宗旨与使命
筹委会的职责是为《全面禁止核试验条约》生效做好各项准备工作组织介绍
Components of the U.S. B83 gravity bomb - “”dial-a-yield”” option for up to 1200 kilotons.
The Comprehensive Nuclear-Test-Ban Treaty (CTBT) bans nuclear explosions by everyone, everywhere: on the Earth’s surface, in the atmosphere, underwater and underground.
It makes it very difficult for countries to develop nuclear bombs for the first time, or for countries that already have them, to make more powerful bombs. It also prevents the huge damage caused by radioactivity from nuclear explosions to humans, animals and plants.
The five biggest testing nations.
Over 2000 nuclear explosions from 1945 to 1996
Over 2000 nuclear tests were carried out between 1945 and 1996, when the CTBT opened for signature: by the United States (1000+), the Soviet Union (700+), France (200+), the United Kingdom and China (45 each). Three countries have broken the de facto moratorium and tested nuclear weapons since 1996: India and Pakistan in 1998, and the Democratic People’s Republic of Korea (DPRK) in 2006, 2009, 2013 and 2016.
Eight ratifications missing for entry into force.
CTBT almost universal but has yet to become law
Many attempts were made during the Cold War to negotiate a comprehensive test ban, but it was only in the 1990s that the Treaty became a reality. The CTBT was negotiated in Geneva between 1994 and 1996. One hundred and eighty three countries have signed the Treaty, of which 164 have also ratified it, including three of the nuclear weapon States: France, the Russian Federation and the United Kingdom. But 44 specific nuclear technology holder countries must sign and ratify before the CTBT can enter into force. Of these, eight are still missing: China, Egypt, India, Iran, Israel, North Korea, Pakistan and the USA. India, North Korea and Pakistan have yet to sign the CTBT. The last Annex 2 State to ratify the Treaty was Indonesia on 6 February 2012.
The Comprehensive Nuclear-Test-Ban Treaty (CTBT) bans nuclear explosions by everyone, everywhere: on the Earth’s surface, in the atmosphere, underwater and underground.
It makes it very difficult for countries to develop nuclear bombs for the first time, or for countries that already have them, to make more powerful bombs. It also prevents the huge damage caused by radioactivity from nuclear explosions to humans, animals and plants.
The five biggest testing nations.
Over 2000 nuclear explosions from 1945 to 1996
Over 2000 nuclear tests were carried out between 1945 and 1996, when the CTBT opened for signature: by the United States (1000+), the Soviet Union (700+), France (200+), the United Kingdom and China (45 each). Three countries have broken the de facto moratorium and tested nuclear weapons since 1996: India and Pakistan in 1998, and the Democratic People’s Republic of Korea (DPRK) in 2006, 2009, 2013 and 2016.
Eight ratifications missing for entry into force.
CTBT almost universal but has yet to become law
Many attempts were made during the Cold War to negotiate a comprehensive test ban, but it was only in the 1990s that the Treaty became a reality. The CTBT was negotiated in Geneva between 1994 and 1996. One hundred and eighty three countries have signed the Treaty, of which 164 have also ratified it, including three of the nuclear weapon States: France, the Russian Federation and the United Kingdom. But 44 specific nuclear technology holder countries must sign and ratify before the CTBT can enter into force. Of these, eight are still missing: China, Egypt, India, Iran, Israel, North Korea, Pakistan and the USA. India, North Korea and Pakistan have yet to sign the CTBT. The last Annex 2 State to ratify the Treaty was Indonesia on 6 February 2012.
工作领域
Verification regime to make sure that no nuclear explosion goes undetected
The Global Alarm System - click for animation.
The Treaty has a unique and comprehensive verification regime to make sure that no nuclear explosion goes undetected. This regime consists of three pillars:
The International Monitoring System (IMS) will, when complete, consist of 337 facilities worldwide to monitor the planet for signs of nuclear explosions. Around 90 percent of the facilities are already up and running. The IMS uses the following four state-of-the-art technologies (numbers reflect final configuration):
• Seismic: 50 primary and 120 auxiliary seismic stations monitor shockwaves in the Earth. The vast majority of these shockwaves – many thousands every year – are caused by earthquakes. But man-made explosions such as mine explosions or the announced North Korean nuclear tests in 2006, 2009, 2013 and 2016 are also detected.
• Hydroacoustic: 11 hydroacoustic stations “listen” for sound waves in the oceans. Sound waves from explosions can travel extremely far underwater.
• Infrasound: 60 stations on the surface can detect ultra-low frequency sound waves (inaudible to the human ear) that are emitted by large explosions.
• Radionuclide: 80 stations measure the atmosphere for radioactive particles; 40 of them also pick up noble gas. Only these measurements can give a clear indication as to whether an explosion detected by the other methods was actually nuclear or not. They are supported by 16 radionuclide laboratories.
On-Site Inspections
On-site inspections can be dispatched to the area of a suspicious nuclear explosion if the data from the IMS indicate that a nuclear test has taken place there. Inspectors will collect evidence on the ground at the suspected site. Such an inspection can only be requested and approved by Member States once the CTBT has entered into force. Large on-site inspection exercises were carried out in 2008 in Kazakhstan and in 2014 in Jordan.
Helping Tsunami Warning and the Environment
The huge amount of data collected by the stations can also be used for other purposes than detecting nuclear explosions. They can provide tsunami warning centres with almost real-time information about an underwater earthquake, thus helping to warn people earlier and possibly saving lives. During the March 2011 Fukushima power plant accident, the network’s radionuclide stations tracked the dispersion of radioactivity on a global scale. The data could also help us better understand the oceans, volcanoes, climate change, the movement of whales, and many other issues.
The International Data Centre
The International Data Centre at the CTBTO’s headquarters in Vienna receives gigabytes of data from the global monitoring stations. The data are processed and distributed to the CTBTO’s Member States in both raw and analyzed form. When North Korea tested in 2006, 2009 and 2013, the Member States received information about the location, magnitude, time and depth of the tests within two hours - and before the actual test had been announced by North Korea.
The Global Alarm System - click for animation.
The Treaty has a unique and comprehensive verification regime to make sure that no nuclear explosion goes undetected. This regime consists of three pillars:
The International Monitoring System (IMS) will, when complete, consist of 337 facilities worldwide to monitor the planet for signs of nuclear explosions. Around 90 percent of the facilities are already up and running. The IMS uses the following four state-of-the-art technologies (numbers reflect final configuration):
• Seismic: 50 primary and 120 auxiliary seismic stations monitor shockwaves in the Earth. The vast majority of these shockwaves – many thousands every year – are caused by earthquakes. But man-made explosions such as mine explosions or the announced North Korean nuclear tests in 2006, 2009, 2013 and 2016 are also detected.
• Hydroacoustic: 11 hydroacoustic stations “listen” for sound waves in the oceans. Sound waves from explosions can travel extremely far underwater.
• Infrasound: 60 stations on the surface can detect ultra-low frequency sound waves (inaudible to the human ear) that are emitted by large explosions.
• Radionuclide: 80 stations measure the atmosphere for radioactive particles; 40 of them also pick up noble gas. Only these measurements can give a clear indication as to whether an explosion detected by the other methods was actually nuclear or not. They are supported by 16 radionuclide laboratories.
On-Site Inspections
On-site inspections can be dispatched to the area of a suspicious nuclear explosion if the data from the IMS indicate that a nuclear test has taken place there. Inspectors will collect evidence on the ground at the suspected site. Such an inspection can only be requested and approved by Member States once the CTBT has entered into force. Large on-site inspection exercises were carried out in 2008 in Kazakhstan and in 2014 in Jordan.
Helping Tsunami Warning and the Environment
The huge amount of data collected by the stations can also be used for other purposes than detecting nuclear explosions. They can provide tsunami warning centres with almost real-time information about an underwater earthquake, thus helping to warn people earlier and possibly saving lives. During the March 2011 Fukushima power plant accident, the network’s radionuclide stations tracked the dispersion of radioactivity on a global scale. The data could also help us better understand the oceans, volcanoes, climate change, the movement of whales, and many other issues.
The International Data Centre
The International Data Centre at the CTBTO’s headquarters in Vienna receives gigabytes of data from the global monitoring stations. The data are processed and distributed to the CTBTO’s Member States in both raw and analyzed form. When North Korea tested in 2006, 2009 and 2013, the Member States received information about the location, magnitude, time and depth of the tests within two hours - and before the actual test had been announced by North Korea.
