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Wednesday, May 17, 2023

Oak Ridge National Laboratory

From Wikipedia, the free encyclopedia
 
Oak Ridge National Laboratory
Oak Ridge National Laboratory official logo.png
Oak Ridge National Laboratory Aerial View.jpg
Aerial view of ORNL's main campus in 2014
 
Motto"Solving Big Problems"
Established1943; 80 years ago
Research typeMultidisciplinary
BudgetUS$2.4 billion
Field of research
DirectorJeff Smith
Staff5,700
LocationOak Ridge, Tennessee, United States
35.93°N 84.31°WCoordinates: 35.93°N 84.31°W
CampusORNL occupies about 10,000 acres (40 km2) of the approximately 35,000 acres (140 km2) Oak Ridge Reservation
AffiliationsUnited States Department of Energy (DOE)
Operating agency
UT–Battelle
Websiteornl.gov

Oak Ridge National Laboratory (ORNL) is a federally funded research and development center in Oak Ridge, Tennessee, United States. Founded in 1943, the laboratory is now sponsored by the United States Department of Energy and administered by UT–Battelle, LLC.

Established in 1943, ORNL is the largest science and energy national laboratory in the Department of Energy system (by size) and third largest by annual budget. It is located in the Roane County section of Oak Ridge, Tennessee. Its scientific programs focus on materials, nuclear science, neutron science, energy, high-performance computing, systems biology and national security, sometimes in partnership with the state of Tennessee, universities and other industries.

ORNL has several of the world's top supercomputers, including Frontier, ranked by the TOP500 as the world's most powerful. The lab is a leading neutron and nuclear power research facility that includes the Spallation Neutron Source, the High Flux Isotope Reactor, and the Center for Nanophase Materials Sciences.

Overview

Oak Ridge National Laboratory is managed by UT–Battelle, a limited liability partnership between the University of Tennessee and the Battelle Memorial Institute, formed in 2000 for that purpose. The annual budget is US$2.4 billion. As of 2021 there is a staff of 5,700 working at ORNL, around 2,000 of whom are scientists and engineers, and an additional 3,200 guest researchers annually.

There are five campuses on the Department of Energy's Oak Ridge reservation: the National Laboratory, the Y-12 National Security Complex, the East Tennessee Technology Park (formerly the Oak Ridge Gaseous Diffusion Plant), the Oak Ridge Institute for Science and Education, and the developing Oak Ridge Science and Technology Park, although the four other facilities are unrelated to the National Laboratory. The total area of the reservation 150 square kilometres (58 sq mi) of which the lab takes up 18 square kilometres (7 sq mi).

History

Workers in 1943 loading uranium slugs into the X-10 Graphite Reactor (now a National Historic Landmark)

In 1934, the Freel Farm Mound Site, an archaeological site and burial mound of the Late Woodland period was excavated.

The city of Oak Ridge was established by the Army Corps of Engineers as part of the Clinton Engineer Works in 1942 on isolated farm land as part of the Manhattan Project. During the war, advanced research for the government was managed at the site by the University of Chicago's Metallurgical Laboratory. In 1943, construction of the "Clinton Laboratories" was completed, later renamed to "Oak Ridge National Laboratory". The site was chosen for the X-10 Graphite Reactor, used to produce plutonium from natural uranium for the Manhattan project. Enrico Fermi and his colleagues developed the world's second self-sustaining nuclear reactor after Fermi's previous experiment, the Chicago Pile-1. The X-10 was the first reactor designed for continuous operation. After the end of World War II the demand for weapons-grade plutonium fell and the reactor and the laboratory's 1,000 employees were no longer involved in nuclear weapons. Instead, it was used for scientific research. In 1946 the first medical isotopes were produced in the X-10 reactor, and by 1950 almost 20,000 samples had been shipped to various hospitals. As the demand for military science had fallen dramatically, the future of the lab was uncertain. Management of the lab was contracted by the US government to Monsanto; however, they withdrew in 1947. The University of Chicago re-assumed responsibility, until in December 1947, when Union Carbide and Carbon Co., which already operated two other facilities at Oak Ridge, took control of the laboratory. Alvin Weinberg was named Director of Research, ORNL, and in 1955 Director of the Laboratory.

In 1950 the Oak Ridge School of Reactor Technology was established with two courses in reactor operation and safety; almost 1,000 students graduated. Much of the research performed at ORNL in the 1950s was related to nuclear reactors as a form of energy production, both for propulsion and electricity. More reactors were built in the 1950s than in the rest of the ORNL's history combined.

Another project was the world's first light water reactor. With its principles of neutron moderation and fuel cooling by ordinary water, it is the direct ancestor of most modern nuclear power stations. The US Military funded much of its development, for nuclear-powered submarines and ships of the US Navy.

The US Army contracted portable nuclear reactors in 1953 for heat and electricity generation in remote military bases. The reactors were designed at ORNL, produced by American Locomotive Company and used in Greenland, the Panama Canal Zone and Antarctica. The United States Air Force (USAF) also contributed funding to three reactors, the lab's first computers, and its first particle accelerators. ORNL designed and tested a nuclear-powered aircraft in 1954 as a proof-of-concept for a proposed USAF fleet of long-range bombers, although it never flew.

The provision of radionuclides by X-10 for medicine grew steadily in the 1950s with more isotopes available. ORNL was the only Western source of californium-252. ORNL scientists lowered the immune systems of mice and performed the world's first successful bone marrow transplant.

Cayce Pentecost, Lyndon B. Johnson, Buford Ellington and Albert Gore Sr. operating mechanical hands at a hot cell at Oak Ridge, on October 19, 1958.
 
S.R. Sapirie, Senator Albert Gore Sr., Senator Lyndon Johnson and Dr.John Swartout looking at a model of a graphite reactor at Oak Ridge National Lab, on October 19, 1958.

In the early 1960s there was a large push at ORNL to develop nuclear-powered desalination plants, where deserts met the sea, to provide water. The project, called Water for Peace, was backed by John F. Kennedy and Lyndon B. Johnson, and presented at a 1964 United Nations conference, but increases in the cost of construction and falling public confidence in nuclear power caused the plan to fail. The Health Physics Research Reactor built in 1962 was used for radiation exposure experiments leading to more accurate dosage limits and dosimeters, and improved radiation shielding.

In 1964 the Molten-Salt Reactor Experiment began with the construction of the reactor. It was operated from 1966 until 1969 (with six months down time to move from U-235 to U-233 fuel), and proved the viability of molten salt reactors, while also producing fuel for other reactors as a byproduct of its own reaction.

The High Flux Isotope Reactor built in 1965 had the highest neutron flux of any reactor at the time. It improved upon the work of the X-10 reactor, producing more medical isotopes, as well as allowing higher fidelity of materials research.

Researchers in the Biology Division studied the effects of chemicals on mice, including petrol fumes, pesticides, and tobacco.

In the late 1960s, cuts in funding led to the cancellation of plans for another particle accelerator, and the United States Atomic Energy Commission cut the breeder reactor program by two-thirds, leading to a downsizing in staff from 5000 to 3800.

The inside of ORMAK, an early tokamak, was gold plated for reflectivity

In the 1970s, the prospect of fusion power was strongly considered, sparking research at ORNL. A tokamak called ORMAK, made operational in 1971, was the first tokamak to achieve a plasma temperature of 20 million Kelvin. After the success of the fusion experiments, it was enlarged and renamed ORMAK II in 1973; however, the experiments ultimately failed to lead to fusion power plants.

The US Atomic Energy Commission required improved safety standards in the early 1970s for nuclear reactors, so ORNL staff wrote almost 100 requirements covering many factors including fuel transport and earthquake resistance. In 1972 the AEC held a series of public hearings where emergency cooling requirements were highlighted and the safety requirements became more stringent.

ORNL was involved in analysing the damage to the core of the Three Mile Island Nuclear Generating Station after the accident in 1979.

Also in 1972, Peter Mazur, a biologist at ORNL, froze with liquid nitrogen, thawed and implanted mouse embryos in a surrogate mother. The mouse pups were born healthy. The technique is popular in the livestock industry, as it allows the embryos of valuable cattle to be transported easily and a prize cow can have multiple eggs extracted and thus, through in vitro fertilisation, have many more offspring than would naturally be possible.

In 1974 Alvin Weinberg, director of the lab for 19 years, was replaced by Herman Postma, a fusion scientist.

In 1977 construction began for 6 metre (20 foot) superconducting electromagnets, intended to control fusion reactions. The project was an international effort: three electromagnets were produced in the US, one in Japan, one in Switzerland and the final by remaining European states. Experimentation continued into the 1980s.

The 1980s brought more changes to ORNL: a focus on efficiency became paramount.

An accelerated climate simulation chamber was built that applied varying weather conditions to insulation to test its efficacy and durability faster than real time. Materials research into heat resistant ceramics for use in truck and high-tech car engines was performed, building upon the materials research that began in the nuclear reactors of the 1950s. In 1987 the High Temperature Materials Laboratory was established, where ORNL and industry researchers cooperated on ceramic and alloy projects. The materials research budget at ORNL doubled after initial uncertainty regarding Reagan's economic policy of less government expenditure.

In 1981, the Holifield Heavy Ion Research Facility, a 25 MV particle accelerator, was opened at ORNL. At the time, Holifield had the widest range of ion species and was twice as powerful as other accelerators, attracting hundreds of guest researchers each year.

The Department of Energy was concerned with the pollution surrounding ORNL and it began clean-up efforts. Burial trenches and leaking pipes had contaminated the groundwater beneath the lab, and radiation tanks were sitting idle, full of waste. Estimates of the total cost of clean-up were into the hundreds of millions of US dollars.

The five older reactors were subjected to safety reviews in 1987, ordered to be deactivated until the reviews were complete. By 1989 when the High Flux Isotope Reactor was restarted the US supply of certain medical isotopes was depleted.

In 1989 the former executive officer of the American Association for the Advancement of Science, Alvin Trivelpiece, became director of ORNL; he remained in the role until 2000.

In 1992, a whistleblower, Charles Varnadore, filed complaints against ORNL, alleging safety violations and retaliation by his superiors. While an administrative law judge ruled in Varnadore's favor, the Secretary of Labor, Robert Reich, overturned that ruling. However, Varnadore's case saw prime contractor Martin Marietta cited for safety violations, and ultimately led to additional whistleblower protection within DOE.

In January 2019 ORNL announced a major breakthrough in its capacity to automate Pu-238 production which helped push annual production from 50 grams to 400 grams, moving closer to NASA's goal of 1.5 kilograms per year by 2025 in order to sustain its space exploration programs.

Areas of research

ORNL conducts research and development activities that span a wide range of scientific disciplines. Many research areas have a significant overlap with each other; researchers often work in two or more of the fields listed here. The laboratory's major research areas are described briefly below.

  • Chemical sciences – ORNL conducts both fundamental and applied research in a number of areas, including catalysis, surface science and interfacial chemistry; molecular transformations and fuel chemistry; heavy element chemistry and radioactive materials characterization; aqueous solution chemistry and geochemistry; mass spectrometry and laser spectroscopy; separations chemistry; materials chemistry including synthesis and characterization of polymers and other soft materials; chemical biosciences; and neutron science.
  • Electron microscopy – ORNL's electron microscopy program investigates key issues in condensed matter, materials, chemical and nanosciences.
  • Nuclear medicine – The laboratory's nuclear medicine research is focused on the development of improved reactor production and processing methods to provide medical radioisotopes, the development of new radionuclide generator systems, the design and evaluation of new radiopharmaceuticals for applications in nuclear medicine and oncology.
  • Physics – Physics research at ORNL is focused primarily on studies of the fundamental properties of matter at the atomic, nuclear, and subnuclear levels and the development of experimental devices in support of these studies.
  • Population – ORNL provides federal, state and international organizations with a gridded population database, called Landscan, for estimating ambient population. LandScan is a raster image, or grid, of population counts, which provides human population estimates every 30 x 30 arc seconds, which translates roughly to population estimates for 1 kilometer square windows or grid cells at the equator, with cell width decreasing at higher latitudes. Though many population datasets exist, LandScan is the best spatial population dataset, which also covers the globe. Updated annually (although data releases are generally one year behind the current year) offers continuous, updated values of population, based on the most recent information. Landscan data are accessible through GIS applications and a USAID public domain application called Population Explorer.

Energy

The laboratory has a long history of energy research; nuclear reactor experiments have been conducted since the end of World War II in 1945. Because of the availability of reactors and high-performance computing resources an emphasis on improving the efficiency of nuclear reactors is present. The programs develop more efficient materials, more accurate simulations of aging reactor cores, sensors and controls as well as safety procedures for regulatory authorities.

The Energy Efficiency and Electricity Technologies Program (EEETP) aims to improve air quality in the US and reduce dependence on foreign oil supplies. There are three key areas of research; electricity, manufacturing and mobility. The electricity division focuses on reducing electricity consumption and finding alternative sources for production. Buildings, which account for 39% of US electricity consumption as of 2012, are a key area of research as the program aims to create affordable, carbon-neutral homes by 2020. Research also takes place into higher efficiency solar panels, geothermal electricity and heating, lower cost wind generators and the economic and environmental feasibility of potential hydro power plants.

Fusion is another area with a history of research at ORNL, dating back to the 1950s. The Fusion Energy Division pursues short-term goals to develop components such as high temperature superconductors, high-speed hydrogen pellet injectors and suitable materials for future fusion research. Much research into the behaviour and maintenance of a plasma takes place at the Fusion Energy Division to further the understanding of plasma physics, a crucial area for developing a fusion power plant. The US ITER office is at ORNL with partners at Princeton Plasma Physics Laboratory and Savannah River National Laboratory. The US contribution to the ITER project is 9.1% which is expected to be in excess of US$1.6 billion throughout the contract. ORNL researchers participated in developing of an extensive research plan for the US-ITER collaboration detailed in 2022.

Biology

Oak Ridge National Laboratory's biological research covers genomics, computational biology, structural biology and bioinformatics. The BioEnergy Program aims to improve the efficiency of all stages of the biofuel process to improve the energy security of the United States. The program aims to make genetic improvements to the potential biomass used, formulate methods for refineries that can accept a diverse range of fuels and to improve the efficiency of energy delivery both to power plants and end users.

The Center for Molecular Biophysics conducts research into the behaviour of biological molecules in various conditions. The center hosts projects that examine cell walls for biofuel production, use neutron scattering to analyse protein folding and simulate the effect of catalysis on a conventional and quantum scale.

Neutron science

There are two neutron sources at ORNL; the High Flux Isotope Reactor (HFIR) and the Spallation Neutron Source. HFIR provides neutrons in a stable beam resulting from a constant nuclear reaction whereas SNS, a particle accelerator, produces pulses of neutrons. HFIR went critical in 1965 and has been used for materials research and as a major source of medical radioisotopes since. As of 2013, HFIR provides the world's highest constant neutron flux as a result of various upgrades. Berkelium-249, used to synthesize tennessine for the first time, was produced in the High Flux Isotope Reactor as part of an international effort. HFIR is likely to operate until approximately 2060 before the reactor vessel is considered unsafe for continued use.

The Spallation Neutron Source (SNS) is a particle accelerator that has the highest intensity neutron pulses of any human-made neutron source. SNS was made operational in 2006 and has since been upgraded to 1 megawatt with plans to continue up to 3 megawatts. High power neutron pulses permit clearer images of the targets meaning smaller samples can be analysed and accurate results require fewer pulses.

Materials

The Advanced Microscopy Laboratory at ORNL

Oak Ridge National Laboratory conducts research into materials science in a range of areas. Between 2002 and 2008 ORNL partnered with Caterpillar Inc. (CAT) to form a new material for their diesel engines that can withstand large temperature fluctuations. The new steel, named CF8C Plus, is based on conventional CF8C stainless steel with added manganese and nitrogen; the result has better high–temperature properties and is easier to cast at a similar cost. In 2003 the partners received an R&D 100 award from R&D magazine and in 2009 received an award for "excellence in technology transfer" from the Federal Laboratory Consortium for the commercialisation of the steel.

There is a high-temperature materials lab at ORNL that permits researchers from universities, private companies and other government initiatives to use their facilities. As is the case for all designated user facilities, the resources of the High Temperature Materials Laboratory are available for free if the results are published; private research is permitted but requires payment.

The Center for Nanophase Materials Sciences (CNMS) researches the behaviour and fabrication of nanomaterials. The center emphasises discovery of new materials and the understanding of underlying physical and chemical interactions that enable creation of nanomaterials. In 2012, CNMS produced a lithium-sulfide battery with a theoretical energy density three to five times greater than existing lithium ion batteries.

Security

Oak Ridge National Laboratory provides resources to the US Department of Homeland Security and other defense programs. The Global Security and Nonproliferation (GS&N) program develops and implements policies, both US based and international, to prevent the proliferation of nuclear material. The program has developed safeguards for nuclear arsenals, guidelines for dismantling arsenals, plans of action should nuclear material fall into unauthorised hands, detection methods for stolen or missing nuclear material and trade of nuclear material between the US and Russia. The GS&N's work overlaps with that of the Homeland Security Programs Office, providing detection of nuclear material and nonproliferation guidelines. Other areas concerning the Department Homeland Security include nuclear and radiological forensics, chemical and biological agent detection using mass spectrometry and simulations of potential national hazards.

High-performance computing

Summit, developed at ORNL, was the world's fastest supercomputer from November 2018 to June 2020.

Throughout the history of the Oak Ridge National Laboratory it has been the site of various supercomputers, home to the fastest on several occasions. In 1953, ORNL partnered with the Argonne National Laboratory to build ORACLE (Oak Ridge Automatic Computer and Logical Engine), a computer to research nuclear physics, chemistry, biology and engineering. ORACLE had 2048 words (80 Kibit) of memory and took approximately 590 microseconds to perform addition or multiplications of integers. In the 1960s ORNL was also equipped with an IBM 360/91 and an IBM 360/65. In 1995 ORNL bought an Intel Paragon based computer called the Intel Paragon XP/S 150 that performed at 154 gigaFLOPS and ranked third on the TOP500 list of supercomputers. In 2005 Jaguar was built, a Cray XT3-based system that performed at 25 teraFLOPS and received incremental upgrades up to the XT5 platform that performed at 2.3 petaFLOPS in 2009. It was recognised as the world's fastest from November 2009 until November 2010. Summit was built for Oak Ridge National Laboratory during 2018, which benchmarked at 122.3 petaflops. As of June 2020, Summit was the world's second fastest [clocked] supercomputer with 202,752 CPU cores, 27,648 Nvidia Tesla GPUs and 250 Petabytes of storage, having lost the top position to the Japanese Fugaku supercomputer. In May 2022, the ORNL Frontier system broke the exascale barrier, achieving 1.102 exaflop/s using 8,730,112 cores.

Since 1992 the Center for Computational Sciences (CCS) has overseen high performance computing at ORNL. It manages the Oak Ridge Leadership Computing Facility that contains the machines. In 2012, Jaguar was upgraded to the XK7 platform, a fundamental change as GPUs are used for the majority of processing, and renamed Titan. Titan performed at 17.59 petaFLOPS and held the number 1 spot on the TOP500 list for November 2012. Other computers include a 77 node cluster to visualise data that the larger machines output in the Exploratory Visualization Environment for Research in Science and Technology (EVEREST), a visualisation room with a 10 by 3 metre (30 by 10 ft) wall that displays 35 megapixel projections. Smoky is an 80 node linux cluster used for application development. Research projects are refined and tested on Smoky before running on larger machines such as Titan.

In 1989 programmers at the Oak Ridge National Lab wrote the first version of Parallel Virtual Machine (PVM), software that enables distributed computing on machines of differing specifications. PVM is free software and has become the de facto standard for distributed computing. Jack Dongarra of ORNL and the University of Tennessee wrote the LINPACK software library and LINPACK benchmarks, used to calculate linear algebra and the standard method of measuring floating point performance of a supercomputer as used by the TOP500 organisation.

History of nuclear power

From Wikipedia, the free encyclopedia

This is a history of nuclear power as realized through the first artifical fission of atoms that would lead to the Manhattan Project and, eventually, to using nuclear fission to generate electricity.

Origins

In 1932, physicists John Cockcroft, Ernest Walton, and Ernest Rutherford discovered that when lithium atoms were "split" by protons from a proton accelerator, immense amounts of energy were released in accordance with the principle of mass–energy equivalence. However, they and other nuclear physics pioneers Niels Bohr and Albert Einstein believed harnessing the power of the atom for practical purposes anytime in the near future was unlikely. The same year, Rutherford's doctoral student James Chadwick discovered the neutron. Experiments bombarding materials with neutrons led Frédéric and Irène Joliot-Curie to discover induced radioactivity in 1934, which allowed the creation of radium-like elements. Further work by Enrico Fermi in the 1930s focused on using slow neutrons to increase the effectiveness of induced radioactivity. Experiments bombarding uranium with neutrons led Fermi to believe he had created a new transuranic element, which was dubbed hesperium.

In 1938, German chemists Otto Hahn and Fritz Strassmann, along with Austrian physicist Lise Meitner and Meitner's nephew, Otto Robert Frisch, conducted experiments with the products of neutron-bombarded uranium, as a means of further investigating Fermi's claims. They determined that the relatively tiny neutron split the nucleus of the massive uranium atoms into two roughly equal pieces, contradicting Fermi. This was an extremely surprising result; all other forms of nuclear decay involved only small changes to the mass of the nucleus, whereas this process—dubbed "fission" as a reference to biology—involved a complete rupture of the nucleus. Numerous scientists, including Leó Szilárd, who was one of the first, recognized that if fission reactions released additional neutrons, a self-sustaining nuclear chain reaction could result. Once this was experimentally confirmed and announced by Frédéric Joliot-Curie in 1939, scientists in many countries (including the United States, the United Kingdom, France, Germany, and the Soviet Union) petitioned their governments for support of nuclear fission research, just on the cusp of World War II, for the development of a nuclear weapon.

First nuclear reactor

The first light bulbs ever lit by electricity generated by nuclear power at EBR-1 at Argonne National Laboratory-West, December 20, 1951. As the first liquid metal cooled reactor, it demonstrated Fermi's breeder reactor principle to maximize the energy obtainable from natural uranium, which at that time was considered scarce.

In the United States, where Fermi and Szilárd had both emigrated, the discovery of the nuclear chain reaction led to the creation of the first man-made reactor, the research reactor known as Chicago Pile-1, which achieved criticality on December 2, 1942. The reactor's development was part of the Manhattan Project, the Allied effort to create atomic bombs during World War II. It led to the building of larger single-purpose production reactors, such as the X-10 Pile, for the production of weapons-grade plutonium for use in the first nuclear weapons. The United States tested the first nuclear weapon in July 1945, the Trinity test, with the atomic bombings of Hiroshima and Nagasaki taking place one month later.

In August 1945, the first widely distributed account of nuclear energy, the pocketbook The Atomic Age, was released. It discussed the peaceful future uses of nuclear energy and depicted a future where fossil fuels would go unused. Nobel laureate Glenn Seaborg, who later chaired the United States Atomic Energy Commission, is quoted as saying "there will be nuclear powered earth-to-moon shuttles, nuclear powered artificial hearts, plutonium heated swimming pools for SCUBA divers, and much more".

In the same month, with the end of the war, Seaborg and others would file hundreds of initially classified patents, most notably Eugene Wigner and Alvin Weinberg's Patent #2,736,696, on a conceptual light water reactor (LWR) that would later become the United States' primary reactor for naval propulsion and later take up the greatest share of the commercial fission-electric landscape. The United Kingdom, Canada, and the USSR proceeded to research and develop nuclear energy over the course of the late 1940s and early 1950s.

Electricity was generated for the first time by a nuclear reactor on December 20, 1951, at the EBR-I experimental station near Arco, Idaho, which initially produced about 100 kW. In 1953, American President Dwight Eisenhower gave his "Atoms for Peace" speech at the United Nations, emphasizing the need to develop "peaceful" uses of nuclear power quickly. This was followed by the Atomic Energy Act of 1954 which allowed rapid declassification of U.S. reactor technology and encouraged development by the private sector.

The F-1 (from "First Physical Reactor") was a research reactor operated by the Kurchatov Institute in Moscow, Russia. When started on December 25, 1946, it became the first nuclear reactor in Europe to achieve a self-sustaining nuclear chain reaction.

Early years

The launching ceremony of the USS Nautilus January 1954. In 1958 it would become the first vessel to reach the North Pole.
 
The Calder Hall nuclear power station in the United Kingdom, the world's first commercial nuclear power station.
 
The 60 MWe Shippingport Atomic Power Station in Pennsylvania, the first commercial nuclear power plant in the United States.
 
Vessels size comparison of generation II reactor designs. The PWR is the most compact and has the highest power density, thus most suited to submarines.

The first organization to develop nuclear power was the U.S. Navy, with the S1W reactor for the purpose of propelling submarines and aircraft carriers. The first nuclear-powered submarine, USS Nautilus, was put to sea in January 1954. The S1W reactor was a Pressurized Water Reactor. This design was chosen because it was simpler, more compact, and easier to operate compared to alternative designs, thus more suitable to be used in submarines. This decision would result in the PWR being the reactor of choice also for power generation, thus having a lasting impact on the civilian electricity market in the years to come. The United States Navy Nuclear Propulsion design and operation community, under Rickover's style.

On June 27, 1954, the Obninsk Nuclear Power Plant in the USSR became the world's first nuclear power plant to generate electricity for a power grid, producing around 5 megawatts of electric power. The world's first commercial nuclear power station, Calder Hall at Windscale, England was connected to the national power grid on 27 August 1956. In common with a number of other generation I reactors, the plant had the dual purpose of producing electricity and plutonium-239, the latter for the nascent nuclear weapons program in Britain. It had an initial capacity of 50 MW per reactor (200 MW total), it was the first of a fleet of dual-purpose MAGNOX reactors.

The U.S. Army Nuclear Power Program formally commenced in 1954. Under its management, the 2 megawatt SM-1, at Fort Belvoir, Virginia, was the first in the United States to supply electricity in an industrial capacity to the commercial grid (VEPCO), in April 1957. The first commercial nuclear station to become operational in the United States was the 60 MW Shippingport Reactor (Pennsylvania), in December 1957. Originating from a cancelled nuclear-powered aircraft carrier contract, the plant used a PWR reactor design. Its early adoption, technological lock-in, and familiarity among retired naval personnel, established the PWR as the predominant civilian reactor design, that it still retains today in the United States.

In 1957 EURATOM was launched alongside the European Economic Community (the latter is now the European Union). The same year also saw the launch of the International Atomic Energy Agency (IAEA).

The first major accident at a nuclear reactor occurred at the 3 MW SL-1, a U.S. Army experimental nuclear power reactor at the National Reactor Testing Station, Idaho National Laboratory. It was derived from the Borax Boiling water reactor (BWR) design and it first achieved operational criticality and connection to the grid in 1958. For reasons unknown, in 1961 a technician removed a control rod about 22 inches farther than the prescribed 4 inches. This resulted in a steam explosion which killed the three crew members and caused a meltdown. The event was eventually rated at 4 on the seven-level INES scale. Another serious accident happened in 1968, when one of the two liquid-metal-cooled reactors on board the Soviet submarine K-27 underwent a fuel element failure, with the emission of gaseous fission products into the surrounding air. This resulted in 9 crew fatalities and 83 injuries.

Development and early opposition to nuclear power

Number of generating and under construction civilian fission-electric reactors, over the period 1960 to 2021.
 
Pressurized Water ReactorBoiling Water ReactorGas Cooled ReactorPressurized Heavy Water ReactorLWGRFast Breeder ReactorCircle frame.svg
  •   PWR: 277 (63.2%)
  •   BWR: 80 (18.3%)
  •   GCR: 15 (3.4%)
  •   PHWR: 49 (11.2%)
  •   LWGR: 15 (3.4%)
  •   FBR: 2 (0.5%)
Number of electricity generating civilian reactors by type (end 2014): 277 Pressurized Water Reactors, 80 Boiling Water Reactors, 15 Gas Cooled Reactors, 49 Pressurized Heavy Water Reactors (CANDU), 15 LWGR (RBMK), and 2 Fast Breeder Reactors.

The total global installed nuclear capacity initially rose relatively quickly, rising from less than 1 gigawatt (GW) in 1960 to 100 GW in the late 1970s, and 300 GW in the late 1980s. Since the late 1980s worldwide capacity has risen much more slowly, reaching 366 GW in 2005. Between around 1970 and 1990, more than 50 GW of capacity was under construction (peaking at over 150 GW in the late 1970s and early 1980s)—in 2005, around 25 GW of new capacity was planned. More than two-thirds of all nuclear plants ordered after January 1970 were eventually cancelled. A total of 63 nuclear units were canceled in the United States between 1975 and 1980.

In 1972 Alvin Weinberg, co-inventor of the light water reactor design (the most common nuclear reactors today) was fired from his job at Oak Ridge National Laboratory by the Nixon administration, "at least in part" over his raising of concerns about the safety and wisdom of ever larger scaling-up of his design, especially above a power rating of ~500 MWe, as in a loss of coolant accident scenario, the decay heat generated from such large compact solid-fuel cores was thought to be beyond the capabilities of passive/natural convection cooling to prevent a rapid fuel rod melt-down and resulting in then, potential far reaching fission product pluming. While considering the LWR, well suited at sea for the submarine and naval fleet, Weinberg did not show complete support for its use by utilities on land at the power output that they were interested in for supply scale reasons, and would request for a greater share of AEC research funding to evolve his team's demonstrated, Molten-Salt Reactor Experiment, a design with greater inherent safety in this scenario and with that an envisioned greater economic growth potential in the market of large-scale civilian electricity generation.

Similar to the earlier BORAX reactor safety experiments, conducted by Argonne National Laboratory, in 1976 Idaho National Laboratory began a test program focused on LWR reactors under various accident scenarios, with the aim of understanding the event progression and mitigating steps necessary to respond to a failure of one or more of the disparate systems, with much of the redundant back-up safety equipment and nuclear regulations drawing from these series of destructive testing investigations.

During the 1970s and 1980s rising economic costs (related to extended construction times largely due to regulatory changes and pressure-group litigation) and falling fossil fuel prices made nuclear power plants then under construction less attractive. In the 1980s in the U.S. and 1990s in Europe, the flat electric grid growth and electricity liberalization also made the addition of large new baseload energy generators economically unattractive.

Electricity production in France, previously dominated by fossil fuels, has been dominated by nuclear power since the early 1980s, and a large portion of that power is exported to neighboring countries.
  thermofossil
  hydroelectric
  nuclear
  Other renewables

The 1973 oil crisis had a significant effect on countries, such as France and Japan, which had relied more heavily on oil for electric generation (39% and 73% respectively) to invest in nuclear power. The French plan, known as the Messmer plan, was for the complete independence from oil, with an envisaged construction of 80 reactors by 1985 and 170 by 2000. France would construct 25 fission-electric stations, installing 56 mostly PWR design reactors over the next 15 years, though foregoing the 100 reactors initially charted in 1973, for the 1990s. In 2019, 71% of French electricity was generated by 58 reactors, the highest percentage by any nation in the world.

Some local opposition to nuclear power emerged in the U.S. in the early 1960s, beginning with the proposed Bodega Bay station in California, in 1958, which produced conflict with local citizens and by 1964 the concept was ultimately abandoned. In the late 1960s some members of the scientific community began to express pointed concerns. These anti-nuclear concerns related to nuclear accidents, nuclear proliferation, nuclear terrorism and radioactive waste disposal. In the early 1970s, there were large protests about a proposed nuclear power plant in Wyhl, Germany. The project was cancelled in 1975 the anti-nuclear success at Wyhl inspired opposition to nuclear power in other parts of Europe and North America. By the mid-1970s anti-nuclear activism gained a wider appeal and influence, and nuclear power began to become an issue of major public protest. In some countries, the nuclear power conflict "reached an intensity unprecedented in the history of technology controversies". In May 1979, an estimated 70,000 people, including then governor of California Jerry Brown, attended a march against nuclear power in Washington, D.C. Anti-nuclear power groups emerged in every country that had a nuclear power programme.

Globally during the 1980s one new nuclear reactor started up every 17 days on average.

Regulations, pricing and accidents

In the early 1970s, the increased public hostility to nuclear power in the United States lead the United States Atomic Energy Commission and later the Nuclear Regulatory Commission to lengthen the license procurement process, tighten engineering regulations and increase the requirements for safety equipment. Together with relatively minor percentage increases in the total quantity of steel, piping, cabling and concrete per unit of installed nameplate capacity, the more notable changes to the regulatory open public hearing-response cycle for the granting of construction licenses, had the effect of what was once an initial 16 months for project initiation to the pouring of first concrete in 1967, escalating to 32 months in 1972 and finally 54 months in 1980, which ultimately, quadrupled the price of power reactors.

Utility proposals in the U.S for nuclear generating stations, peaked at 52 in 1974, fell to 12 in 1976 and have never recovered, in large part due to the pressure-group litigation strategy, of launching lawsuits against each proposed U.S construction proposal, keeping private utilities tied up in court for years, one of which having reached the supreme court in 1978 (see Vermont Yankee Nuclear Power Corp. v. Natural Resources Defense Council, Inc. With permission to build a nuclear station in the U.S. eventually taking longer than in any other industrial country, the spectre facing utilities of having to pay interest on large construction loans while the anti-nuclear movement used the legal system to produce delays, increasingly made the viability of financing construction, less certain. By the close of the 1970s it became clear that nuclear power would not grow nearly as dramatically as once believed.

Over 120 reactor proposals in the United States were ultimately cancelled and the construction of new reactors ground to a halt. A cover story in the February 11, 1985, issue of Forbes magazine commented on the overall failure of the U.S. nuclear power program, saying it "ranks as the largest managerial disaster in business history".

According to some commentators, the 1979 accident at Three Mile Island played a major part in the reduction in the number of new plant constructions in many other countries. According to the Nuclear Regulatory Commission (NRC), the Three Mile Island accident was the most serious accident in "U.S. commercial nuclear power plant operating history, even though it led to no deaths or injuries to plant workers or members of the nearby community." The regulatory uncertainty and delays eventually resulted in an escalation of construction related debt that led to the bankruptcy of Seabrook's major utility owner, Public Service Company of New Hampshire. At the time, the fourth largest bankruptcy in United States corporate history.

Among American engineers, the cost increases from implementing the regulatory changes that resulted from the TMI accident were, when eventually finalized, only a few percent of total construction costs for new reactors, primarily relating to the prevention of safety systems from being turned off. With the most significant engineering result of the TMI accident, the recognition that better operator training was needed and that the existing emergency core cooling system of PWRs worked better in a real-world emergency than members of the anti-nuclear movement had routinely claimed.

The already slowing rate of new construction along with the shutdown in the 1980s of two existing demonstration nuclear power stations in the Tennessee Valley, United States, when they could not economically meet the NRC's new tightened standards, shifted electricity generation to coal-fired power plants. In 1977, following the first oil shock, U.S. President Jimmy Carter made a speech calling the energy crisis the "moral equivalent of war" and prominently supporting nuclear power. However, nuclear power could not compete with cheap oil and gas, particularly after public opposition and regulatory hurdles made new nuclear prohibitively expensive.

In 1982, amongst a backdrop of ongoing protests directed at the construction of the first commercial scale breeder reactor in France, a later member of the Swiss Green Party fired five RPG-7 rocket-propelled grenades at the still under construction containment building of the Superphenix reactor. Two grenades hit and caused minor damage to the reinforced concrete outer shell. It was the first time protests reached such heights. After examination of the superficial damage, the prototype fast breeder reactor started and operated for over a decade.

Chernobyl disaster

The town of Pripyat abandoned since 1986, with the Chernobyl plant and the Chernobyl New Safe Confinement arch in the distance.

The Chernobyl disaster occurred on Saturday 26 April 1986, at the No. 4 reactor in the Chernobyl Nuclear Power Plant, near the city of Pripyat in the north of the Ukrainian SSR. It is considered as the worst nuclear disaster in history both in terms of cost and casualties. The initial emergency response, together with later decontamination of the environment, ultimately involved more than 500,000 personnel and cost an estimated 18 billion Soviet rubles—roughly US$68 billion in 2019, adjusted for inflation.

According to some commentators, the Chernobyl disaster played a major part in the reduction in the number of new plant constructions in many other countries. Unlike the Three Mile Island accident the much more serious Chernobyl accident did not increase regulations or engineering changes affecting Western reactors; because the RBMK design, which lacks safety features such as "robust" containment buildings, was only used in the Soviet Union. Over 10 RBMK reactors are still in use today. However, changes were made in both the RBMK reactors themselves (use of a safer enrichment of uranium) and in the control system (preventing safety systems being disabled), amongst other things, to reduce the possibility of a similar accident. Russia now largely relies upon, builds and exports a variant of the PWR, the VVER, with over 20 in use today.

An international organization to promote safety awareness and the professional development of operators in nuclear facilities, the World Association of Nuclear Operators (WANO), was created as a direct outcome of the 1986 Chernobyl accident. The organization was created with the intent to share and grow the adoption of nuclear safety culture, technology and community, where before there was an atmosphere of cold war secrecy.

Numerous countries, including Austria (1978), Sweden (1980) and Italy (1987) (influenced by Chernobyl) have voted in referendums to oppose or phase out nuclear power.

Nuclear renaissance

Olkiluoto 3 under construction in 2009. It was the first EPR, a modernized PWR design, to start construction.

In the early 2000s, the nuclear industry was expecting a nuclear renaissance, an increase in the construction of new reactors, due to concerns about carbon dioxide emissions. However, in 2009, Petteri Tiippana, the director of nuclear power plant division in the Finnish Radiation and Nuclear Safety Authority, told the BBC that it was difficult to deliver a Generation III reactor project on schedule because builders were not used to working to the exacting standards required on nuclear construction sites, since so few new reactors had been built in recent years.

The Olkiluoto 3 was the first EPR, a modernized PWR design, to start construction. Problems with workmanship and supervision have created costly delays. The reactor is estimated to cost three times the initial estimate and will be delivered over 10 years behind schedule.

In 2018 the MIT Energy Initiative study on the future of nuclear energy concluded that, together with the strong suggestion that government should financially support development and demonstration of new Generation IV nuclear technologies, for a worldwide renaissance to commence, a global standardization of regulations needs to take place, with a move towards serial manufacturing of standardized units akin to the other complex engineering field of aircraft and aviation. At present it is common for each country to demand bespoke changes to the design to satisfy varying national regulatory bodies, often to the benefit of domestic engineering supply firms. The report goes on to note that the most cost-effective projects have been built with multiple (up to six) reactors per site using a standardized design, with the same component suppliers and construction crews working on each unit, in a continuous work flow.

Fukushima Daiichi disaster

Following the Tōhoku earthquake on 11 March 2011, one of the largest earthquakes ever recorded, and a subsequent tsunami off the coast of Japan, the Fukushima Daiichi Nuclear Power Plant suffered three core meltdowns due to failure of the emergency cooling system for lack of electricity supply. This resulted in the most serious nuclear accident since the Chernobyl disaster.

The Fukushima Daiichi nuclear accident prompted a re-examination of nuclear safety and nuclear energy policy in many countries and raised questions among some commentators over the future of the renaissance. Germany approved plans to close all its reactors by 2022. (Following the energy crisis caused by Russia's invasion of Ukraine, Germany now plans to keep reactors running until April 2023) Italian nuclear energy plans ended when Italy banned the generation, but not consumption, of nuclear electricity in a June 2011 referendum. China, Switzerland, Israel, Malaysia, Thailand, United Kingdom, and the Philippines reviewed their nuclear power programs.

In 2011 the International Energy Agency halved its prior estimate of new generating capacity to be built by 2035. Nuclear power generation had the biggest ever fall year-on-year in 2012, with nuclear power plants globally producing 2,346 TWh of electricity, a drop of 7% from 2011. This was caused primarily by the majority of Japanese reactors remaining offline that year and the permanent closure of eight reactors in Germany.

Post-Fukushima

The locations, primarily those adjacent to both decommissioned and operational reactors, across the U.S. where nuclear waste is stored and the planned Yucca Mountain nuclear waste repository.

The Associated Press and Reuters reported in 2011 the suggestion that the safety and survival of the younger Onagawa Nuclear Power Plant, the closest reactor facility to the epicenter and on the coast, demonstrate that it is possible for nuclear facilities to withstand the greatest natural disasters. The Onagawa plant was also said to show that nuclear power can retain public trust, with the surviving residents of the town of Onagawa taking refuge in the gymnasium of the nuclear facility following the destruction of their town.

In February 2012, the U.S. NRC approved the construction of 2 reactors at the Vogtle Electric Generating Plant, the first approval in 30 years.

In August 2015, following 4 years of near zero fission-electricity generation, Japan began restarting its nuclear reactors, after safety upgrades were completed, beginning with Sendai Nuclear Power Plant.

By 2015, the IAEA's outlook for nuclear energy had become more promising. "Nuclear power is a critical element in limiting greenhouse gas emissions," the agency noted, and "the prospects for nuclear energy remain positive in the medium to long term despite a negative impact in some countries in the aftermath of the [Fukushima-Daiichi] accident...it is still the second-largest source worldwide of low-carbon electricity. And the 72 reactors under construction at the start of last year were the most in 25 years." As of 2015, the global trend was for new nuclear power stations coming online to be balanced by the number of old plants being retired. Eight new grid connections were completed by China in 2015.

In 2016, the BN-800 sodium cooled fast reactor in Russia, began commercial electricity generation, while plans for a BN-1200 were initially conceived the future of the fast reactor program in Russia awaits the results from MBIR, an under construction multi-loop Generation research facility for testing the chemically more inert lead, lead-bismuth and gas coolants, it will similarly run on recycled MOX (mixed uranium and plutonium oxide) fuel. An on-site pyrochemical processing, closed fuel-cycle facility, is planned, to recycle the spent fuel/"waste" and reduce the necessity for a growth in uranium mining and exploration. In 2017 the manufacture program for the reactor commenced with the facility open to collaboration under the "International Project on Innovative Nuclear Reactors and Fuel Cycle", it has a construction schedule, that includes an operational start in 2020. As planned, it will be the world's most-powerful research reactor.

In 2015, the Japanese government committed to the aim of restarting its fleet of 40 reactors by 2030 after safety upgrades, and to finish the construction of the Generation III Ōma Nuclear Power Plant. This would mean that approximately 20% of electricity would come from nuclear power by 2030. As of 2018, some reactors have restarted commercial operation following inspections and upgrades with new regulations. While South Korea has a large nuclear power industry, the new government in 2017, influenced by a vocal anti-nuclear movement, committed to halting nuclear development after the completion of the facilities presently under construction.

The bankruptcy of Westinghouse in March 2017 due to US$9 billion of losses from the halting of construction at Virgil C. Summer Nuclear Generating Station, in the U.S. is considered an advantage for eastern companies, for the future export and design of nuclear fuel and reactors.

In 2016, the U.S. Energy Information Administration projected for its "base case" that world nuclear power generation would increase from 2,344 terawatt hours (TWh) in 2012 to 4,500 TWh in 2040. Most of the predicted increase was expected to be in Asia. As of 2018, there are over 150 nuclear reactors planned including 50 under construction. In January 2019, China had 45 reactors in operation, 13 under construction, and plans to build 43 more, which would make it the world's largest generator of nuclear electricity.

Current prospects

The Hanul Nuclear Power Plant in South Korea, one of the largest nuclear power plants in the world, using indigenously-designed APR-1400 generation-III reactors

Zero-emission nuclear power is an important part of the climate change mitigation effort. Under IEA Sustainable Development Scenario by 2030 nuclear power and CCUS would have generated 3900 TWh globally while wind and solar 8100 TWh with the ambition to achieve net-zero CO2 emissions by 2070. In order to achieve this goal on average 15 GWe of nuclear power should have been added annually on average. As of 2019 over 60 GW in new nuclear power plants was in construction, mostly in China, Russia, Korea, India and UAE. Many countries in the world are considering Small Modular Reactors with one in Russia connected to the grid in 2020.

Countries with at least one nuclear power plant in planning phase include Argentina, Brazil, Bulgaria, the Czech Republic, Egypt, Finland, Hungary, India, Kazakhstan, Poland, Saudi Arabia and Uzbekistan.

The future of nuclear power varies greatly between countries, depending on government policies. Some countries, most notably, Germany, have adopted policies of nuclear power phase-out. At the same time, some Asian countries, such as China and India, have committed to rapid expansion of nuclear power. In other countries, such as the United Kingdom and the United States, nuclear power is planned to be part of the energy mix together with renewable energy.

Nuclear energy may be one solution to providing clean power while also reversing the impact fossil fuels have had on our climate. These plants would capture carbon dioxide and create a clean energy source with zero emissions, making a carbon-negative process. Scientists propose that 1.8 million lives have already been saved by replacing fossil fuel sources with nuclear power.

As of 2019 the cost of extending plant lifetimes is competitive with other electricity generation technologies, including new solar and wind projects. In the United States, licenses of almost half of the operating nuclear reactors have been extended to 60 years. The U.S. NRC and the U.S. Department of Energy have initiated research into light water reactor sustainability which is hoped will lead to allowing extensions of reactor licenses beyond 60 years, provided that safety can be maintained, to increase energy security and preserve low-carbon generation sources. Research into nuclear reactors that can last 100 years, known as Centurion Reactors, is being conducted. As of 2020, a number of US nuclear power plants were cleared by Nuclear Regulatory Commission for operations up to 80 years.

Following the 2022 Russian invasion of Ukraine, the situation has changed. With the Versailles declaration agreed in March 2022, the EU leaders of the 27 member states agreed to phase out the EU’s dependence on Russian fossil fuels as soon as possible. The World Economic Forum has published energy policy changes, following the Russian Invasion. Korea is planning to "increase renewables in electricity [...] [and] nuclear power to over 30%". Japan has decided to "restart nuclear power plants aligned with the 6th Strategic Energy Plan [...]". Germany decided to postpone the shutdown of its three remaining nuclear power plants until April 2023.

Introduction to entropy

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