Atomic Age

(Redirected from Atomic era)

The Atomic Age, also known as the Atomic Era, is the period of history following the detonation of the first nuclear weapon, The Gadget at the Trinity test in New Mexico on 16 July 1945 during World War II. Although nuclear chain reactions had been hypothesized in 1933 and the first artificial self-sustaining nuclear chain reaction (Chicago Pile-1) had taken place in December 1942,[1] the Trinity test and the ensuing bombings of Hiroshima and Nagasaki that ended World War II represented the first large-scale use of nuclear technology and ushered in profound changes in sociopolitical thinking and the course of technological development.

An early nuclear power plant that used atomic energy to generate electricity

While atomic power was promoted for a time as the epitome of progress and modernity,[2] entering into the nuclear power era also entailed frightful implications of nuclear warfare, the Cold War, mutual assured destruction, nuclear proliferation, the risk of nuclear disaster (potentially as extreme as anthropogenic global nuclear winter), as well as beneficial civilian applications in nuclear medicine. It is no easy matter to fully segregate peaceful uses of nuclear technology from military or terrorist uses (such as the fabrication of dirty bombs from radioactive waste), which complicated the development of a global nuclear-power export industry right from the outset.

In 1973, concerning a flourishing nuclear power industry, the United States Atomic Energy Commission predicted that by the turn of the 21st century, 1,000 reactors would be producing electricity for homes and businesses across the U.S. However, the "nuclear dream" fell far short of what was promised because nuclear technology produced a range of social problems, from the nuclear arms race to nuclear meltdowns, and the unresolved difficulties of bomb plant cleanup and civilian plant waste disposal and decommissioning.[3] Since 1973, reactor orders declined sharply as electricity demand fell and construction costs rose. Many orders and partially completed plants were cancelled.[4]

By the late 1970s, nuclear power had suffered a remarkable international destabilization, as it was faced with economic difficulties and widespread public opposition, coming to a head with the Three Mile Island accident in 1979 and the Chernobyl disaster in 1986, both of which adversely affected the nuclear power industry for many decades.[5]

Early years

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In 1901, Frederick Soddy and Ernest Rutherford discovered that radioactivity was part of the process by which atoms changed from one kind to another, involving the release of energy. Soddy wrote in popular magazines that radioactivity was a potentially "inexhaustible" source of energy and offered a vision of an atomic future where it would be possible to "transform a desert continent, thaw the frozen poles, and make the whole earth one smiling Garden of Eden." The promise of an "atomic age," with nuclear energy as the global, utopian technology for the satisfaction of human needs, has been a recurring theme ever since. But "Soddy also saw that atomic energy could possibly be used to create terrible new weapons".[6][7]

The concept of a nuclear chain reaction was hypothesized in 1933, shortly after James Chadwick's discovery of the neutron. Only a few years later, in December 1938 nuclear fission was discovered by Otto Hahn and his assistant Fritz Strassmann. Hahn understood that a "burst" of the atomic nuclei had occurred.[8][9] Lise Meitner and Otto Frisch gave a full theoretical interpretation and named the process "nuclear fission".[citation needed] The first artificial self-sustaining nuclear chain reaction took place at Chicago Pile-1 in December 1942 under the leadership of Enrico Fermi.[1]

In 1945, the pocketbook The Atomic Age heralded the untapped atomic power in everyday objects and depicted a future where fossil fuels would go unused. One science writer, David Dietz, wrote that instead of filling the gas tank of your car two or three times a week, you will travel for a year on a pellet of atomic energy the size of a vitamin pill. Glenn T. Seaborg, who chaired the Atomic Energy Commission, wrote "there will be nuclear powered earth-to-moon shuttles, nuclear powered artificial hearts, plutonium heated swimming pools for SCUBA divers, and much more".[10]

World War II

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The phrase Atomic Age was coined by William L. Laurence, a journalist with The New York Times, who became the official journalist for the Manhattan Project which developed the first nuclear weapons.[11][12] He witnessed both the Trinity test and the bombing of Nagasaki and went on to write a series of articles extolling the virtues of the new weapon. His reporting before and after the bombings helped to spur public awareness of the potential of nuclear technology and in part motivated development of the technology in the U.S. and in the Soviet Union.[13] The Soviet Union would go on to test its first nuclear weapon in 1949.

In 1949, U.S. Atomic Energy Commission chairman, David Lilienthal stated that "atomic energy is not simply a search for new energy, but more significantly a beginning of human history in which faith in knowledge can vitalize man's whole life".[14]

1950s

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This view of downtown Las Vegas shows a mushroom cloud in the background. Scenes such as this were typical during the 1950s. From 1951 to 1962 the government conducted 100 atmospheric tests at the nearby Nevada Test Site.[15]

The phrase gained popularity as a feeling of nuclear optimism emerged in the 1950s in which it was believed that all power generators in the future would be atomic in nature. The atomic bomb would render all conventional explosives obsolete, and nuclear power plants would do the same for power sources such as coal and oil. There was a general feeling that everything would use a nuclear power source of some sort, in a positive and productive way, from irradiating food to preserve it, to the development of nuclear medicine. There would be an age of peace and plenty in which atomic energy would "provide the power needed to desalinate water for the thirsty, irrigate the deserts for the hungry, and fuel interstellar travel deep into outer space".[2] This use would render the Atomic Age as significant a step in technological progress as the first smelting of bronze, of iron, or the commencement of the Industrial Revolution.

This included even cars, leading Ford Motor Company to display the Ford Nucleon concept car to the public in 1958. There was also the promise of golf balls which could always be found and nuclear-powered aircraft, which the U.S. federal government even spent US$1.5 billion researching.[2] Nuclear policymaking became almost a collective technocratic fantasy, or at least was driven by fantasy:[16]

The very idea of splitting the atom had an almost magical grip on the imaginations of inventors and policymakers. As soon as someone said—in an even mildly credible way—that these things could be done, then people quickly convinced themselves ... that they would be done.[16]

In the US, military planners "believed that demonstrating the civilian applications of the atom would also affirm the American system of private enterprise, showcase the expertise of scientists, increase personal living standards, and defend the democratic lifestyle against communism".[17] Some media reports predicted that thanks to the giant nuclear power stations of the near future electricity would soon become much cheaper and that electricity meters would be removed, because power would be "too cheap to meter."[18]

When the Shippingport reactor went online in 1957 it produced electricity at a cost roughly ten times that of coal-fired generation. Scientists at the AEC's own Brookhaven Laboratory "wrote a 1958 report describing accident scenarios in which 3,000 people would die immediately, with another 40,000 injured".[19] However Shippingport was an experimental reactor using highly enriched uranium (unlike most power reactors) and originally intended for a (cancelled) nuclear-powered aircraft carrier.

Kenneth Nichols, a consultant for the Connecticut Yankee and Yankee Rowe nuclear power stations, wrote that while considered "experimental" and not expected to be competitive with coal and oil, they "became competitive because of inflation ... and the large increase in price of coal and oil." He wrote that for nuclear power stations the capital cost is the major cost factor over the life of the plant, hence "antinukes" try to increase costs and building time with changing regulations and lengthy hearings, so that "it takes almost twice as long to build a (U.S.-designed boiling-water or pressurised water) atomic power plant in the United States as in France, Japan, Taiwan or South Korea." French pressurised-water nuclear plants produce 60% of their electric power and have proven to be much cheaper than oil or coal.[20]

Fear of possible atomic attack from the Soviet Union caused U.S. school children to participate in "duck and cover" civil defense drills.[21]

Atomic City

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During the 1950s, Las Vegas earned the nickname "Atomic City" for becoming a hotspot where tourists would gather to watch above-ground nuclear weapons tests taking place at Nevada Test Site. Following the detonation of Able, one of the first atomic bombs dropped at the Nevada Test Site, the Las Vegas Chamber of Commerce began advertising the tests as an entertainment spectacle to tourists.

The detonations proved popular, and casinos throughout the city capitalised on the tests by advertising hotel rooms or rooftops which offered views of the testing site or by planning "Dawn Bomb Parties" where people would come together to celebrate the detonations.[22] Most parties started at midnight, and musicians would perform at the venues until 4:00 a.m. when the party would briefly stop so guests could silently watch the detonation. Some casinos capitalised on the tests further by creating so called "atomic cocktails", a mixture of vodka, cognac, sherry and champagne.[23] Meanwhile, groups of tourists would drive out into the desert with family or friends to watch the detonations.

Despite the health risks associated with nuclear fallout, tourists and viewers were told to simply "shower". Later on, however, anyone who had worked at the testing site or lived in areas exposed to nuclear fallout fell ill and had higher chances of developing cancer or suffering pre-mature deaths.[24]

1960s

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The term "atomic age" was initially used in a positive, futuristic sense, but by the 1960s the threats posed by nuclear weapons had begun to edge out nuclear power as the dominant motif of the atom. In the Thunderbirds TV series, a set of vehicles was presented that were imagined to be completely nuclear, as shown in cutaways presented in their comic-books.

Project Plowshare

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By exploiting the peaceful uses of the "friendly atom" in medical applications, earth removal and subsequently in nuclear power plants, the nuclear industry and U.S. government sought to allay public fears about nuclear technology and promote the acceptance of nuclear weapons. At the peak of the Atomic Age, the U.S. initiated Project Plowshare, involving "peaceful nuclear explosions". The United States Atomic Energy Commission (AEC) chairman announced that Plowshare was intended to "highlight the peaceful applications of nuclear explosive devices and thereby create a climate of world opinion that is more favorable to weapons development and tests".[25] Plowshare "was named directly from the Bible itself, specifically Micah 4:3, which states that God will beat swords into ploughshares, and spears into pruning hooks, so that no country could lift up weapons against another".[26]

Proposed uses included widening the Panama Canal, constructing a new sea-level waterway through Nicaragua nicknamed the Pan-Atomic Canal, cutting paths through mountainous areas for highways, and connecting inland river systems. Other proposals involved blasting caverns for water, natural gas, and petroleum storage. It was proposed to plant underground atomic bombs to extract shale oil in eastern Utah and western Colorado. Serious consideration was given to using these explosives for various mining operations. One proposal suggested using nuclear blasts to connect underground aquifers in Arizona. Another plan involved surface blasting on the western slope of California's Sacramento Valley for a water transport project.[26]

However, there were many negative impacts from Project Plowshare's 27 nuclear explosions.[26] Consequences included blighted land, relocated communities, tritium-contaminated water, radioactivity, and fallout from debris being hurled high into the atmosphere. These were ignored and downplayed until the program was terminated in 1977, due in large part to public opposition, after $770 million had been spent on the project.[26]

1970s to 1990s

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The abandoned city of Pripyat. The Chernobyl Nuclear Power Plant can be seen on the horizon.

French advocates of nuclear power developed an aesthetic vision of nuclear technology as art to bolster support for the technology. Leclerq compares the nuclear cooling tower to some of the grandest architectural monuments of Western culture:[27]

The age in which we live has, for the public, been marked by the nuclear engineer and the gigantic edifices he has created. For builders and visitors alike, nuclear power plants will be considered the cathedrals of the 20th century. Their syncretism mingles the conscious and the unconscious, religious fulfilment and industrial achievement, the limitations of uses of materials and boundless artistic inspiration, utopia come true and the continued search for harmony.[27]

In 1973, the AEC predicted that, by the turn of the 21st century 1,000 reactors would be producing electricity for homes and businesses across the U.S. But after 1973, reactor orders declined sharply as electricity demand fell and construction costs rose. Many orders and partially completed plants were cancelled.[4]

Nuclear power has proved controversial since the 1970s. Highly radioactive materials may overheat and escape from the reactor building. Nuclear waste (spent nuclear fuel) needs to be regularly removed from the reactors and disposed of safely for up to a million years, so that it does not pollute the environment. Recycling of nuclear waste has been discussed, but it creates plutonium which can be used in weapons, and in any case still leaves much unwanted waste to be stored and disposed of. Large, purpose-built facilities for long-term disposal of nuclear waste have been difficult to site.[28]

By the late 1970s, nuclear power suffered a remarkable international destabilization, as it was faced with economic difficulties and widespread public opposition, coming to a head with the Three Mile Island accident in 1979 and the Chernobyl disaster in 1986, both of which adversely affected the nuclear power industry for decades thereafter. A cover story in the 11 February 1985 issue of Forbes magazine addresses the overall management of the nuclear power program in the United States:

The failure of the U.S. nuclear power program ranks as the largest managerial disaster in business history, a disaster on a monumental scale ... only the blind, or the biased, can now think that the money has been well spent. It is a defeat for the U.S. consumer and for the competitiveness of U.S. industry, for the utilities that undertook the program and for the private enterprise system that made it possible.[29]

In a period just over 30 years, the early dramatic rise of nuclear power went into equally meteoric reverse. With no other energy technology has there been a conjunction of such rapid and revolutionary international emergence, followed so quickly by equally transformative demise.[30]

21st century

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The 2011 Fukushima Daiichi nuclear disaster in Japan, the worst nuclear accident in 25 years, displaced 50,000 households after radiation leaked into the air, soil and sea.[31]

In the 21st century, the label of the "Atomic Age" connotes either a sense of nostalgia or naïveté and is considered by many to have ended with the fall of the Soviet Union in 1991, though the term continues to be used by many historians to describe the era following the conclusion of the Second World War. Atomic energy and weapons continue to have a strong effect on world politics in the 21st century.

The nuclear power industry has improved the safety and performance of reactors and has proposed new safer (but generally untested) reactor designs, but there is no guarantee that the reactors will be designed, built and operated correctly.[32] Mistakes do occur, and natural disasters can effect nuclear power plants, such as the 2011 Tōhoku earthquake and tsunami that damaged the Fukushima plant in Japan.[33] According to UBS AG, the Fukushima accident cast doubt on whether even an advanced economy like Japan can master nuclear safety.[34] Catastrophic scenarios involving terrorist attacks are also conceivable.[32] An interdisciplinary team from MIT has estimated that if nuclear power use tripled from 2005 to 2055 (2%[35]–7%), at least four serious nuclear accidents would be expected in that period.[36][37]

In September 2012, in reaction to the Fukushima disaster, Japan announced that it would completely phase out nuclear power by 2030, although the likelihood of this goal became unlikely during the subsequent Abe administration.[38] Germany planned to completely phase out nuclear energy by 2022[39] but was still using 11.9% in 2021.[needs update] In 2022, following the Russian invasion of Ukraine, the United Kingdom pledged to build up to 8 new reactors to reduce their reliance on gas and oil and hopes that 25% of all energy produced will be by nuclear means.[40]

On August 1, 2024, Vipin Narang, a senior Pentagon official, remarked, "We now find ourselves in nothing short of a new nuclear age." He attributed this development to an "unprecedented mix of multiple revisionist nuclear challengers who are uninterested in arms control or risk-reduction efforts, each rapidly modernizing and expanding their nuclear arsenals."[41]

Anti-nuclear movement

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A large anti-nuclear demonstration was held on 6 May 1979, in Washington D.C., when 125,000 people[42] including the governor of California, attended a march and rally against nuclear power.[43] In New York City on 23 September 1979, almost 200,000 people attended a protest against nuclear power.[44] Anti-nuclear power protests preceded the shutdown of the Shoreham, Yankee Rowe, Millstone I, Rancho Seco, Maine Yankee, and about a dozen other nuclear power plants.[45]

On 12 June 1982, one million people demonstrated in New York City's Central Park against nuclear weapons and for an end to the Cold War arms race. It was the largest anti-nuclear protest and the largest political demonstration in American history.[46][47] International Day of Nuclear Disarmament protests were held on 20 June 1983, at 50 sites across the United States.[48][49] In 1986, hundreds of people walked from Los Angeles to Washington, D.C., in the Great Peace March for Global Nuclear Disarmament.[50] There were many Nevada Desert Experience protests and peace camps at the Nevada Test Site during the 1980s and 1990s.[51][52]

On May 1, 2005, 40,000 anti-nuclear/anti-war protesters marched past the United Nations in New York, 60 years after the atomic bombings of Hiroshima and Nagasaki.[53][54] This was the largest anti-nuclear rally in the U.S. for several decades.[55]

Timeline

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Discovery and development

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  • 1896 – Henri Becquerel notices that uranium gives off an unknown radiation which fogs photographic film.[56]
  • 1898 – Marie Curie discovers thorium gives off a similar radiation. She calls it radioactivity.[56]
  • 1903 – Ernest Rutherford begins to speak of the possibility of atomic energy.[57]
  • 1905 – Albert Einstein formulates the special theory of relativity which explains the phenomenon of radioactivity as mass–energy equivalence.[57]
  • 1911 – Ernest Rutherford formulates a theory about the structure of the atomic nucleus based on his experiments with alpha particles.[58]
  • 1930 – Otto Hahn writes an article with his prophecy "The Atom – the source of power of the future?" in the newspaper Deutsche Allgemeine Zeitung.[59]
  • 1932 – James Chadwick discovers the neutron.[60]
  • 1934 – Enrico Fermi begins bombarding uranium with slow neutrons; Ida Noddack predicts that uranium nuclei will break up under bombardment by fast neutrons. (Fermi does not pursue this because his theoretical mathematical predictions do not predict this result.)
  • 17 December 1938 – Otto Hahn and his assistant Fritz Strassmann, by bombarding uranium with fast neutrons, discover experimentally and prove nuclear fission with radiochemical methods.[61]
  • 6 January 1939 – Hahn and Strassmann publish the first paper about their discovery in the German review Die Naturwissenschaften.[62]
  • 10 February 1939 – Hahn and Strassmann publish the second paper about their discovery in Die Naturwissenschaften, using for the first time the term uranium fission, and predict the liberation of additional neutrons in the fission process.[63]
  • 11 February 1939 – Lise Meitner and her nephew Otto Frisch publish the first theoretical interpretation of nuclear fission, a term coined by Frisch, in the British review Nature.[64]
  • 11 October 1939 – The Einstein–Szilárd letter, suggesting that the United States construct a nuclear weapon, is delivered to President Franklin D. Roosevelt. Roosevelt signs the order to build a nuclear weapon on 6 December 1941.[65]
  • 26 February 1941 – Discovery of plutonium by Glenn Seaborg and Arthur Wahl.
  • September 1942 – General Leslie Groves takes charge of the Manhattan Project.
  • 2 December 1942 – Under the leadership of Fermi, the first self-sustaining nuclear chain reaction takes place at the Chicago Pile-1.

Nuclear arms deployment

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"Atoms for Peace"

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Three Mile Island and Chernobyl

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Nuclear arms reduction

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  • 8 December 1987 – The Intermediate-Range Nuclear Forces Treaty is signed in Washington 1987. Ronald Reagan and Mikhail Gorbachev agreed after negotiations following the 11–12 October 1986 Reykjavík Summit to go farther than a nuclear freeze – they agreed to reduce nuclear arsenals. IRBMs and SRBMs were eliminated.
  • 1993–2007 – Nuclear power is the primary source of electricity in France. Throughout these two decades, France produced over three quarters of its power from nuclear sources (78.8%), the highest percentage in the world at the time.[72][73]
  • 31 July 1991 – As the Cold War ends, the Start I treaty is signed by the United States and the Soviet Union, reducing the deployed nuclear warheads of each side to no more than 6,000 each.
  • 1993 – The Megatons to Megawatts Program is agreed upon by Russia and the United States and begins to be implemented in 1995. When it is completed in 2013, five hundred tonnes of uranium derived from 20,000 nuclear warheads from Russia will have been converted from weapons-grade to reactor-grade uranium and used in United States nuclear plants to generate electricity. This has provided 10% of the electrical power of the U.S. (50% of its nuclear power) during the 1995–2013 period.[74]
  • 2006 – Patrick Moore, an early member of Greenpeace and environmentalists such as Stewart Brand[75] suggest the deployment of more advanced nuclear power technology for electric power generation (such as pebble-bed reactors) to combat global warming.
  • 21 November 2006 – Implementation of the ITER fusion power reactor project near Cadarache, France is begun. Construction is to be completed in 2016 with the hope that the research conducted there will allow the introduction of practical commercial fusion power plants by 2050.
  • 2006–2009 – Nuclear engineers begin to suggest that, to combat global warming, it would be more efficient to build nuclear reactors that operate on the thorium cycle.[76][77]
  • 8 April 2010 – The New START treaty is signed by the United States and Russia in Prague. It mandates the eventual reduction by both sides to no more than 1,550 deployed strategic nuclear weapons each.

Fukushima

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  • 11 March 2011 – A tsunami resulting from the Tōhoku earthquake causes severe damage to the Fukushima I nuclear power plant in Japan, causing partial nuclear meltdowns in several of the reactors. Many international leaders express concerns about the accidents, and some countries re-evaluate existing nuclear energy programs. The event is rated level 7 on the International Nuclear Event Scale by the Japanese government's nuclear safety agency.[78][79] Other than the Chernobyl disaster, it is the only nuclear accident to be rated at level 7, the highest level on the scale, and caused the most dramatic shift in nuclear policy to date.
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Cover of Atomic War number one, November 1952
  • 1945 – The Atomaton chapter of Sweet Adelines was formed by Edna Mae Anderson after she and her sister singers decided, "We have an atom of an idea and a ton of energy." The name also recognized the Atomic Age—just three days after Sweet Adelines was founded (13 July 1945), the first nuclear bomb, Trinity, was detonated.
  • 5 July 1946 – The bikini swimsuit, named after Bikini Atoll, where an atomic bomb test called Operation Crossroads had taken place a few days earlier on 1 July 1946, was introduced at a fashion show in Paris.[80]
  • 1954 – Them!, a science fiction film about humanity's battle with a nest of giant mutant ants, was one of the first of the "nuclear monster" movies.
  • 1954 – The science fiction film Godzilla was released, about an iconic fictional monster that is a gigantic irradiated dinosaur, transformed from the fallout of a hydrogen bomb test.
  • 23 January 1957 – Walt Disney Productions released the film "Our Friend the Atom" describing the marvelous benefits of atomic power. As well as being presented as an episode on the TV show Disneyland, this film was also shown to almost all baby boomers in their public school auditoriums or their science classes and was instrumental in creating within that generation a mostly favorable attitude toward nuclear power.[81]
  • 1958 –The peace symbol was designed for the British nuclear disarmament movement by Gerald Holtom.[82]
  • 1959 – The popular film On the Beach shows the last remnants of humanity in Australia awaiting the end of the human race after a nuclear war.
  • 1964 – The film Dr. Strangelove, or: How I Learned to Stop Worrying and Love the Bomb (aka Dr. Strangelove), a black comedy directed by Stanley Kubrick about an accidentally triggered nuclear war, was released.
  • 1982 – The documentary film The Atomic Cafe, detailing society's attitudes toward the atomic bomb in the early Atomic Age, debuted to widespread acclaim.
  • 1982 – Jonathan Schell's book Fate of the Earth, about the consequences of nuclear war, is published. The book "forces even the most reluctant person to confront the unthinkable: the destruction of humanity and possibly most life on Earth". The best-selling book instigated the Nuclear Freeze campaign.
  • 20 November 1983 – The Day After, an American television movie was aired on the ABC Television Network and in the Soviet Union. The film portrays a fictional nuclear war between the United States/NATO and the Soviet Union/Warsaw Pact. After the film, a panel discussion was presented in which Carl Sagan suggested that we need to reduce the number of nuclear weapons as a matter of "planetary hygiene". This film was seen by over 100,000,000 people and was instrumental in greatly increasing public support for the Nuclear Freeze campaign.

See also

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References

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  1. ^ a b Holl, Jack (1997). Argonne National Laboratory, 1946–96. University of Illinois Press. ISBN 978-0-252-02341-5.
  2. ^ a b c Benjamin K. Sovacool (2011). Contesting the Future of Nuclear Power: A Critical Global Assessment of Atomic Energy, World Scientific, p. 259.
  3. ^ John Byrne and Steven M. Hoffman (1996). Governing the Atom: The Politics of Risk, Transaction Publishers, p. 99.
  4. ^ a b Stephanie Cooke (2009). In Mortal Hands: A Cautionary History of the Nuclear Age, Black Inc., p. 283.
  5. ^ "Nuclear Follies", 11 February 1985, cover story in Forbes magazine.
  6. ^ Zia Mian & Alexander Glaser (June 2006). "Life in a Nuclear Powered Crowd" (PDF). INESAP Information Bulletin No.26.
  7. ^ The two words atomic and nuclear are synonymous in the context of atomic power and weapons. The atom consists of a nucleus and one or more electrons. All atomic reactions involve changing one atom into another by changing the nucleus. Historically atomic power is an older term, and nuclear power is newer.President Eisenhower's "Atoms for Peace" Speech
  8. ^ "The Discovery of Nuclear Fission". www.mpic.de.
  9. ^ Oelering, Jan H. J. (September 1996). "Hahn´s Nobel was well deserved" (PDF). Nature. 383 (6598): 294. Bibcode:1996Natur.383..294O. doi:10.1038/383294b0.
  10. ^ Benjamin K. Sovacool, The National Politics of Nuclear Power, Routledge, p. 68.
  11. ^ Laurence, William L. (26 September 1945). "Drama of the Atomic Bomb Found Climax in July 16 Test". The New York Times. ISBN 9781434405302.
  12. ^ Gonzalez, Juan (9 August 2005). "ATOMIC TRUTHS PLAGUE PRIZE COVERUP". New York Daily News. Laurence, the only journalist the U.S. government permitted to witness the bombing of Nagasaki, is also the reporter who first coined the term "Atomic Age." ... Nagasaki, Laurence launched his Times series, where he extolled the bomb and sought to discredit other accounts about effects of the bomb.[permanent dead link]
  13. ^ On this incident, see David Holloway, Stalin and the Bomb: The Soviet Union and Atomic Energy, 1939–1956 (New Haven, CT: Yale University Press, 1994): 59–60.
  14. ^ John Byrne and Steven M. Hoffman (1996). Governing the Atom: The Politics of Risk, Transaction Publishers, p. 85.
  15. ^ Simon, Steven; Bouville, Andre (2006). "Fallout from Nuclear Weapons Tests and Cancer Risks". American Scientist. AmericanScientist.org. Retrieved 12 September 2020. Exposures 50 years ago still have health implications today that will continue into the future.
  16. ^ a b John Byrne and Steven M. Hoffman (1996). Governing the Atom: The Politics of Risk, Transaction Publishers, pp. 50–51.
  17. ^ Benjamin K. Sovacool (2011). Contesting the Future of Nuclear Power: A Critical Global Assessment of Atomic Energy, World Scientific, p. 266.
  18. ^ "Too Cheap to Meter?". Canadian Nuclear Society. 30 March 2007. Archived from the original on 4 February 2007. Retrieved 17 June 2007.
  19. ^ John Byrne and Steven M. Hoffman (1996). Governing the Atom: The Politics of Risk, Transaction Publishers, p. 55.
  20. ^ Nichols, Kenneth David (1987). The Road to Trinity: A Personal Account of How America's Nuclear Policies Were Made. New York: William Morrow and Company. p. 344. ISBN 978-0-688-06910-0. OCLC 15223648.
  21. ^ Kelly, Kate (26 October 2010). "Remember Duck and Cover? What Safety Experts May Have Been Thinking". HuffPost.
  22. ^ "Atomic Tourism in Nevada". pbs.org. Retrieved 23 July 2020.
  23. ^ Bosker, Gideon (1998). Atomic Cocktails. San Francisco: Chronicle Books. p. 8.
  24. ^ Loria, Kevin (17 August 2017). "Nuclear explosions from the past are still causing cancer and health problems today". Business Insider. Retrieved 24 October 2018.
  25. ^ Charles Perrow (September–October 2013). "Nuclear denial: From Hiroshima to Fukushima". Bulletin of the Atomic Scientists.
  26. ^ a b c d Benjamin K. Sovacool (2011). Contesting the Future of Nuclear Power: A Critical Global Assessment of Atomic Energy, World Scientific, pp. 171–172.
  27. ^ a b John Byrne and Steven M. Hoffman (1996). Governing the Atom: The Politics of Risk, Transaction Publishers, pp. 20–21.
  28. ^ Congressional Research report, Nuclear Energy: Overview of Congressional Issues, CRS Report, 2015.
  29. ^ "Nuclear Follies", a February 11, 1985, cover story in Forbes magazine.
  30. ^ Andy Stirling (2014). "Transforming power". Energy Research and Social Science. 1: 83–95. doi:10.1016/j.erss.2014.02.001.
  31. ^ Tomoko Yamazaki & Shunichi Ozasa (27 June 2011). "Fukushima Retiree Leads Anti-Nuclear Shareholders at Tepco Annual Meeting". Bloomberg.
  32. ^ a b Jacobson, Mark Z. & Delucchi, Mark A. (2010). "Providing all Global Energy with Wind, Water, and Solar Power, Part I: Technologies, Energy Resources, Quantities and Areas of Infrastructure, and Materials" (PDF). Energy Policy. p. 6.
  33. ^ Hugh Gusterson (16 March 2011). "The lessons of Fukushima". Bulletin of the Atomic Scientists. Archived from the original on 6 June 2013.
  34. ^ James Paton (4 April 2011). "Fukushima Crisis Worse for Atomic Power Than Chernobyl, UBS Says". Bloomberg Businessweek. Archived from the original on 15 May 2011.
  35. ^ World Energy Outlook 2007 pp 74,360
  36. ^ Benjamin K. Sovacool (January 2011). "Second Thoughts About Nuclear Power" (PDF). National University of Singapore. p. 8. Archived from the original (PDF) on 16 January 2013. Retrieved 4 December 2012.
  37. ^ Massachusetts Institute of Technology (2003). "The Future of Nuclear Power" (PDF). p. 48.
  38. ^ "Japan Plans To Abandon Nuclear Power". www.countercurrents.org.
  39. ^ "The history behind Germany's nuclear phase-out". Clean Energy Wire. 25 September 2014. Retrieved 20 November 2015.
  40. ^ "How much nuclear power does the UK use and is it safe?". BBC News. 9 November 2021.
  41. ^ "America prepares for a new nuclear-arms race". The Economist. 12 August 2024. Retrieved 14 August 2024.
  42. ^ a b "D.C. Anti-Nuke Rally Draws 125,000", WRL News, July–August 1979, War Resisters League, New York, NY
  43. ^ a b Giugni, Marco (2004). Social Protest and Policy Change: Ecology, Antinuclear, and Peace Movements in Comparative Perspective. Rowman & Littlefield. p. 45. ISBN 978-0-7425-1827-8.
  44. ^ a b Herman, Robin (24 September 1979). "Nearly 200,000 Rally to Protest Nuclear Energy". The New York Times. p. B1.
  45. ^ Williams, Estha. Nuke Fight Nears Decisive Moment Archived 29 November 2014 at the Wayback Machine Valley Advocate, 28 August 2008.
  46. ^ Jonathan Schell. The Spirit of June 12 Archived 12 May 2019 at the Wayback Machine The Nation, 2 July 2007.
  47. ^ 1982 – a million people march in New York City Archived 16 May 2008 at the Wayback Machine
  48. ^ Klehr, Harvey (1988). Far Left of Center: The American Radical Left Today. Transaction Publishers. p. 150. ISBN 978-1-4128-2343-2.
  49. ^ 1,400 Anti-nuclear protesters arrested Miami Herald, 21 June 1983.
  50. ^ Hundreds of Marchers Hit Washington in Finale of Nationwaide Peace March Gainesville Sun, 16 November 1986.
  51. ^ Robert Lindsey. 438 Protesters are Arrested at Nevada Nuclear Test Site The New York Times, 6 February 1987.
  52. ^ 493 Arrested at Nevada Nuclear Test Site The New York Times, 20 April 1992.
  53. ^ Lance Murdoch. Pictures: New York MayDay anti-nuke/war march Archived 28 July 2011 at the Wayback Machine IndyMedia, 2 May 2005.
  54. ^ Anti-Nuke Protests in New York Fox News, 2 May 2005.
  55. ^ Lawrence S. Wittner. Nuclear Disarmament Activism in Asia and the Pacific, 1971–1996 The Asia-Pacific Journal, Vol. 25-5-09, 22 June 2009.
  56. ^ a b Asimov, Isaac Atom: Journey Across the Sub-Atomic Cosmos New York:1992 Plume Page 92
  57. ^ a b Asimov, Isaac Atom: Journey Across the Sub-Atomic Cosmos New York:1992 Plume Page 125
  58. ^ Asimov, Isaac Atom: Journey Across the Sub-Atomic Cosmos New York:1992 Plume Page 95
  59. ^ Klaus Hoffmann: Otto Hahn – Achievement and Responsibility. Springer Verlag, Inc., New York-Berlin-London-Tokyo etc. 2001. p. 81. ISBN 0-387-95057-5.
  60. ^ Asimov, Isaac Atom: Journey Across the Sub-Atomic Cosmos New York:1992 Plume Page 154
  61. ^ Otto Hahn: A Scientific Autobiography. Charles Scribner's, New York 1966.
  62. ^ Klaus Hoffmann: Otto Hahn – Achievement and Responsibility. Springer Verlag, Inc., New York-Berlin-Barcelona-Hong Kong-Milan-Paris-Singapore-Tokyo 2001. ISBN 0-387-95057-5.
  63. ^ Lise Meitner: Erinnerungen an Otto Hahn. S. Hirzel, Stuttgart 2005. ISBN 3-7776-1380-0.
  64. ^ Lise Meitner: Otto Hahn – the discoverer of nuclear fission. In: Forscher und Wissenschaftler im heutigen Europa. Stalling, Oldenburg-Hamburg 1955.
  65. ^ Asimov, Isaac Atom: Journey Across the Sub-Atomic Cosmos New York:1992 Plume Page 182
  66. ^ Too Cheap to Meter?: Archived 4 February 2007 at the Wayback Machine
  67. ^ "First commercial nuclear power station". Guinness World Records. Retrieved 14 September 2022.
  68. ^ Samuel Upton Newtan (2007). Nuclear War I and Other Major Nuclear Disasters of the 20th Century. AuthorHouse. pp. 237–240. ISBN 978-1-4259-8512-7.
  69. ^ Fortune magazine November 1961 Pages 112–115 et al
  70. ^ "Nuclear Pulse Propulsion: A Historical Review" by Martin and Bond, Journal of the British Interplanetary Society, 1979 (p.301)
  71. ^ Interstellar Transport Physics Today October 1968
  72. ^ EnerPub (8 June 2007). "France: Energy profile". Spero News. Archived from the original on 4 October 2007. Retrieved 25 August 2007.
  73. ^ World Nuclear Association (August 2007). "Nuclear Power in France". Archived from the original on 7 August 2007. Retrieved 25 August 2007. (alternate copy Archived 3 March 2008 at the Wayback Machine)
  74. ^ USEC Progress Report on Megatons to Megawatts Program: Archived 8 October 2012 at the Wayback Machine
  75. ^ Tierney, John (27 February 2007). "Findings; An Early Environmentalist, Embracing New 'Heresies'". The New York Times. Retrieved 23 March 2008.
  76. ^ "Scientist Urges Switch to Thorium". Australian Broadcasting Corporation. Archived from the original on 28 March 2010. Retrieved 20 January 2010.
  77. ^ Martin, Richard (21 December 2009). "Uranium Is So Last Century — Enter Thorium, the New Green Nuke". Wired. Vol. 18, no. 1 – via www.wired.com.
  78. ^ "Japan to raise Fukushima crisis level to worst". Archived from the original on 12 April 2011. Retrieved 12 April 2011.
  79. ^ "Japan raises nuclear crisis to same level as Chernobyl". Reuters. 12 April 2011.
  80. ^ "The Bikini Turns 60". Archived from the original on 9 September 2016. Retrieved 21 February 2008.
  81. ^ Animation World Magazine Issue 3.1, April 1998 — The Making of Our Friend the Atom
  82. ^ Breyer, Melissa (21 September 2010). "Where did the peace sign come from?". Shine. Yahoo!. Archived from the original on 4 October 2010. Retrieved 30 September 2010.

Further reading

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  • "Presidency in the Nuclear Age", conference and forum at the JFK Library, Boston, 12 October 2009. Four panels: "The Race to Build the Bomb and the Decision to Use It", "Cuban Missile Crisis and the First Nuclear Test Ban Treaty", "The Cold War and the Nuclear Arms Race", and "Nuclear Weapons, Terrorism, and the Presidency".
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