High-altitude nuclear explosion: Difference between revisions
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File:Hardtack_I_Teak_002.jpg|High-altitude nuclear explosion | |||
File:Starfish_prime_35mm_frame.jpg|Starfish Prime explosion | |||
File:EMP_mechanism.png|Electromagnetic pulse mechanism | |||
File:HD.10.069_(10562002014).jpg|High-altitude nuclear explosion | |||
File:Hardtack_I_Orange_002.jpg|High-altitude nuclear explosion | |||
File:Starfish5.JPG|Starfish Prime explosion | |||
File:Operation_Dominic_Starfish-Prime_nuclear_test_from_plane.jpg|Operation Dominic Starfish-Prime nuclear test | |||
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Latest revision as of 11:13, 18 February 2025
High-altitude nuclear explosion refers to a nuclear explosion that occurs at altitudes above the dense layers of the Earth's atmosphere. These explosions are characterized by the creation of an electromagnetic pulse (EMP), which can cause significant damage to electronic systems and infrastructure.
History[edit]
The concept of high-altitude nuclear explosions was first explored during the Cold War, with both the United States and the Soviet Union conducting a series of tests. The most notable of these was the Starfish Prime test conducted by the United States in 1962, which resulted in an EMP that caused electrical damage over 1,400 kilometers away in Hawaii.
Effects[edit]
The primary effect of a high-altitude nuclear explosion is the creation of an EMP. This pulse is a short burst of electromagnetic energy that can disrupt or damage electronic equipment within a large area. The extent of the damage depends on the altitude of the explosion, the yield of the nuclear device, and the proximity of electronic systems to the detonation point.
In addition to the EMP, a high-altitude nuclear explosion can also produce a number of secondary effects. These include ionization of the upper atmosphere, which can disrupt radio communications, and the creation of a nuclear fallout that can spread radioactive particles over a wide area.
Defense and mitigation[edit]
Defending against a high-altitude nuclear explosion involves a combination of missile defense systems to intercept and destroy incoming warheads, and hardening of critical infrastructure to withstand the effects of an EMP. Mitigation strategies include the development of EMP-resistant technologies and the implementation of emergency response plans to manage the aftermath of an explosion.
See also[edit]
| Electromagnetic radiation | ||||||||||
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This electromagnetic radiation related article is a stub.
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High-altitude nuclear explosion -
Starfish Prime explosion -
Electromagnetic pulse mechanism -
High-altitude nuclear explosion -
High-altitude nuclear explosion -
Starfish Prime explosion -
Operation Dominic Starfish-Prime nuclear test
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