of the
Manhattan Project was the first detonation of a nuclear weapon, which led
J. Robert Oppenheimer to recall verses from the
Hindu scripture
Bhagavad Gita: "If the radiance of a thousand suns were to burst at once into the sky, that would be like the splendor of the mighty one" ... "I am become Death, the destroyer of worlds". There are two basic types of nuclear weapons: those that derive the majority of their energy from
nuclear fission reactions alone, and those that use fission reactions to begin
nuclear fusion reactions that produce a large amount of the total energy output.
Fission weapons weapon designs All existing nuclear weapons derive some of their explosive energy from nuclear fission reactions. Weapons whose explosive output is exclusively from fission reactions are commonly referred to as
atomic bombs or
atom bombs (abbreviated as
A-bombs). This has long been noted as something of a
misnomer, as their energy comes from the
nucleus of the atom, just as it does with fusion weapons. In fission weapons, a mass of
fissile material (
enriched uranium or
plutonium) is forced into
supercriticality—allowing an
exponential growth of
nuclear chain reactions—either by shooting one piece of sub-critical material into another (the "gun" method) or by compression of a sub-critical sphere or cylinder of fissile material using chemically fueled
explosive lenses. The latter approach, the "implosion" method, is more sophisticated and more efficient (smaller, less massive, and requiring less of the expensive fissile fuel) than the former. A major challenge in all nuclear weapon designs is to ensure that a significant fraction of the fuel is consumed before the weapon destroys itself. The amount of energy released by fission bombs can range from the equivalent of just under a ton to upwards of 500,000 tons (500
kilotons) of
TNT (). All fission reactions generate
fission products, the remains of the split atomic nuclei. Many fission products are either highly
radioactive (but short-lived) or moderately radioactive (but long-lived), and as such, they are a serious form of
radioactive contamination. Fission products are the principal radioactive component of
nuclear fallout. Another source of radioactivity is the burst of free neutrons produced by the weapon. When they collide with other nuclei in the surrounding material, the neutrons transmute those nuclei into other isotopes, altering their stability and making them radioactive. The most commonly used fissile materials for nuclear weapons applications have been
uranium-235 and
plutonium-239. Less commonly used has been
uranium-233.
Neptunium-237 and some isotopes of
americium may be usable for nuclear explosives as well, but it is not clear that this has ever been implemented, and their plausible use in nuclear weapons is a matter of dispute.
Fusion weapons for a hydrogen bomb: a fission bomb uses radiation to compress and heat a separate section of fusion fuel. The other basic type of nuclear weapon produces a large proportion of its energy in nuclear fusion reactions. Such fusion weapons are generally referred to as
thermonuclear weapons or more colloquially as
hydrogen bombs (abbreviated as
H-bombs), as they rely on fusion reactions between isotopes of
hydrogen (
deuterium and
tritium). All such weapons derive a significant portion of their energy from fission reactions used to "trigger" fusion reactions, and fusion reactions can themselves trigger additional fission reactions. Only six countries—the
United States,
Russia, the
United Kingdom,
China,
France, and
India—have conducted thermonuclear weapon tests. Whether India has detonated a "true" multi-staged
thermonuclear weapon is controversial.
North Korea claims to have tested a fusion weapon , though this claim is disputed. Thermonuclear weapons are considered much more difficult to successfully design and execute than primitive fission weapons. Almost all deployed nuclear weapons use the thermonuclear design because it results in an explosion hundreds of times stronger than that of a fission bomb of similar weight. Thermonuclear bombs use the energy of a fission bomb to compress and heat fusion fuel. In the
Teller-Ulam design, which accounts for all multi-megaton yield hydrogen bombs, this is accomplished by placing a fission bomb and fusion fuel (
tritium,
deuterium, or
lithium deuteride) in proximity within a special, radiation-reflecting container. When the fission bomb is detonated,
gamma rays and
X-rays emitted first compress the fusion fuel, then heat it to thermonuclear temperatures. The ensuing fusion reaction creates enormous numbers of high-speed
neutrons, which can then induce fission in materials not normally prone to it, such as
depleted uranium. Each of these components is known as a "stage", with the fission bomb as the "primary" and the fusion capsule as the "secondary". In large, megaton-range hydrogen bombs, about half of the yield comes from the final fissioning of depleted uranium. In the early 1950s the
Livermore Laboratory in the United States had plans for the testing of two massive bombs, Gnomon and
Sundial, 1 gigaton of TNT and 10 gigatons of TNT respectively. , often referred to as the "father of the hydrogen bomb" Fusion reactions do not create fission products, and thus contribute far less to the creation of
nuclear fallout than fission reactions, but because all
thermonuclear weapons contain at least one
fission stage, and many high-yield thermonuclear devices have a final fission stage, thermonuclear weapons can generate at least as much nuclear fallout as fission-only weapons. Furthermore, high yield thermonuclear explosions (most dangerously ground bursts) have the force to lift radioactive debris upwards past the
tropopause into the
stratosphere, where the calm non-turbulent winds permit the debris to travel great distances from the burst, eventually settling and unpredictably contaminating areas far removed from the target of the explosion.
Other types There are other types of nuclear weapons as well. For example, a
boosted fission weapon is a fission bomb that increases its explosive yield through a small number of fusion reactions, but it is not a fusion bomb. In the boosted bomb, the neutrons produced by the fusion reactions serve primarily to increase the efficiency of the fission bomb. There are two types of boosted fission bomb: internally boosted, in which a deuterium-tritium mixture is injected into the bomb core, and externally boosted, in which concentric shells of lithium-deuteride and depleted uranium are layered on the outside of the fission bomb core. The external method of boosting enabled the
USSR to field the first partially thermonuclear weapons, but it is considered obsolete because it demands a spherical bomb geometry, which was adequate during the 1950s arms race when bomber aircraft were the only available delivery vehicles. The detonation of any nuclear weapon is accompanied by a blast of
neutron radiation. Surrounding a nuclear weapon with suitable materials (such as
cobalt or
gold) creates a weapon known as a
salted bomb. This device can produce exceptionally large quantities of long-lived
radioactive contamination. It has been conjectured that such a device could serve as a "doomsday weapon" because such a large quantity of radioactivities with half-lives of decades, lifted into the stratosphere where winds would distribute it around the globe, would make all life on the planet extinct. In connection with the
Strategic Defense Initiative, research into the
nuclear pumped laser was conducted under the DOD program
Project Excalibur but this did not result in a working weapon. The concept involves the tapping of the energy of an exploding nuclear bomb to power a single-shot laser that is directed at a distant target. During the
Starfish Prime high-altitude nuclear test in 1962, an unexpected effect was produced which is called a
nuclear electromagnetic pulse. This is an intense flash of electromagnetic energy produced by a rain of high-energy electrons which in turn are produced by a nuclear bomb's gamma rays. This flash of energy can permanently destroy or disrupt electronic equipment if insufficiently shielded. It has been proposed to use this effect to disable an enemy's military and civilian infrastructure as an adjunct to other nuclear or conventional military operations. By itself it could as well be useful to terrorists for crippling a nation's economic electronics-based infrastructure. Because the effect is most effectively produced by high altitude nuclear detonations (by military weapons delivered by air, though ground bursts also produce EMP effects over a localized area), it can produce damage to electronics over a wide, even continental, geographical area. Research has been done into the possibility of
pure fusion bombs: nuclear weapons that consist of fusion reactions without requiring a fission bomb to initiate them. Such a device might provide a simpler path to thermonuclear weapons than one that required the development of fission weapons first, and pure fusion weapons would create significantly less nuclear fallout than other thermonuclear weapons because they would not disperse fission products. In 1998, the
United States Department of Energy divulged that the United States had "...made a substantial investment," in the past to develop pure fusion weapons, but that "The U.S. does not have and is not developing a pure fusion weapon," and that "No credible design for a pure fusion weapon resulted from the DOE investment".
Nuclear isomers provide a possible pathway to fissionless fusion bombs. These are naturally occurring
isotopes (
178m2Hf being a prominent example) which exist in an elevated energy state. Mechanisms to release this energy as bursts of gamma radiation (as in the
hafnium controversy) have been proposed as possible triggers for conventional thermonuclear reactions.
Antimatter, which consists of
particles resembling ordinary
matter particles in most of their properties but having opposite
electric charge, has been considered as a trigger mechanism for nuclear weapons. A major obstacle is the difficulty of producing antimatter in large enough quantities, and there is no evidence that it is feasible beyond the military domain. However, the US Air Force funded studies of the physics of antimatter in the
Cold War, and began considering its possible use in weapons, not just as a trigger, but as the explosive itself. A fourth generation nuclear weapon design Most variation in
nuclear weapon design is for the purpose of achieving
different yields for different situations, and in manipulating design elements to attempt to minimize weapon size,
radiation hardness or requirements for special materials, especially fissile fuel or tritium.
Tactical nuclear weapons missile. Capable of firing a 100-kiloton nuclear warhead a distance of 185 km Some nuclear weapons are designed for special purposes; most of these are for non-strategic (decisively war-winning) purposes and are referred to as
tactical nuclear weapons. The
neutron bomb purportedly conceived by
Sam Cohen is a thermonuclear weapon that yields a relatively small explosion but a relatively large amount of neutron
radiation. Such a weapon could, according to tacticians, be used to cause massive biological casualties while leaving inanimate infrastructure mostly intact and creating minimal fallout. Because high energy neutrons are capable of penetrating dense matter, such as tank armor, neutron warheads were procured in the 1980s (though not deployed in Europe) for use as tactical payloads for US Army artillery shells (200 mm
W79 and 155 mm
W82) and
short range missile forces. Soviet authorities announced similar intentions for neutron warhead deployment in Europe; indeed, they claimed to have originally invented the neutron bomb, but their deployment on USSR tactical nuclear forces is unverifiable. A type of nuclear explosive most suitable for use by ground special forces was the
Special Atomic Demolition Munition, or SADM, sometimes popularly known as a
suitcase nuke. This is a nuclear bomb that is man-portable, or at least truck-portable, and though of a relatively small yield (one or two kilotons) is sufficient to destroy important tactical targets such as bridges, dams, tunnels, important military or commercial installations, etc. either behind enemy lines or pre-emptively on friendly territory soon to be overtaken by invading enemy forces. These weapons require plutonium fuel and are particularly "dirty". They also demand especially stringent security precautions in their storage and deployment. Small "tactical" nuclear weapons were deployed for use as antiaircraft weapons. Examples include the USAF
AIR-2 Genie, the
AIM-26 Falcon and US Army
Nike Hercules. Missile interceptors such as the
Sprint and the
Spartan also used small nuclear warheads (optimized to produce neutron or X-ray flux) but were for use against enemy strategic warheads. Other small, or tactical, nuclear weapons were deployed by naval forces for use primarily as
antisubmarine weapons. These included nuclear
depth bombs or nuclear armed torpedoes. Nuclear mines for use on land or at sea are also possibilities. == Weapons delivery ==