Movatterモバイル変換

[0]ホーム
URL:

Jump to content
WikipediaThe Free Encyclopedia
Search

Nuclear detonation detection system

From Wikipedia, the free encyclopedia
Series of devices detecting nuclear explosions

Anuclear detonation detection system (NDDS) is a device or a series of devices that are able to indicate, and pinpoint anuclear explosion has occurred as well as the direction of the explosion. The main purpose of these devices or systems was to verify compliance of countries that signed nucleartreaties such as thePartial Test Ban treaty of 1963 (PTBT) and theTreaty of Tlatelolco.

There are many different ways todetect a nuclear detonation, these includeseismic,hydroacoustic, andinfrasound detection,air sampling, andsatellites. They have their own weaknesses and strengths, as well as different utilities. Each has been used separately, but at present the best results occur when data is used in tandem, since theenergy caused by an explosion will transfer over to different mediums.[1]

Seismic

[edit]

Seismic networks are one of the possibilities of detonation detection. During an above ground nuclear explosion, there will be a blooming mushroom in the sky, but there will also be a vibration through the ground that spreads for a long distance.[2] In the 1980s, nuclear weapons testing was moved below ground. Even then, it is hard to detect, and especially tricky when the explosion has a small yield. With a seismic network, detection of these nuclear tests is possible.

The Partial Test Ban Treaty (PTBT) banned nuclear testing in theatmosphere,underwater, and inouter space. TheU.S. developed many different devices to ensure theSoviet Union was upholding its part of the treaty. The PTBT aimed to ban underground testing as well, but at the time thetechnology could not detect detonations very well with seismographs, let alone differentiate them from earthquakes[3] making underground tests more difficult to identify than detonations in the atmosphere or underwater. Larger yields could be differentiated but the smaller ones could not be. Even then larger explosions could be dampened by a larger cavity in the ground.[4] With the threat of the Soviet Union conducting underground detonations the U.S. pumped money intoseismologyresearch.

Hydroacoustic

[edit]

There are 11hydroacoustic stations that are set up to monitor any activity in the oceans. They were developed to ensure the ban on underwater testing, and because ofwater’s ability to carry sound they are very efficient.[5] These stations collect data in real time, work 24 hours a day for 365 days a year. However, hydroacoustics have difficulties pinpointing the location of an explosion or event, so they must be used with another method of detection finding (such as the ones previously mentioned).[6] Other problems that hydroacoustics face are the difficulties caused by the structure of the sea floor, as well as islands that can block sound. Sound travels the best through deep ocean, so events near shallow water will not be detected as well.[7] However, hydroacoustic devices also serve different purposes and are used as a unique resource for research on ocean phenomena.[8]

Infrasound

[edit]

Infrasound works by having multiple stations that usemicrobarometers to listen for infrasonic waves caused by explosions, volcanoes or other natural occurring events.[9] As with other detection methods, infrasound was developed during the Cold War.[10] These stations were designed to detect explosions with forces as low as 1 kiloton. But after the PTBT, atmospheric detonation detection was left to satellites.[11] Although infrasound waves could travel across the earth multiple times they are very prone to being influenced by the wind and by temperature variations.[12] Sources of long range infrasonic waves are difficult to differentiate (e.g. chemical explosion vs. nuclear explosion).[citation needed]

Air sampling

[edit]

Another way of detecting a nuclear detonation is through air sampling; after a nuclear explosion,radioactive isotopes that get released into the air can be collected by plane. Theseradionuclides includeamericium-241,iodine-131,caesium-137,krypton-85,strontium-90,plutonium-239,tritium andxenon.[13] Sending planes over or near an area can reveal if there was a recent nuclear detonation, though most air samples are taken at one of many radionuclide stations set throughout the world. Even underground detonations will eventually release radioactivegases (most notably xenon) which can also be detected via these methods. Issues with air-sampling detection instruments include sensitivity, convenience, reliability, accuracy and power requirements.[14]

One weakness of the air sampling method is that air currents can move the gases or radionuclides in unpredictable ways, depending on where the explosion was and theweather conditions at the time.[1] The detection process involves taking air samples with afilter paper which collects the radioactive material which can then be counted and analyzed by acomputer. Outside “noise” such as other forms ofradiation, like those released fromfactories ornuclear plants, can throw off the results.[15] Another weakness of this method is that special media must be used for certainradionuclides.[14]Radioactive iodine is an example of this, as it exists in many chemical forms, combined with an array of many different gases that are not suitable for direct reading methods using absorption or collection of a fixed volume in containers.[14]

An example of how air currents can easily disperse radioactiveparticles is theChernobyl disaster; as thereactor started failing, a large amount of radionuclides were released into the air. Spread byair currents, this led to radiation that could be detected as far asSweden and other countries hundreds of miles away from the plant within a few days;[16] the same occurred at theFukushima Daiichi disaster. The spread of radioactive xenon gas, iodine-131, and caesium-137 could be detected on differentcontinents many miles away.[17]

Satellites

[edit]

Satellites rely on sensors to monitor radiation from nuclear explosions that always producegamma rays,x-rays, andneutrons.[3] Nuclear explosions release a massive burst of x-rays that occur repeatedly with an interval of less than 1 microsecond that could be detected by the satellite.[18] Groups of satellites can pick up on these signals, and can triangulate the location of the explosion. Satellites were first used in 1963 and throughout theCold War to ensure no nuclear testing was conducted. A minor drawback to the satellite detection method is that there are somecosmic rays that emit neutrons and could give false signals to the sensor.[19]

Starting in October 17, 1963, in the USA, dedicatedVela Satellites were first used by the Air Force and theAtomic Energy Commission, which is a predecessor organization to the currentDepartment of Energy.[18] The Vela satellite was created following thePTBT (Partial Test Ban Treaty), which was signed in August 1963.[20] Vela's purpose was to respond to the PTBT, as a nuclear detonation detector. Vela is considered as a GPA satellite, while the Department of Energy operates the sensors.[18] The project consisted of 12 satellites, each equipped with x-ray, neutron, and gamma ray detectors.[21] and also was equipped to measure physical outputs: light(via a photodiode), and radio waves.

Satellites are now also equipped with cameras measuring the complete visible light spectrum that are able to capture above ground explosions.[citation needed] With the advent ofGlobal Position System (GPS) satellites being launched with nuclear detection systems, satellites have become an important method of detonation detection.[22]

Satellites with improved Space and Atmospheric Burst Reporting System (SABRS) equipment were launched after 2018 with such equipment increasing reliability, reducing size and improving nuclear detonation detection capabilities.[23]

Comprehensive Nuclear Test Ban Treaty

[edit]

TheComprehensive Nuclear Test Ban Treaty (CTBT) banned all forms of nuclear testing in an attempt to disarm and move away from nuclear weapons, but with it came old challenges, such as how to ensure members would not cheat on the treaty. To that end theInternational monitoring system (IMS) was born, having 321 stations, which use all of the sensor types previously described. Using collected data from each source to calculate detonations, the IMS employs hydroacoustic, infrasound, and seismic wave detection systems, as well as air samplers for radionuclides. All of this information is collected by thePreparatory Commission for the Comprehensive Nuclear-Test-Ban Treaty Organization (CTBTO) which is stationed inVienna,Austria.[24]

Effectiveness

[edit]

One of the first occasions when the CTBTO and its detection systems showed itself effective was when it was able to identify nuclear testing byIndia andPakistan in May 1998.[25]

Another notable example is the detection ofNorth Korean testing. As most countries have given up nuclear detonation tests, North Korea has attempted to create a powerful nuclearwarhead.[26] Due to North Korea’s secrecy it is up to IMS to give researchers the information needed to evaluate North Korea’s threats. Even their lowyield (0.6 Kiloton) first attempt at a nuclear weapon was picked up and isolated in 2006.[27]

References

[edit]
  1. ^abNational Research Council (1997).3 Monitoring Technologies: Research Priorities - Research Required to Support Comprehensive Nuclear Test Ban Treaty Monitoring. The National Academies Press.doi:10.17226/5875.ISBN 978-0-309-05826-1. Retrieved20 April 2017.
  2. ^"Could Seismic Networks Reveal Hard-to-Detect Nuclear Tests?".Eos. 25 October 2019. Retrieved2021-05-05.
  3. ^ab"Radiation - Nuclear Radiation - Ionizing Radiation - Health Effects - World Nuclear Association". Retrieved20 April 2017.
  4. ^Latter, A. L.; LeLevier, R. E.; Martinelli, E. A.; McMillan, W. G. (March 1961). "A method of concealing underground nuclear explosions".Journal of Geophysical Research.66 (3):943–946.Bibcode:1961JGR....66..943L.doi:10.1029/JZ066i003p00943.
  5. ^"Hydroacoustic monitoring: CTBTO Preparatory Commission". Retrieved20 April 2017.
  6. ^3 Monitoring Technologies: Research Priorities - Research Required to Support Comprehensive Nuclear Test Ban Treaty Monitoring - The National Academies Press. 1997.doi:10.17226/5875.ISBN 978-0-309-05826-1. Retrieved20 April 2017.
  7. ^3 Monitoring Technologies: Research Priorities - Research Required to Support Comprehensive Nuclear Test Ban Treaty Monitoring - The National Academies Press. 1997.doi:10.17226/5875.ISBN 978-0-309-05826-1. Retrieved20 April 2017.
  8. ^"Acoustical Society of America -A Global Hydroacoustic Monitoring System for the Comprehensive Nuclear-Test-Ban Treaty: Plans and Progress".acoustics.org. Retrieved2021-05-05.
  9. ^"Infrasound monitoring: CTBTO Preparatory Commission". Retrieved20 April 2017.
  10. ^Bedard Jr., Alfred J.; Georges, Thomas M. (2000)."Atmospheric infrasound".Physics Today.53 (3):32–37.Bibcode:2000PhT....53c..32B.doi:10.1063/1.883019.eISSN 0031-9228.ISSN 0031-9228.
  11. ^Medalia, Jonathan. Detection Of Nuclear Weapons And Materials. 1st ed. Washington, D.C: Congressional Research Service, Library of Congress, 2010. Print
  12. ^3 Monitoring Technologies: Research Priorities - Research Required to Support Comprehensive Nuclear Test Ban Treaty Monitoring. The National Academies Press. 1997.doi:10.17226/5875.ISBN 978-0-309-05826-1. Retrieved20 April 2017.
  13. ^"General overview of the effects of nuclear testing: CTBTO Preparatory Commission". Retrieved20 April 2017.
  14. ^abcBreslin, A. J. (1976-11-01).Guidance for air sampling at nuclear facilities. [Radiation monitoring] (Report).doi:10.2172/7326039.OSTI 7326039.
  15. ^"Radionuclide data processing and analysis: CTBTO Preparatory Commission". Retrieved20 April 2017.
  16. ^"Chernobyl's Accident: Path and extension of the radioactive cloud". Retrieved20 April 2017.
  17. ^Axelsson, Anders; Ringbom, Anders (July 2013)."The noble gas releases from Fukushima"(PDF).CTBTO Spectrum. No. 20. Preparatory Commission for the Comprehensive Nuclear-Test-Ban Treaty Organization. pp. 27–31.Archived(PDF) from the original on 2024-04-19. Retrieved2024-04-19.
  18. ^abcHigbie, P. R.; Blocker, N. K. (1993-07-27).The Nuclear Detonation Detection System on the GPS satellites (Report).doi:10.2172/10185731.OSTI 10185731.S2CID 118978885.
  19. ^Medalia, Jonathan. Detection Of Nuclear Weapons And Materials. 1st ed. Washington, D.C: Congressional Research Service, Library of Congress, 2010. Print.
  20. ^Volmar, Axel (January 2013). "Listening to the Cold War: The Nuclear Test Ban Negotiations, Seismology, and Psychoacoustics, 1958–1963".Osiris.28 (1):80–102.doi:10.1086/671364.S2CID 144906607.
  21. ^"The Vela 5A satellite". Retrieved20 April 2017.
  22. ^Holmes, Sue; Sandia National Laboratories."Looking from space for nuclear detonations".phys.org. Retrieved2024-04-19.
  23. ^"NNSA delivers enduring space-based nuclear detonation detection capability".Energy.gov. Retrieved2023-06-07.
  24. ^"History of the International Data Centre".ctbto.org.
  25. ^Barker, B., Clark, M., Davis, P., Fisk, M., Hedlin, M., Israelsson, H., . . . Wallace, T. (1998). Monitoring Nuclear Tests.Science, 281(5385), 1967–1968. Retrieved fromJSTOR 2895717.
  26. ^Davis, William J. Broad, Kenan; Patel, Jugal K. (12 April 2017)."North Korea May Be Preparing Its 6th Nuclear Test".The New York Times. Retrieved20 April 2017.{{cite web}}: CS1 maint: multiple names: authors list (link)
  27. ^"The Comprehensive Test Ban Treaty: Effectively Verifiable". Arms Control Association. Retrieved20 April 2017.
Retrieved from "https://en.wikipedia.org/w/index.php?title=Nuclear_detonation_detection_system&oldid=1307038328"
Category:
Hidden categories:
[8]ページ先頭
©2009-2025 Movatter.jp