the intimate ties of man with the earth, for the earth ceases to be an object of huckstering, and through free labor and free enjoyment becomes once more a true personal property of man.

Economies of scale in Marshall

Alfred Marshall notes that "some, among whom Cournot himself," have considered "the internal economies [...] apparently without noticing that their premises lead inevitably to the conclusion that, whatever firm first gets a good start will obtain a monopoly of the whole business of its trade … ". Marshall believes that there are factors that limit this trend toward monopoly, and in particular:

  • the death of the founder of the firm and the difficulty that the successors may have inherited his/her entrepreneurial skills;
  • the difficulty of reaching new markets for one's goods;
  • the growing difficulty of being able to adapt to changes in demand and to new techniques of production;
  • The effects of external economies, that is the particular type of economies of scale connected not to the production scale of an individual production unit, but to that of an entire sector.

Sraffa's critique

Piero Sraffa observes that Marshall, in order to justify the operation of the law of increasing returns without it coming into conflict with the hypothesis of free competition, tended to highlight the advantages of external economies linked to an increase in the production of an entire sector of activity. However, "those economies which are external from the point of view of the individual firm, but internal as regards the industry in its aggregate, constitute precisely the class which is most seldom to be met with." "In any case - Sraffa notes – in so far as external economies of the kind in question exist, they are not linked to be called forth by small increases in production," as required by the marginalist theory of price. Sraffa points out that, in the equilibrium theory of the individual industries, the presence of external economies cannot play an important role because this theory is based on marginal changes in the quantities produced.

Sraffa concludes that, if the hypothesis of perfect competition is maintained, economies of scale should be excluded. He then suggests the possibility of abandoning the assumption of free competition to address the study of firms that have their own particular market. This stimulated a whole series of studies on the cases of imperfect competition in Cambridge. However, in the succeeding years Sraffa followed a different path of research that brought him to write and publish his main work Production of commodities by means of commodities (Sraffa 1966). In this book, Sraffa determines relative prices assuming no changes in output, so that no question arises as to the variation or constancy of returns.

Economies of scale and the tendency towards monopoly: "Cournot's dilemma"

It has been noted that in many industrial sectors there are numerous companies with different sizes and organizational structures, despite the presence of significant economies of scale. This contradiction, between the empirical evidence and the logical incompatibility between economies of scale and competition, has been called the ‘Cournot dilemma’. As Mario Morroni observes, Cournot's dilemma appears to be unsolvable if we only consider the effects of economies of scale on the dimension of scale. If, on the other hand, the analysis is expanded, including the aspects concerning the development of knowledge and the organization of transactions, it is possible to conclude that economies of scale do not always lead to monopoly. In fact, the competitive advantages deriving from the development of the firm's capabilities and from the management of transactions with suppliers and customers can counterbalance those provided by the scale, thus counteracting the tendency towards a monopoly inherent in economies of scale. In other words, the heterogeneity of the organizational forms and of the size of the companies operating in a sector of activity can be determined by factors regarding the quality of the products, the production flexibility, the contractual methods, the learning opportunities, the heterogeneity of preferences of customers who express a differentiated demand with respect to the quality of the product, and assistance before and after the sale. Very different organizational forms can therefore co-exist in the same sector of activity, even in the presence of economies of scale, such as, for example, flexible production on a large scale, small-scale flexible production, mass production, industrial production based on rigid technologies associated with flexible organizational systems and traditional artisan production. The considerations regarding economies of scale are therefore important, but not sufficient to explain the size of the company and the market structure. It is also necessary to take into account the factors linked to the development of capabilities and the management of transaction costs.

External economies of scale

External economies of scale tend to be more prevalent than internal economies of scale. Through the external economies of scale, the entry of new firms benefits all existing competitors as it creates greater competition and also reduces the average cost for all firms as opposed to internal economies of scale which only allows benefits to the individual firm. Advantages that arise from external economies of scale include;

  • Expansion of the industry.
  • Benefits most or all of the firms within the industry.
  • Can lead to rapid growth of local governments.
Graph Depicting External Economies of Scale

Sources

Purchasing

Firms are able to lower their average costs by buying their inputs required for the production process in bulk or from special wholesalers.

Managerial

Firms might be able to lower their average costs by improving their management structure within the firm. This can range from hiring better skilled or more experienced managers from the industry.

Technological

Technological advancements will change the production process which will subsequently reduce the overall cost per unit.

 

Small modular reactor

From Wikipedia, the free encyclopedia
 
Illustration of a light water small modular nuclear reactor (SMR)

Small modular reactors (SMRs) are nuclear fission reactors that are smaller than conventional reactors and centrally manufactured. They can be manufactured at a plant and brought to a site to be installed. Modular reactors allow for less on-site construction, increased containment efficiency, and enhanced safety due to passive nuclear safety features. SMRs have the advantage of integrating passive safety features that do not require human intervention. In the case of a problem, the passive safety features will act in the absence of human supervision. SMRs also require less staffing than conventional nuclear reactors.  SMRs have been proposed as a way to bypass financial and safety barriers that have inhibited the construction of large conventional nuclear reactors in recent decades.

Several designs exist for SMR, ranging from scaled down versions of existing designs to entirely new generation IV designs. Both thermal-neutron reactors and fast-neutron reactors have been proposed, as well as molten salt and gas cooled reactor models.

A main hindrance to commercial use is licensing, since current regulatory regimes are adapted to conventional nuclear power plants. SMRs differ in terms of staffing, security and deployment time. One concern with SMRs is preventing proliferation of nuclear material that is simpler to access than a conventional large-scale reactor. Licensing time, cost and risk are critical elements for the success of SMRs. Studies by the US government evaluating the risks associated with SMRs have led to challenges licensing and deploying them.

Advantages

The main SMR advantage is that they can be manufactured and assembled at a central factory location. They can then be sent to their deployment site and be installed with little difficulty. However, SMR module transport is critical and needs further studies.

Another advantage is that a user can install their first unit, instantly generating revenue and cash flows, then later add other reactors as necessary — cutting back on financing times and saving on multi-year construction processes.

Some larger SMRs require more significant on-site construction, such as the 440 MWe 3-loop Rolls-Royce SMR. The firm is targeting a 500-day construction time.

SMR reactors have a much smaller footprint, e.g. the Rolls-Royce SMR reactor takes 40.000m2 instead of 400.000m2 for a traditional plant.

SMRs can be deployed essentially anywhere. Containment is more efficient, and proliferation concerns are much less. SMRs are more flexible and do not need to be hooked into the local power grid.

Electricity needs in remote locations are usually small and variable. Large plants produce so much power that they require a large grid to distribute their output. SMRs have a load-following design so that when electricity demands are low they can produce less electricity.

Many SMRs are designed to use new fuel ideas that allow for higher burnup and longer fuel cycles. Longer refueling intervals can decrease proliferation risks and lower chances of radiation escaping containment. For reactors in remote areas, accessibility can be troublesome, so longer fuel life can be helpful.

SMRs can power significant users of energy, such as large vessels or production facilities (e.g. water treatment/purification, or mines). Remote locations may have difficulty finding efficient, reliable energy sources. Small nuclear reactors may solve energy problems in many hard-to-reach places. Cogeneration is an option.

Because of the lack of trained personnel available in remote areas, SMRs have to be inherently safe. Many SMRs use passive or inherent safety features. Passive safety features are engineered, but do not require human input to work. A pressure release valve may have a spring that can be pushed back when pressure gets too high. Inherent safety features require no moving parts to work, depending on physical laws.

Types

A nuclear fission chain is required to generate nuclear power.

SMRs come in multiple designs. Some are simplified versions of current reactors, others involve entirely new technologies. All proposed SMRs use nuclear fission. SMR designs include thermal-neutron reactors and fast-neutron reactors.

Thermal-neutron reactors

Thermal-neutron reactors rely on a moderator to slow neutrons and generally use 235
U
as fissile material. Most operating reactors are of this type.

Fast reactors

Fast reactors don't use moderators. Instead they rely on the nuclear fuel to absorb higher speed neutrons. This usually means changing the fuel arrangement within the core, or using different fuels. E.g., 239
Pu
is more likely to absorb a high-speed neutron than 235
U
.

Fast reactors can be breeder reactors. These reactors release enough neutrons to transmute non-fissionable elements into fissionable ones. A common use for a breeder reactor is to surround the core in a "blanket" of 238
U
, the most easily found isotope. Once the 238
U
undergoes a neutron absorption reaction, it becomes 239
Pu
, which can be removed from the reactor during refueling, and used as fuel once it has been prepared.

Cooling

Conventional reactors use water as a coolant. SMRs may use water, liquid metal, gas and molten salt as coolants.

Thermal/electrical generation

Traditionally, nuclear reactors use a coolant loop to heat water into steam, and use that steam to run turbines to generate electricity. Some gas-cooled reactor designs are meant to drive a gas-powered turbine, rather than boil water. Thermal energy can be used directly, without conversion. Heat can be used in hydrogen production and other commercial operations, such as desalination and the production of petroleum products (extracting oil from tar sands, creating synthetic oil from coal, etc.).

Staffing

Several SMR developers claimed that their designs would require fewer staff members because of the inherent/passive safety systems. Reactors such as the Toshiba 4S are designed to run with little supervision.

Load following

Nuclear plants have been historically deployed to cover the base load of the electricity demand.

Some plants might perform daily load cycling (i.e. load following) at between 50% and 100% of their rated power. adjusting output, "Load Following via Cogeneration" runs the reactor at a constant level, while diverting any excess power to an auxiliary use. A suitable cogeneration system needs:

  • demand of electricity and/or heat in the region of 500 MWe–1.5 GWt;
  • market demand;
  • access to adequate input to process;
  • flexibility: cogeneration might operate at full load during the night when the request of electricity is low, and be turned off during the daytime.

Economically, it is essential that the investment in the auxiliary system be profitable. District heating, desalination and hydrogen have been proposed as technically and economically feasible options. SMR can be ideal for desalination over night.

Waste reduction

Many SMRs are fast reactors that are designed to have higher fuel burnup rates, reducing the amount of waste. At higher neutron energy more fission products can be usually tolerated. As mentioned before, some SMRs are also breeder reactors that "burn" 235
U
, but convert fertile materials such as 238
U
(which occurs naturally at a much higher concentration than 235
U
) into usable fuels.

Some reactors are designed to run on the thorium fuel cycle, which offers significantly reduced long-term waste radiotoxicity compared to the uranium cycle.

The traveling wave reactor uses the fuel that it breeds. It eliminates the need to remove the spent fuel and "clean" it before reusing any newly bred fuel.

Safety

Diverse safety features can be involved, depending on reactor design. Coolant systems can use natural circulation – convection – to eliminate pumps that could break down, and they keep removing decay heat after the reactor shuts down, so that the core doesn't overheat and melt. Negative temperature coefficients in the moderators and the fuels keep the fission reactions under control, causing the reaction to slow as temperature increases. While passive control is a key selling point, a functioning reactor may also need an active cooling system to back up the passive system, at higher cost. Additionally, SMR designs have less need for containment structures.

Some SMR designs site the reactor and spent-fuel storage pools underground. Smaller reactors would be easier to upgrade quickly and have better passive quality controls.

Economics

A key driver of SMRs are the claimed economies of scale, compared to larger reactors, that stem from the ability to prefabricate them in a manufacturing plant/factory. Some studies instead find the capital cost of SMRs to be practically equivalent to larger reactors. A key disadvantage is that the improved affordability can only be realised if the factory is built in the first place, and this is likely to require initial orders for 40–70 units.

Another economic advantage is that the construction cost is much less than that of constructing a much more complex, non-modular, large nuclear plant. This makes SMR a smaller-risk venture for power companies than other nuclear power plants. However, modularisation and modularity influence the economic competitiveness of SMRs. Financial and economic issues can hinder SMR construction.

Staffing costs per unit output increase as reactor size decreases, due because some costs are fixed. SMR staff costs per unit output can be as much as 190% higher than the fixed operating cost of large reactors.

In 2017 an Energy Innovation Reform Project study of eight companies looked at reactor models with capacity between 47.5 MWe and 1,648 MWe in development. The study reported average capital cost of $3,782/kW, average operating cost total of $21/MWh and levelized cost of electricity of $60/MWh.

Energy Impact Center founder Bret Kugelmass claimed that thousands of SMRs could be built in parallel, "thus reducing costs associated with long borrowing times for prolonged construction schedules and reducing risk premiums currently linked to large projects." GE Hitachi Nuclear Energy Executive Vice President Jon Ball agreed, saying the modular elements of SMRs would also help reduce costs associated with extended construction times.

Licensing

A major barrier is the licensing process, historically developed for large reactors, preventing the simple deployment of several identical units in different countries. In particular the US Nuclear Regulatory Commission process for licensing has focused mainly on large commercial reactors. The design and safety specifications, staffing requirements and licensing fees have all been geared toward reactors with an electrical output of more than 700MWe.

Licensing for SMRs has been an ongoing discussion. There was a workshop in October 2009 about licensing difficulties and another in June 2010, with a US congressional hearing in May 2010. With growing worries about climate change and greenhouse gas emissions, added to problems with hydrocarbon supplies from foreign countries and accidents like the BP oil rig explosion in the Gulf of Mexico, many US government agencies are working to push the development of different licensing for SMRs. However, some argue that weakening safety regulations to push the development of SMRs may cancel out their enhanced safety characteristics.

The U.S. Advanced Reactor Demonstration Program will help license and build two prototype SMRs during the 2020s, with up to $4 billion of government funding support.

Non-proliferation

Nuclear proliferation, or the use of nuclear materials to create weapons, is a concern for small modular reactors. As SMRs have lower generation capacity and are physically small, they are intended to be deployed in many more locations than existing nuclear plants. This means both at more sites in existing nuclear power states, and in more countries that previously did not have nuclear plants. It is also intended that SMR sites have much lower staffing levels than current nuclear plants. Because of the increased number of sites, with fewer staff, physical protection and security becomes an increased challenge which could increase proliferation risks.

Many SMRs are designed to lessen the danger of materials being stolen or misplaced. Nuclear reactor fuel can be low-enriched uranium, with a concentration of less than 20% of fissile 235
U
. This low quantity, non-weapons-grade uranium makes the fuel less desirable for weapons production. Once the fuel has been irradiated, the fission products mixed with the fissile materials are highly radioactive and require special handling to remove safely, another non-proliferation feature.

Some SMR designs are intended to have lifetime cores so the SMRs do not need refuelling. This improves proliferation resistance by not requiring any on-site nuclear fuel handling. But it also means that there will be large inventories of fissile material within the SMRs to sustain a long lifetime, which could make it a more attractive proliferation target. A 200 MWe 30-year core life light water SMR could contain about 2.5 tonnes of plutonium toward the end of its working life.

Light-water reactors designed to run on the thorium fuel cycle offer increased proliferation resistance compared to conventional uranium cycle, though molten salt reactors have a substantial risk.

The modular construction of SMRs is another useful feature. Because the reactor core is often constructed completely inside a central manufacturing facility, fewer people have access to the fuel before and after irradiation.

Reactor designs

Numerous new reactor designs have been proposed across the world. A small selection of the most notable current SMR designs is listed below.

  Design   Licensing   Under construction   Operational   Cancelled   Retired

List of small nuclear reactor designs
Name Gross power (MWe) Type Producer Country Status
4S 10–50 SFR Toshiba Japan Detailed design
ABV-6 6–9 PWR OKBM Afrikantov Russia Detailed design
ACP100 125 PWR China National Nuclear Corporation China Under Construction 
TMSR-LF1 10MW MSR China National Nuclear Corporation China Under Construction
ARC-100 100 SFR ARC Nuclear Canada Design: Vendor design review. One unit approved for construction at Point Lepreau Nuclear Generating Station in December 2019.
MMR 5 MSR Ultra Safe Nuclear Corp. Canada Licensing stage 
ANGSTREM 6 LFR OKB Gidropress Russia Conceptual design
B&W mPower 195 PWR Babcock & Wilcox United States Cancelled in March 2017
BANDI-60 60 PWR (floating) KEPCO South Korea Detailed design
BREST-OD-300 300 LFR Atomenergoprom Russia Under construction
BWRX-300 300 ABWR GE Hitachi Nuclear Energy United States Licensing stage
CAREM 27–30 PWR CNEA Argentina Under construction
Copenhagen Atomics Waste Burner 50 MSR Copenhagen Atomics Denmark Conceptual design
CMSR 100 MSR Seaborg Technologies Denmark Conceptual design
EGP-6 11 RBMK IPPE & Teploelektroproekt Design Russia Operating
(not actively marketed due to legacy design, will be taken out of operation permanently in 2021)
ELENA 0.068 PWR Kurchatov Institute Russia Conceptual design
Energy Well 8.4 MSR cs:Centrum výzkumu Řež Czechia Conceptual design
Flexblue 160 PWR Areva TA / DCNS group France Conceptual design
Fuji MSR 200 MSR International Thorium Molten Salt Forum (ITMSF) Japan Conceptual design
GT-MHR 285 GTMHR OKBM Afrikantov Russia Conceptual design completed
G4M 25 LFR Gen4 Energy United States Conceptual design
GT-MHR 50 GTMHR General Atomics, Framatom United States,France Conceptual design
IMSR400 185–192 MSR Terrestrial Energy Canada Conceptual design
TMSR-500 500 MSR ThorCon Indonesia Conceptual design
IRIS 335 PWR Westinghouse-led international Design (Basic)
KLT-40S 35 PWR OKBM Afrikantov Russia Operating
MHR-100 25–87 HTGR OKBM Afrikantov Russia Conceptual design
MHR-T 205.5x4 HTGR OKBM Afrikantov Russia Conceptual design
MRX 30–100 PWR JAERI Japan Conceptual design
NP-300 100–300 PWR Areva TA France Conceptual design
NuScale 45 PWR NuScale Power LLC United States Licensing stage
Nuward 300–400 PWR consortium France Conceptual design, construction anticipated in 2030
PBMR-400 165 HTGR Eskom South Africa Cancelled. Postponed indefinitely
RITM-200 50 PWR OKBM Afrikantov Russia Operational since October 2019
Rolls-Royce SMR 440 PWR Rolls-Royce United Kingdom Design stage
SEALER 55 LFR LeadCold Sweden Design stage
SMART 100 PWR KAERI South Korea Licensed
SMR-160 160 PWR Holtec International United States Conceptual design
SVBR-100 100 LFR OKB Gidropress Russia Detailed design
SSR-W 300–1000 MSR Moltex Energy United Kingdom Conceptual design
S-PRISM 311 FBR GE Hitachi Nuclear Energy United States/Japan Detailed design
TerraPower 10 TWR Intellectual Ventures United States Conceptual design
U-Battery 4 HTGR U-Battery consortium United Kingdom Design and development work
VBER-300 325 PWR OKBM Afrikantov Russia Licensing stage
VK-300 250 BWR Atomstroyexport Russia Detailed design
VVER-300 300 BWR OKB Gidropress Russia Conceptual design
Westinghouse SMR 225 PWR Westinghouse Electric Company United States Cancelled. Preliminary design completed.
Xe-100 80 HTGR X-energy United States Conceptual design development
Updated as of 2014. Some reactors are not included in IAEA Report. Not all IAEA reactors are listed there are added yet and some are added (anno 2021) that were not yet listed in the now dated IAEA report.

Proposed sites

Canada

In 2018, the Canadian province of New Brunswick announced it would invest $10 million to attract SMR research to New Brunswick with a potential site for a demonstration project at the Point Lepreau Nuclear Generating Station. It was later announced that SMR proponents Advanced Reactor Concepts and Moltex would open offices in New Brunswick with the potential of developing sites at Lepreau.

On 1 December 2019, the Premiers of Ontario, New Brunswick and Saskatchewan signed a memorandum of understanding  "committing to collaborate on the development and deployment of innovative, versatile and scalable nuclear reactors, known as Small Modular Reactors (SMRs)." They were later joined by Alberta in August 2020.

China

In July 2019 China National Nuclear Corporation announced it would start building a demonstration ACP100 SMR on the north-west side of the existing Changjiang Nuclear Power Plant by the end of the year.

On 7 June 2021, the construction of a demonstration ACP100 small modular reactor (SMR) at Changjiang in Hainan province has been approved by China's National Development and Reform Commission.

In July 2021 China National Nuclear Corporation (CNNC) has started construction of the first commercial onshore nuclear project using its homegrown “Linglong One” small modular reactor (SMR) design.

Poland

Polish chemical company Synthos declared plans to deploy a Hitachi BWRX-300 reactor (300 MW) in Poland by 2030. A feasibility study for the project was completed in December 2020 and licensing process started with Polish National Atomic Energy Agency.

United Kingdom

In 2016 it was reported that the UK Government was assessing sites for deploying SMRs in Wales - including the former Trawsfynydd nuclear power station - and on the site of former nuclear or coal-fired power stations in Northern England. Existing nuclear sites including Bradwell, Hartlepool, Heysham, Oldbury, Sizewell, Sellafield and Wylfa are thought to be possibilities. The target cost for a 440 MWe Rolls-Royce SMR unit is £1.8 billion for the fifth unit built. In 2020 it was reported that Rolls-Royce has plans to construct up to 16 SMRs in the UK. In 2019, the company received £18 million to begin designing the modular system, and the BBC claims that the government will provide an additional £200 million for the project as a part of its green plan for economic recovery.

United States

In December 2019 the Tennessee Valley Authority was authorized to receive an Early Site Permit (ESP) by the Nuclear Regulatory Commission for potentially siting an SMR at its Clinch River Site in Tennessee. This ESP will be valid for up to 20 years, and addresses site safety, environmental protection and emergency preparedness associated. TVA has not made a technology selection so this ESP is applicable for any of the light-water reactor SMR designs under development in the United States.

The Utah Associated Municipal Power Systems (UAMPS) announced a teaming partnership with Energy Northwest to explore siting a NuScale Power reactor in Idaho, possibly on the Department of Energy's Idaho National Laboratory.

The Galena Nuclear Power Plant in Galena, Alaska was a proposed micro nuclear reactor installation intended to reduce the costs and environmental pollution required to power the town. It was a potential deployment for the Toshiba 4S reactor.

 

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