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Underground nuclear weapons testing

April 26, 2024

Underground nuclear testing is the test detonation of nuclear weapons that is performed underground. When the device being tested is buried at sufficient depth, the nuclear explosion may be contained, with no release of radioactive materials to the atmosphere.

Preparation for an underground nuclear test at the Nevada Test Site in the 1990s as the diagnostic cables are being installed.

The extreme heat and pressure of an underground nuclear explosion causes changes in the surrounding rock. The rock closest to the location of the test is vaporised, forming a cavity. Farther away, there are zones of crushed, cracked, and irreversibly strained rock. Following the explosion, the rock above the cavity may collapse, forming a rubble chimney. If this chimney reaches the surface, a bowl-shaped subsidence crater may form.

The first underground test took place in 1951. Further tests soon led scientists to conclude that even notwithstanding environmental and diplomatic considerations, underground testing was of far greater scientific value than all other forms of testing. This understanding strongly influenced the governments of the first three nuclear powers to sign of the Limited Test Ban Treaty in 1963, which banned all nuclear tests except for those performed underground. From then until the signing of the Comprehensive Nuclear-Test-Ban Treaty in 1996, most nuclear tests were performed underground, which prevented additional nuclear fallout from entering into the atmosphere.

Background edit

Public concern about fallout from nuclear testing grew in the early 1950s.[1][2] Fallout was discovered after the Trinity test, the first ever atomic bomb test, in 1945.[2] Photographic film manufacturers later reported 'fogged' films; this was traced to packaging materials sourced from Indiana crops, contaminated by Trinity and later tests at the Nevada Test Site, over 1,000 miles (≈1600 kilometres) away.[2] Intense fallout from the 1953 Simon test was documented as far as Albany, New York.[2]

The fallout from the March 1954 Bravo test in the Pacific Ocean had "scientific, political and social implications that have continued for more than 40 years".[3] The multi-megaton test caused fallout to occur on the islands of the Rongerik and Rongelap atolls, and a Japanese fishing boat known as the Daigo Fukuryū Maru (Lucky Dragon).[3] Prior to this test, there was "insufficient" appreciation of the dangers of fallout.[3]

The test became an international incident. In a Public Broadcasting Service (PBS) interview, the historian Martha Smith argued: "In Japan, it becomes a huge issue in terms of not just the government and its protest against the United States, but all different groups and all different peoples in Japan start to protest. It becomes a big issue in the media. There are all kinds of letters and protests that come from, not surprisingly, Japanese fishermen, the fishermen's wives; there are student groups, all different types of people; that protest against the Americans' use of the Pacific for nuclear testing. They're very concerned about, first of all, why the United States even has the right to be carrying out those kinds of tests in the Pacific. They're also concerned about the health and environmental impact."[4] The Prime Minister of India "voiced the heightened international concern" when he called for the elimination of all nuclear testing worldwide.[who?][1]

Knowledge about fallout and its effects grew, and with it concern about the global environment and long-term genetic damage.[5] Talks between the United States, the United Kingdom, Canada, France, and the Soviet Union began in May 1955 on the subject of an international agreement to end nuclear tests.[5] On August 5, 1963, representatives of the United States, the Soviet Union, and the United Kingdom signed the Limited Test Ban Treaty, forbidding testing of nuclear weapons in the atmosphere, in space, and underwater.[6] Agreement was facilitated by the decision to allow underground testing, eliminating the need for on-site inspections that concerned the Soviets.[6] Underground testing was allowed, provided that it does not cause "radioactive debris to be present outside the territorial limits of the State under whose jurisdiction or control such explosion is conducted".[5]

Early history of underground testing edit

Following analysis of underwater detonations that were part of Operation Crossroads in 1946, inquiries were made regarding the possible military value of an underground explosion.[7] The US Joint Chiefs of Staff thus obtained the agreement of the United States Atomic Energy Commission (AEC) to perform experiments on both surface and sub-surface detonations.[7] The Alaskan island of Amchitka was initially selected for these tests in 1950, but the site was later deemed unsuitable and the tests were moved to the Nevada Test Site.[8]

 
Buster-Jangle Uncle, the first underground nuclear explosion

The first underground nuclear test was conducted on 29 November 1951.[9][10][11] This was the 1.2 kiloton Buster-Jangle Uncle,[12] which detonated 5.2 m (17 ft) beneath ground level.[10] The test was designed as a scaled-down investigation of the effects of a 23-kiloton ground-penetrating gun-type fission weapon that was then being considered for use as a cratering and bunker-buster weapon.[13] The explosion resulted in a cloud that rose to 3,500 m (11,500 ft), and deposited fallout to the north and north-northeast.[14] The resulting crater was 79 m (260 ft) wide and 16 m (53 ft) deep.[13]

 
Teapot Ess

The next underground test was Teapot Ess, on 23 March 1955.[10] The one-kiloton explosion was an operational test of an 'Atomic Demolition Munition' (ADM).[15] It was detonated 20.4 m (67 ft) underground, in a shaft lined with corrugated steel, which was then back-filled with sandbags and dirt.[16] Because the ADM was buried underground, the explosion blew tons of earth upwards,[15] creating a crater 91 m (300 ft) wide and 39 m (128 ft) deep.[16] The resulting mushroom cloud rose to a height of 3,700 m (12,000 ft) and subsequent radioactive fallout drifted in an easterly direction, travelling as far as 225 km (140 mi) from ground zero.[15]

On 26 July 1957, Plumbbob Pascal-A was detonated at the bottom of a 148 m (486 ft) shaft.[17][18] According to one description, it "ushered in the era of underground testing with a magnificent pyrotechnic roman candle!"[19] As compared with an above-ground test, the radioactive debris released to the atmosphere was reduced by a factor of ten.[19] Theoretical work began on possible containment schemes.[19]

 
Dust raised by Plumbbob Rainier
 
Layout of the Plumbbob Rainier tunnel

Plumbbob Rainier was detonated at 899 ft (274 m) underground on 19 September 1957.[17] The 1.7 kt explosion was the first to be entirely contained underground, producing no fallout.[20] The test took place in a 1,600[21] – 2,000 ft[22] (488 – 610 m) horizontal tunnel in the shape of a hook.[22] The hook "was designed so explosive force will seal off the non-curved portion of tunnel nearest the detonation before gases and fission fragments can be vented around the curve of the tunnel's hook".[22] This test would become the prototype for larger, more powerful tests.[20] Rainier was announced in advance, so that seismic stations could attempt to record a signal.[23] Analysis of samples collected after the test enabled scientists to develop an understanding of underground explosions that "persists essentially unaltered today".[23] The information would later provide a basis for subsequent decisions to agree to the Limited Test Ban Treaty.[23]

Cannikin, the last test at the facility on Amchitka, was detonated on 6 November 1971. At approximately 5 megatons, it was the largest underground test in US history.[24]

Effects edit

 
Relative crater sizes and shapes resulting from various burst depths

The effects of an underground nuclear test may vary according to factors including the depth and yield of the explosion, as well as the nature of the surrounding rock.[25] If the test is conducted at sufficient depth, the test is said to be contained, with no venting of gases or other contaminants to the environment.[25] In contrast, if the device is buried at insufficient depth ("underburied"), then rock may be expelled by the explosion, forming a subsidence crater surrounded by ejecta, and releasing high-pressure gases to the atmosphere (the resulting crater is usually conical in profile, circular, and may range between tens to hundreds of metres in diameter and depth[26]). One figure used in determining how deeply the device should be buried is the scaled depth of burial, or -burst (SDOB)[25] This figure is calculated as the burial depth in metres divided by the cube root of the yield in kilotons. It is estimated that, in order to ensure containment, this figure should be greater than 100.[25][27]

Zones in surrounding rock
Name Radius[26]
Melt cavity 4–12 m/kt1/3
Crushed zone 30–40 m/kt1/3
Cracked zone 80–120 m/kt1/3
Zone of irreversible strain 800–1100 m/kt1/3

The energy of the nuclear explosion is released in one microsecond. In the following few microseconds, the test hardware and surrounding rock are vaporised, with temperatures of several million degrees and pressures of several million atmospheres.[25] Within milliseconds, a bubble of high-pressure gas and steam is formed. The heat and expanding shock wave cause the surrounding rock to vaporise, or be melted further away, creating a melt cavity.[26] The shock-induced motion and high internal pressure cause this cavity to expand outwards, which continues over several tenths of a second until the pressure has fallen sufficiently, to a level roughly comparable with the weight of the rock above, and can no longer grow.[26] Although not observed in every explosion, four distinct zones (including the melt cavity) have been described in the surrounding rock. The crushed zone, about two times the radius of the cavity, consists of rock that has lost all of its former integrity. The cracked zone, about three times the cavity radius, consists of rock with radial and concentric fissures. Finally, the zone of irreversible strain consists of rock deformed by the pressure.[26] The following layer undergoes only an elastic deformation; the strain and subsequent release then forms a seismic wave. A few seconds later the molten rock starts collecting on the bottom of the cavity and the cavity content begins cooling. The rebound after the shock wave causes compressive forces to build up around the cavity, called a stress containment cage, sealing the cracks.[28]

 
Subsidence crater formed by Huron King

Several minutes to days later, once the heat dissipates enough, the steam condenses, and the pressure in the cavity falls below the level needed to support the overburden, the rock above the void falls into the cavity. Depending on various factors, including the yield and characteristics of the burial, this collapse may extend to the surface. If it does, a subsidence crater is created.[26] Such a crater is usually bowl-shaped, and ranges in size from a few tens of metres to over a kilometre in diameter.[26] At the Nevada Test Site, 95 percent of tests conducted at a scaled depth of burial (SDOB) of less than 150 caused surface collapse, compared with about half of tests conducted at a SDOB of less than 180.[26] The radius r (in feet) of the cavity is proportional to the cube root of the yield y (in kilotons), r = 55 *  ; an 8 kiloton explosion will create a cavity with radius of 110 feet (34 m).[28]

 
Rubble mound formed by Whetstone Sulky

Other surface features may include disturbed ground, pressure ridges, faults, water movement (including changes to the water table level), rockfalls, and ground slump.[26] Most of the gas in the cavity is composed of steam; its volume decreases dramatically as the temperature falls and the steam condenses. There are however other gases, mostly carbon dioxide and hydrogen, which do not condense and remain gaseous. The carbon dioxide is produced by thermal decomposition of carbonates, hydrogen is created by reaction of iron and other metals from the nuclear device and surrounding equipment. The amount of carbonates and water in the soil and the available iron have to be considered in evaluating the test site containment; water-saturated clay soils may cause structural collapse and venting. Hard basement rock may reflect shock waves of the explosion, also possibly causing structural weakening and venting. The noncondensible gases may stay absorbed in the pores in the soil. Large amount of such gases can however maintain enough pressure to drive the fission products to the ground.[28]

 
Radioactivity release during Baneberry

Escape of radioactivity from the cavity is known as containment failure. Massive, prompt, uncontrolled releases of fission products, driven by the pressure of steam or gas, are known as venting; an example of such failure is the Baneberry test. Slow, low-pressure uncontrolled releases of radioactivity are known as seeps; these have little to no energy, are not visible and have to be detected by instruments. Late-time seeps are releases of noncondensable gases days or weeks after the blast, by diffusion through pores and crack, probably assisted by a decrease of atmospheric pressure (so called atmospheric pumping). When the test tunnel has to be accessed, controlled tunnel purging is performed; the gases are filtered, diluted by air and released to atmosphere when the winds will disperse them over sparsely populated areas. Small activity leaks resulting from operational aspects of tests are called operational releases; they may occur e.g. during drilling into the explosion location during core sampling, or during the sampling of explosion gases. The radionuclide composition differs by the type of releases; large prompt venting releases significant fraction (up to 10%) of fission products, while late-time seeps contain only the most volatile gases. Soil absorbs the reactive chemical compounds, so the only nuclides filtered through soil into the atmosphere are the noble gases, primarily krypton-85 and xenon-133.[28]

The released nuclides can undergo bio-accumulation. Radioactive isotopes like iodine-131, strontium-90 and caesium-137 are concentrated in the milk of grazing cows; cow milk is therefore a convenient, sensitive fallout indicator. Soft tissues of animals can be analyzed for gamma emitters, bones and liver for strontium and plutonium, and blood, urine and soft tissues are analyzed for tritium.[28]

Although there were early concerns about earthquakes arising as a result of underground tests, there is no evidence that this has occurred.[25] However, fault movements and ground fractures have been reported, and explosions often precede a series of aftershocks, thought to be a result of cavity collapse and chimney formation. In a few cases, seismic energy released by fault movements has exceeded that of the explosion itself.[25]

International treaties edit

Signed in Moscow on August 5, 1963, by representatives of the United States, the Soviet Union, and the United Kingdom, the Limited Test Ban Treaty agreed to ban nuclear testing in the atmosphere, in space, and underwater.[6] Due to the Soviet government's concern about the need for on-site inspections, underground tests were excluded from the ban.[6] 108 countries would eventually sign the treaty, with the significant exception of China.[29]

In 1974, the United States and the Soviet Union signed the Threshold Test Ban Treaty (TTBT) which banned underground tests with yields greater than 150 kilotons.[30] By the 1990s, technologies to monitor and detect underground tests had matured to the point that tests of one kiloton or over could be detected with high probability, and in 1996 negotiations began under the auspices of the United Nations to develop a comprehensive test ban.[29] The resulting Comprehensive Nuclear-Test-Ban Treaty was signed in 1996 by the United States, Russia, United Kingdom, France, and China.[29] However, following the United States Senate decision not to ratify the treaty in 1999, it is still yet to be ratified by 8 of the required 44 'Annex 2' states and so has not entered into force as United Nations law.

Monitoring edit

In the late 1940s, the United States began to develop the capability to detect atmospheric testing using air sampling; this system was able to detect the first Soviet test in 1949.[30] Over the next decade, this system was improved, and a network of seismic monitoring stations was established to detect underground tests.[30] Development of the Threshold Test Ban Treaty in the mid-1970s led to an improved understanding of the relationship between test yield and resulting seismic magnitude.[30]

When negotiations began in the mid-1990s to develop a comprehensive test ban, the international community was reluctant to rely upon the detection capabilities of individual nuclear weapons states (especially the United States), and instead wanted an international detection system.[30] The resulting International Monitoring System (IMS) consists of a network of 321 monitoring stations, and 16 radionuclide laboratories.[31] Fifty "primary" seismic stations send data continuously to the International Data Center, along with 120 "auxiliary" stations which send data on request. The resulting data is used to locate the epicentre, and distinguish between the seismic signatures of an underground nuclear explosion and an earthquake.[30][32] Additionally, eighty radionuclide stations detect radioactive particles vented by underground explosions. Certain radionuclides constitute clear evidence of nuclear tests; the presence of noble gases can indicate whether an underground explosion has taken place.[33] Finally, eleven hydroacoustic stations[34] and sixty infrasound stations[35] monitor underwater and atmospheric tests.

Gallery edit

  •  
    Buster-Jangle Uncle
  •  
    Teapot Ess
  •  
    Storax Sedan
  •  
    Sedan Crater
  •  
    Bowline Schooner
  •  
    Nevada Test Site subsidence craters

See also edit

Notes and references edit

  1. ^ a b . The Preparatory Commission for the Comprehensive Nuclear-Test-Ban Treaty Organization. Archived from the original on 2007-03-03.
  2. ^ a b c d Ortmeyer, Pat; Makhijani, Arjun (November–December 1997). "Worse Than We Knew". Bulletin of the Atomic Scientists. 53 (6): 46–50. Bibcode:1997BuAtS..53f..46O. doi:10.1080/00963402.1997.11456789.
  3. ^ a b c Eisenbud, Merril (July 1997). (PDF). Health Physics. 73 (1): 21–27. doi:10.1097/00004032-199707000-00002. PMID 9199215. Archived from the original (PDF) on October 14, 2006.
  4. ^ . Public Broadcasting Service. Archived from the original on 2016-08-01. Retrieved 2017-09-03.
  5. ^ a b c "Treaty Banning Nuclear Weapon Tests in the Atmosphere, in Outer Space and Under Water". US Department of State.
  6. ^ a b c d "JFK in History: Nuclear Test Ban Treaty". John F. Kennedy Presidential Library and Museum.
  7. ^ a b Gladeck, F.; Johnson, A. (1986). . Defense Nuclear Agency. Archived from the original on May 22, 2011.
  8. ^ U.S. Department of Energy, Nevada Operations Office (December 1998). Amchitka Island, Alaska: Potential U.S. Department of Energy site responsibilities (DOE/NV-526) (Report). Department of Energy. doi:10.2172/758922. Retrieved 2006-10-09.
  9. ^ . The Center for the Study of Technology and Society. Archived from the original on 2002-04-21.
  10. ^ a b c Adushkin, Vitaly V.; Leith, William (September 2001). (PDF). US Department of the Interior Geological Survey. Archived from the original (PDF) on 2013-05-09.
  11. ^ Some sources identify later tests as the "first". Adushkin (2001) defines such a test as "the near-simultaneous detonation of one or more nuclear charges inside one underground excavation (a tunnel, shaft or borehole)", and identifies Uncle as the first.
  12. ^ Some sources refer to the test as Jangle Uncle (e.g., Adushkin, 2001) or Project Windstorm (e.g., DOE/NV-526, 1998). Operation Buster and Operation Jangle were initially conceived as separate operations, and Jangle was at first known as Windstorm, but the AEC merged the plans into a single operation on 19 June 1951. See Gladeck, 1986.
  13. ^ a b "Operation Buster-Jangle". The Nuclear Weapons Archive.
  14. ^ Ponton, Jean; et al. (June 1982). (PDF). Defense Nuclear Agency. Archived from the original (PDF) on 2007-07-10.
  15. ^ a b c Ponton, Jean; et al. (November 1981). (PDF). Defense Nuclear Agency. Archived from the original (PDF) on 2007-07-10.
  16. ^ a b "Operation Teapot". The Nuclear Weapons Archive.
  17. ^ a b "Operation Plumbbob". The Nuclear Weapons Archive.
  18. ^ According to the Nuclear Weapons Archive, the yield is described as "slight", but was approximately 55 tons.
  19. ^ a b c Campbell, Bob; et al. (1983). "Field Testing: The Physical Proof of Design Principles" (PDF). Los Alamos Science.
  20. ^ a b . Department of Energy. Archived from the original on 2006-09-25.
  21. ^ Rollins, Gene (2004). (PDF). Centers for Disease Control. Archived from the original (PDF) on 2006-06-25. Retrieved 2017-09-17.
  22. ^ a b c "Plumbbob Photographs" (PDF). Los Alamos National Laboratory.
  23. ^ a b c . Lawrence Livermore National Laboratory. Archived from the original on 2004-12-05.
  24. ^ Miller, Pam. (PDF). Archived from the original (PDF) on September 28, 2006. Retrieved 2006-10-09.
  25. ^ a b c d e f g McEwan, A. C. (1988). "Environmental effects of underground nuclear explosions". In Goldblat, Jozef; Cox, David (eds.). Nuclear Weapon Tests: Prohibition Or Limitation?. Oxford University Press. pp. 75–79. ISBN 0-19-829120-5.
  26. ^ a b c d e f g h i Hawkins, Wohletz (1996). (PDF). Los Alamos National Laboratory. Archived from the original (PDF) on 2008-10-30. Retrieved 2008-05-05.
  27. ^ Hawkins and Wohletz specify a figure of 90–125.
  28. ^ a b c d e The Containment of Underground Nuclear Explosions. (PDF) . Retrieved on 2010-02-08.
  29. ^ a b c "The Making of the Limited Test Ban Treaty, 1958–1963". The George Washington University.
  30. ^ a b c d e f National Academy of Sciences (2002). Technical Issues Related to the Comprehensive Nuclear Test Ban Treaty. National Academies. ISBN 0-309-08506-3.
  31. ^ . Comprehensive Nuclear-Test-Ban Treaty Organization. Archived from the original on 2008-05-09.
  32. ^ . Comprehensive Nuclear-Test-Ban Treaty Organization. Archived from the original on 2003-06-21.
  33. ^ . Comprehensive Nuclear-Test-Ban Treaty Organization. Archived from the original on 2004-06-10.
  34. ^ . Comprehensive Nuclear-Test-Ban Treaty Organization. Archived from the original on 2003-02-19.
  35. ^ "Verification Technologies: Infrasound". Comprehensive Nuclear-Test-Ban Treaty Organization.[permanent dead link]

Further reading edit

  • "The Containment of Underground Nuclear Explosions", Project Director Gregory E van der Vink, U.S. Congress, Office of Technology Assessment, OTA-ISC-414, (Oct 1989).

External links edit


April 26, 2024
underground, nuclear, weapons, testing, underground, nuclear, testing, test, detonation, nuclear, weapons, that, performed, underground, when, device, being, tested, buried, sufficient, depth, nuclear, explosion, contained, with, release, radioactive, material. Underground nuclear testing is the test detonation of nuclear weapons that is performed underground When the device being tested is buried at sufficient depth the nuclear explosion may be contained with no release of radioactive materials to the atmosphere Preparation for an underground nuclear test at the Nevada Test Site in the 1990s as the diagnostic cables are being installed The extreme heat and pressure of an underground nuclear explosion causes changes in the surrounding rock The rock closest to the location of the test is vaporised forming a cavity Farther away there are zones of crushed cracked and irreversibly strained rock Following the explosion the rock above the cavity may collapse forming a rubble chimney If this chimney reaches the surface a bowl shaped subsidence crater may form The first underground test took place in 1951 Further tests soon led scientists to conclude that even notwithstanding environmental and diplomatic considerations underground testing was of far greater scientific value than all other forms of testing This understanding strongly influenced the governments of the first three nuclear powers to sign of the Limited Test Ban Treaty in 1963 which banned all nuclear tests except for those performed underground From then until the signing of the Comprehensive Nuclear Test Ban Treaty in 1996 most nuclear tests were performed underground which prevented additional nuclear fallout from entering into the atmosphere Contents 1 Background 2 Early history of underground testing 3 Effects 4 International treaties 4 1 Monitoring 5 Gallery 6 See also 7 Notes and references 8 Further reading 9 External linksBackground editPublic concern about fallout from nuclear testing grew in the early 1950s 1 2 Fallout was discovered after the Trinity test the first ever atomic bomb test in 1945 2 Photographic film manufacturers later reported fogged films this was traced to packaging materials sourced from Indiana crops contaminated by Trinity and later tests at the Nevada Test Site over 1 000 miles 1600 kilometres away 2 Intense fallout from the 1953 Simon test was documented as far as Albany New York 2 The fallout from the March 1954 Bravo test in the Pacific Ocean had scientific political and social implications that have continued for more than 40 years 3 The multi megaton test caused fallout to occur on the islands of the Rongerik and Rongelap atolls and a Japanese fishing boat known as the Daigo Fukuryu Maru Lucky Dragon 3 Prior to this test there was insufficient appreciation of the dangers of fallout 3 The test became an international incident In a Public Broadcasting Service PBS interview the historian Martha Smith argued In Japan it becomes a huge issue in terms of not just the government and its protest against the United States but all different groups and all different peoples in Japan start to protest It becomes a big issue in the media There are all kinds of letters and protests that come from not surprisingly Japanese fishermen the fishermen s wives there are student groups all different types of people that protest against the Americans use of the Pacific for nuclear testing They re very concerned about first of all why the United States even has the right to be carrying out those kinds of tests in the Pacific They re also concerned about the health and environmental impact 4 The Prime Minister of India voiced the heightened international concern when he called for the elimination of all nuclear testing worldwide who 1 Knowledge about fallout and its effects grew and with it concern about the global environment and long term genetic damage 5 Talks between the United States the United Kingdom Canada France and the Soviet Union began in May 1955 on the subject of an international agreement to end nuclear tests 5 On August 5 1963 representatives of the United States the Soviet Union and the United Kingdom signed the Limited Test Ban Treaty forbidding testing of nuclear weapons in the atmosphere in space and underwater 6 Agreement was facilitated by the decision to allow underground testing eliminating the need for on site inspections that concerned the Soviets 6 Underground testing was allowed provided that it does not cause radioactive debris to be present outside the territorial limits of the State under whose jurisdiction or control such explosion is conducted 5 Early history of underground testing editThe examples and perspective in this article deal primarily with the United States and do not represent a worldwide view of the subject You may improve this article discuss the issue on the talk page or create a new article as appropriate December 2010 Learn how and when to remove this template message Following analysis of underwater detonations that were part of Operation Crossroads in 1946 inquiries were made regarding the possible military value of an underground explosion 7 The US Joint Chiefs of Staff thus obtained the agreement of the United States Atomic Energy Commission AEC to perform experiments on both surface and sub surface detonations 7 The Alaskan island of Amchitka was initially selected for these tests in 1950 but the site was later deemed unsuitable and the tests were moved to the Nevada Test Site 8 nbsp Buster Jangle Uncle the first underground nuclear explosion The first underground nuclear test was conducted on 29 November 1951 9 10 11 This was the 1 2 kiloton Buster Jangle Uncle 12 which detonated 5 2 m 17 ft beneath ground level 10 The test was designed as a scaled down investigation of the effects of a 23 kiloton ground penetrating gun type fission weapon that was then being considered for use as a cratering and bunker buster weapon 13 The explosion resulted in a cloud that rose to 3 500 m 11 500 ft and deposited fallout to the north and north northeast 14 The resulting crater was 79 m 260 ft wide and 16 m 53 ft deep 13 nbsp Teapot Ess The next underground test was Teapot Ess on 23 March 1955 10 The one kiloton explosion was an operational test of an Atomic Demolition Munition ADM 15 It was detonated 20 4 m 67 ft underground in a shaft lined with corrugated steel which was then back filled with sandbags and dirt 16 Because the ADM was buried underground the explosion blew tons of earth upwards 15 creating a crater 91 m 300 ft wide and 39 m 128 ft deep 16 The resulting mushroom cloud rose to a height of 3 700 m 12 000 ft and subsequent radioactive fallout drifted in an easterly direction travelling as far as 225 km 140 mi from ground zero 15 On 26 July 1957 Plumbbob Pascal A was detonated at the bottom of a 148 m 486 ft shaft 17 18 According to one description it ushered in the era of underground testing with a magnificent pyrotechnic roman candle 19 As compared with an above ground test the radioactive debris released to the atmosphere was reduced by a factor of ten 19 Theoretical work began on possible containment schemes 19 nbsp Dust raised by Plumbbob Rainier nbsp Layout of the Plumbbob Rainier tunnel Plumbbob Rainier was detonated at 899 ft 274 m underground on 19 September 1957 17 The 1 7 kt explosion was the first to be entirely contained underground producing no fallout 20 The test took place in a 1 600 21 2 000 ft 22 488 610 m horizontal tunnel in the shape of a hook 22 The hook was designed so explosive force will seal off the non curved portion of tunnel nearest the detonation before gases and fission fragments can be vented around the curve of the tunnel s hook 22 This test would become the prototype for larger more powerful tests 20 Rainier was announced in advance so that seismic stations could attempt to record a signal 23 Analysis of samples collected after the test enabled scientists to develop an understanding of underground explosions that persists essentially unaltered today 23 The information would later provide a basis for subsequent decisions to agree to the Limited Test Ban Treaty 23 Cannikin the last test at the facility on Amchitka was detonated on 6 November 1971 At approximately 5 megatons it was the largest underground test in US history 24 Effects edit nbsp Relative crater sizes and shapes resulting from various burst depths The effects of an underground nuclear test may vary according to factors including the depth and yield of the explosion as well as the nature of the surrounding rock 25 If the test is conducted at sufficient depth the test is said to be contained with no venting of gases or other contaminants to the environment 25 In contrast if the device is buried at insufficient depth underburied then rock may be expelled by the explosion forming a subsidence crater surrounded by ejecta and releasing high pressure gases to the atmosphere the resulting crater is usually conical in profile circular and may range between tens to hundreds of metres in diameter and depth 26 One figure used in determining how deeply the device should be buried is the scaled depth of burial or burst SDOB 25 This figure is calculated as the burial depth in metres divided by the cube root of the yield in kilotons It is estimated that in order to ensure containment this figure should be greater than 100 25 27 Zones in surrounding rock Name Radius 26 Melt cavity 4 12 m kt1 3 Crushed zone 30 40 m kt1 3 Cracked zone 80 120 m kt1 3 Zone of irreversible strain 800 1100 m kt1 3 The energy of the nuclear explosion is released in one microsecond In the following few microseconds the test hardware and surrounding rock are vaporised with temperatures of several million degrees and pressures of several million atmospheres 25 Within milliseconds a bubble of high pressure gas and steam is formed The heat and expanding shock wave cause the surrounding rock to vaporise or be melted further away creating a melt cavity 26 The shock induced motion and high internal pressure cause this cavity to expand outwards which continues over several tenths of a second until the pressure has fallen sufficiently to a level roughly comparable with the weight of the rock above and can no longer grow 26 Although not observed in every explosion four distinct zones including the melt cavity have been described in the surrounding rock The crushed zone about two times the radius of the cavity consists of rock that has lost all of its former integrity The cracked zone about three times the cavity radius consists of rock with radial and concentric fissures Finally the zone of irreversible strain consists of rock deformed by the pressure 26 The following layer undergoes only an elastic deformation the strain and subsequent release then forms a seismic wave A few seconds later the molten rock starts collecting on the bottom of the cavity and the cavity content begins cooling The rebound after the shock wave causes compressive forces to build up around the cavity called a stress containment cage sealing the cracks 28 nbsp Subsidence crater formed by Huron King Several minutes to days later once the heat dissipates enough the steam condenses and the pressure in the cavity falls below the level needed to support the overburden the rock above the void falls into the cavity Depending on various factors including the yield and characteristics of the burial this collapse may extend to the surface If it does a subsidence crater is created 26 Such a crater is usually bowl shaped and ranges in size from a few tens of metres to over a kilometre in diameter 26 At the Nevada Test Site 95 percent of tests conducted at a scaled depth of burial SDOB of less than 150 caused surface collapse compared with about half of tests conducted at a SDOB of less than 180 26 The radius r in feet of the cavity is proportional to the cube root of the yield y in kilotons r 55 y 3 displaystyle sqrt 3 y nbsp an 8 kiloton explosion will create a cavity with radius of 110 feet 34 m 28 nbsp Rubble mound formed by Whetstone Sulky Other surface features may include disturbed ground pressure ridges faults water movement including changes to the water table level rockfalls and ground slump 26 Most of the gas in the cavity is composed of steam its volume decreases dramatically as the temperature falls and the steam condenses There are however other gases mostly carbon dioxide and hydrogen which do not condense and remain gaseous The carbon dioxide is produced by thermal decomposition of carbonates hydrogen is created by reaction of iron and other metals from the nuclear device and surrounding equipment The amount of carbonates and water in the soil and the available iron have to be considered in evaluating the test site containment water saturated clay soils may cause structural collapse and venting Hard basement rock may reflect shock waves of the explosion also possibly causing structural weakening and venting The noncondensible gases may stay absorbed in the pores in the soil Large amount of such gases can however maintain enough pressure to drive the fission products to the ground 28 nbsp Radioactivity release during Baneberry Escape of radioactivity from the cavity is known as containment failure Massive prompt uncontrolled releases of fission products driven by the pressure of steam or gas are known as venting an example of such failure is the Baneberry test Slow low pressure uncontrolled releases of radioactivity are known as seeps these have little to no energy are not visible and have to be detected by instruments Late time seeps are releases of noncondensable gases days or weeks after the blast by diffusion through pores and crack probably assisted by a decrease of atmospheric pressure so called atmospheric pumping When the test tunnel has to be accessed controlled tunnel purging is performed the gases are filtered diluted by air and released to atmosphere when the winds will disperse them over sparsely populated areas Small activity leaks resulting from operational aspects of tests are called operational releases they may occur e g during drilling into the explosion location during core sampling or during the sampling of explosion gases The radionuclide composition differs by the type of releases large prompt venting releases significant fraction up to 10 of fission products while late time seeps contain only the most volatile gases Soil absorbs the reactive chemical compounds so the only nuclides filtered through soil into the atmosphere are the noble gases primarily krypton 85 and xenon 133 28 The released nuclides can undergo bio accumulation Radioactive isotopes like iodine 131 strontium 90 and caesium 137 are concentrated in the milk of grazing cows cow milk is therefore a convenient sensitive fallout indicator Soft tissues of animals can be analyzed for gamma emitters bones and liver for strontium and plutonium and blood urine and soft tissues are analyzed for tritium 28 Although there were early concerns about earthquakes arising as a result of underground tests there is no evidence that this has occurred 25 However fault movements and ground fractures have been reported and explosions often precede a series of aftershocks thought to be a result of cavity collapse and chimney formation In a few cases seismic energy released by fault movements has exceeded that of the explosion itself 25 International treaties editSigned in Moscow on August 5 1963 by representatives of the United States the Soviet Union and the United Kingdom the Limited Test Ban Treaty agreed to ban nuclear testing in the atmosphere in space and underwater 6 Due to the Soviet government s concern about the need for on site inspections underground tests were excluded from the ban 6 108 countries would eventually sign the treaty with the significant exception of China 29 In 1974 the United States and the Soviet Union signed the Threshold Test Ban Treaty TTBT which banned underground tests with yields greater than 150 kilotons 30 By the 1990s technologies to monitor and detect underground tests had matured to the point that tests of one kiloton or over could be detected with high probability and in 1996 negotiations began under the auspices of the United Nations to develop a comprehensive test ban 29 The resulting Comprehensive Nuclear Test Ban Treaty was signed in 1996 by the United States Russia United Kingdom France and China 29 However following the United States Senate decision not to ratify the treaty in 1999 it is still yet to be ratified by 8 of the required 44 Annex 2 states and so has not entered into force as United Nations law Monitoring edit In the late 1940s the United States began to develop the capability to detect atmospheric testing using air sampling this system was able to detect the first Soviet test in 1949 30 Over the next decade this system was improved and a network of seismic monitoring stations was established to detect underground tests 30 Development of the Threshold Test Ban Treaty in the mid 1970s led to an improved understanding of the relationship between test yield and resulting seismic magnitude 30 When negotiations began in the mid 1990s to develop a comprehensive test ban the international community was reluctant to rely upon the detection capabilities of individual nuclear weapons states especially the United States and instead wanted an international detection system 30 The resulting International Monitoring System IMS consists of a network of 321 monitoring stations and 16 radionuclide laboratories 31 Fifty primary seismic stations send data continuously to the International Data Center along with 120 auxiliary stations which send data on request The resulting data is used to locate the epicentre and distinguish between the seismic signatures of an underground nuclear explosion and an earthquake 30 32 Additionally eighty radionuclide stations detect radioactive particles vented by underground explosions Certain radionuclides constitute clear evidence of nuclear tests the presence of noble gases can indicate whether an underground explosion has taken place 33 Finally eleven hydroacoustic stations 34 and sixty infrasound stations 35 monitor underwater and atmospheric tests Gallery edit nbsp Buster Jangle Uncle nbsp Teapot Ess nbsp Storax Sedan nbsp Sedan Crater nbsp Bowline Schooner nbsp Nevada Test Site subsidence cratersSee also editNuclear weapons testing Subsidence crater Tired mountain syndrome Nuclear bunker buster List of induced seismic eventsNotes and references edit a b History of the Comprehensive Nuclear Test Ban Treaty CTBT The Preparatory Commission for the Comprehensive Nuclear Test Ban Treaty Organization Archived from the original on 2007 03 03 a b c d Ortmeyer Pat Makhijani Arjun November December 1997 Worse Than We Knew Bulletin of the Atomic Scientists 53 6 46 50 Bibcode 1997BuAtS 53f 46O doi 10 1080 00963402 1997 11456789 a b c Eisenbud Merril July 1997 Monitoring distant fallout The role of the Atomic Energy Commission Health and Safety Laboratory during the Pacific tests with special attention to the events following Bravo PDF Health Physics 73 1 21 27 doi 10 1097 00004032 199707000 00002 PMID 9199215 Archived from the original PDF on October 14 2006 Martha Smith on The Impact of the Bravo Test Public Broadcasting Service Archived from the original on 2016 08 01 Retrieved 2017 09 03 a b c Treaty Banning Nuclear Weapon Tests in the Atmosphere in Outer Space and Under Water US Department of State a b c d JFK in History Nuclear Test Ban Treaty John F Kennedy Presidential Library and Museum a b Gladeck F Johnson A 1986 For the Record A History of the Nuclear Test Personnel Review Program 1978 1986 DNA 601F Defense Nuclear Agency Archived from the original on May 22 2011 U S Department of Energy Nevada Operations Office December 1998 Amchitka Island Alaska Potential U S Department of Energy site responsibilities DOE NV 526 Report Department of Energy doi 10 2172 758922 Retrieved 2006 10 09 Today in Technology History November 29 The Center for the Study of Technology and Society Archived from the original on 2002 04 21 a b c Adushkin Vitaly V Leith William September 2001 USGS Open File Report 01 312 Containment of Soviet underground nuclear explosions PDF US Department of the Interior Geological Survey Archived from the original PDF on 2013 05 09 Some sources identify later tests as the first Adushkin 2001 defines such a test as the near simultaneous detonation of one or more nuclear charges inside one underground excavation a tunnel shaft or borehole and identifies Uncle as the first Some sources refer to the test as Jangle Uncle e g Adushkin 2001 or Project Windstorm e g DOE NV 526 1998 Operation Buster and Operation Jangle were initially conceived as separate operations and Jangle was at first known as Windstorm but the AEC merged the plans into a single operation on 19 June 1951 See Gladeck 1986 a b Operation Buster Jangle The Nuclear Weapons Archive Ponton Jean et al June 1982 Shots Sugar and Uncle The final tests of the Buster Jangle series DNA 6025F PDF Defense Nuclear Agency Archived from the original PDF on 2007 07 10 a b c Ponton Jean et al November 1981 Shots Ess through Met and Shot Zucchini The final Teapot tests DNA 6013F PDF Defense Nuclear Agency Archived from the original PDF on 2007 07 10 a b Operation Teapot The Nuclear Weapons Archive a b Operation Plumbbob The Nuclear Weapons Archive According to the Nuclear Weapons Archive the yield is described as slight but was approximately 55 tons a b c Campbell Bob et al 1983 Field Testing The Physical Proof of Design Principles PDF Los Alamos Science a b Operation Plumbbob Department of Energy Archived from the original on 2006 09 25 Rollins Gene 2004 ORAU Team NIOSH Dose Reconstruction Project PDF Centers for Disease Control Archived from the original PDF on 2006 06 25 Retrieved 2017 09 17 a b c Plumbbob Photographs PDF Los Alamos National Laboratory a b c Accomplishments in the 1950s Lawrence Livermore National Laboratory Archived from the original on 2004 12 05 Miller Pam Nuclear Flashback Report of a Greenpeace Scientific Expedition to Amchitka Island Alaska Site of the Largest Underground Nuclear Test in U S History PDF Archived from the original PDF on September 28 2006 Retrieved 2006 10 09 a b c d e f g McEwan A C 1988 Environmental effects of underground nuclear explosions In Goldblat Jozef Cox David eds Nuclear Weapon Tests Prohibition Or Limitation Oxford University Press pp 75 79 ISBN 0 19 829120 5 a b c d e f g h i Hawkins Wohletz 1996 Visual Inspection for CTBT Verification PDF Los Alamos National Laboratory Archived from the original PDF on 2008 10 30 Retrieved 2008 05 05 Hawkins and Wohletz specify a figure of 90 125 a b c d e The Containment of Underground Nuclear Explosions PDF Retrieved on 2010 02 08 a b c The Making of the Limited Test Ban Treaty 1958 1963 The George Washington University a b c d e f National Academy of Sciences 2002 Technical Issues Related to the Comprehensive Nuclear Test Ban Treaty National Academies ISBN 0 309 08506 3 An Overview of the Verification Regime Comprehensive Nuclear Test Ban Treaty Organization Archived from the original on 2008 05 09 Verification Technologies Seismology Comprehensive Nuclear Test Ban Treaty Organization Archived from the original on 2003 06 21 Verification Technologies Radionuclide Comprehensive Nuclear Test Ban Treaty Organization Archived from the original on 2004 06 10 Verification Technologies Hydroacoustics Comprehensive Nuclear Test Ban Treaty Organization Archived from the original on 2003 02 19 Verification Technologies Infrasound Comprehensive Nuclear Test Ban Treaty Organization permanent dead link Further reading edit The Containment of Underground Nuclear Explosions Project Director Gregory E van der Vink U S Congress Office of Technology Assessment OTA ISC 414 Oct 1989 IAEA review of the 1968 book The constructive uses of nuclear explosions by Edward Teller External links edithttps web archive org web 20060908032343 http www princeton edu globsec publications pdf 3 3 4Adushkin pdf Nuclear Pursuits permanent dead link The Bulletin of the Atomic Scientists September October 2003 http www unscear org unscear en publications html https web archive org web 20041218041325 http www ingv it roma SITOINGLESE research projects CTBTO explosions html http www globalsecurity org wmd intro ugt htm https fas org nuke intro nuke ugt nts htm Archived 2015 04 09 at the Wayback Machine http www atomictraveler com UndergroundTestOTA pdf http www pub iaea org MTCD publications PDF Pub1215 web pdf The Soviet Program for Peaceful Uses of Nuclear Explosions M D Nordyke UCRL ID 12441O Rev 2 https web archive org web 20090227073933 http www princeton edu globsec publications effects effects shtml Retrieved from https en wikipedia org w index php title Underground nuclear weapons testing amp oldid 1218356206, wikipedia, wiki, book, books, library,

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