Post by Lord Fer'Kran on Apr 5, 2007 13:56:11 GMT -5
((This is going to be edited!!!!))
A directed-energy weapon is a type of energy weapon that directs energy in a particular direction by a means other than a projectile. It transfers energy to a target for a desired effect. Some of these weapons are real or practicable; some are science fiction. The energy is in various forms:
-Electromagnetic radiation (typically lasers or masers).
-Particles with mass (particle beam weapons).
-Fictional weapons often use some sort of radiation or energetic particle that does not exist in the real world; or where the physical nature of the energy and its means of transmission is not detailed and the visible effects would be impossible in the real world.
Some of these weapons are known as death rays or rayguns and are usually portrayed as projecting energy at a person or object to kill or destroy.
Some lethal directed-energy weapons are under active research and development, but most examples of such weapons appear in science fiction (or non-functional toys and film props).
Contents [hide]
1 Types
2 Lasers
2.1 Tactical considerations
2.2 Problems with lasers
2.2.1 Blooming
2.2.2 Evaporated target material shading the target
2.2.3 High power consumption
2.2.4 The beam being absorbed by obscuration in the air
2.2.5 Lack of indirect fire capabilities
2.3 Electrolaser
2.4 Microwaves
2.5 Pulsed Energy Projectile
2.6 MIRACL
2.7 THEL
2.8 Airborne Laser
2.9 Ultraviolet laser
3 Electric beam in a vacuum
4 Particle beam weapons
5 Plasma weapons
6 Urban legends
6.1 Engine-stopping rays
7 Low-powered lasers
8 History
8.1 Mythology
8.2 Ancient inventors
8.3 Grindell-Matthews
8.4 Robert Watson-Watt
8.5 Tesla
8.6 H.G. Wells
8.7 Nazis
8.8 Star Wars
9 See also
10 External links
11 References
[edit] Types
Broadly defined, directed-energy weapons can be categorised according to the type of energy used (sound, radio, light, particles, plasma, etc) and the intended effects on the target (physical damage, interference with senses and guidance, disorientation, disabling machinery, incapacitating people, etc).
This article restricts itself to weapons designed to cause physical damage with electromagnetic or particle beams. For some other weapons see:-
For weapons to interfere with communications, i.e. jamming, see Electronic countermeasures, Electronic warfare, Radio jamming, and Radar jamming.
For weapons to blind or disorient or interfere with the human eye or electronic sensors see Dazzler (weapon). This is the first verifiable use of directed-energy as a weapon (as opposed to jamming) and dates from World War II.
For particle beams see also Particle beam weapon.
For laser weapons see this article and Laser applications.
For sonic and ultrasonic beam weapons see Sonic weaponry.
For some devices which may be confused with directed-energy weapons see:-
Laser designators are usually infrared lasers used for selective illumination of a target for navigating a laser-guided bomb. They are relatively high-power, often using a solid-state laser, eg Nd:YAG or Eu:YAG.
The term electroshock gun includes two sorts of weapons, but neither of these is a directed-energy weapon, despite its name:
The electric shock prod administers an electric shock on contact. It is not strictly a gun, as it does not cause any effect at a distance.
Guns which fire an electrified projectile.
Occasionally science fiction authors misuse the name "thermic lance" to mean a raygun, but the real thermal lance is not a gun.
For directed-energy weapons in fiction see this article and Raygun.
[edit] Lasers
Lasers are very well known in science fiction as a type of raygun. In the real world, lasers are often used for sighting, ranging and targeting for guns; but the laser beam is not the source of the weapon's firepower.
Laser weapons usually generate brief high-energy pulses. A million joules delivered as a laser pulse is roughly the same energy as 200g of high explosive, and has the same basic effect on a target. The primary damage mechanism is mechanical shear, caused by reaction (like a rocket) when the surface of the target is explosively evaporated.
Most existing weaponized lasers are gas dynamic lasers. Fuel, or a powerful turbine, pushes the lasing media through a circuit or series of orifices. The high-pressures and heating cause the medium to form a plasma and lase. A major difficulty with these systems is preserving the high-precision mirrors and windows of the laser resonating cavity. Most systems use a low-powered "oscillator" laser to generate a coherent wave, and then amplify it. Some experimental laser amplifiers do not use windows or mirrors, but have open orifices, which cannot be destroyed by high energies.
There is research on real lasers as non-lethal weapons. See Dazzler (weapon).
[edit] Tactical considerations
Lasers have three main advantages over conventional weaponry:
Laser beams travel at the speed of light, unlike projectile weapons, so there is no need in terrestrial applications to aim ahead to allow for the target moving while the shot travels as the transit time over such distances is virtually zero.
Some lasers run on electricity which can be cheaply generated, reducing the need for expensive and finite ammunition. However, getting portable electric power sources of sufficient energy capacity is a problem.
Because light has a practically nil ratio (exactly 1 / c) of momentum to energy, lasers produce negligible recoil.
Since lasers can theoretically defeat artillery and missile attacks, any group fielding an effective laser system will gain decisive advantages in ground, air and space combat. Under radar control, lasers have shot artillery shells in flight, including mortar rounds. This suggests that a primary application of lasers might be as part of a defensive system.
The main difficulty with currently practical lasers is the high expense and fragility of their mirrors and mirror-pointing systems.
Some believe that mirrors or other countermeasures can reduce the effectiveness of high energy lasers. This has not been demonstrated. Small defects in mirrors absorb energy, and the defects rapidly expand across the surface. Protective mirroring on the outside of a target could easily be made less effective by incidental damage and by dust and dirt on its surface.
[edit] Problems with lasers
[edit] Blooming
Laser beams begin to cause plasma breakdown in the air at energy densities of around a megajoule per square centimeter. This effect, called "blooming", causes the laser to defocus and to lose energy to the atmosphere. It can be more severe if there is fog, smoke, or dust in the air.
There are several ways to stop or reduce blooming:
The beam can be distributed over a large mirror that focuses the power on the target, to keep energy density in the air too low for blooming to happen. This requires a large, very precise, fragile mirror, mounted somewhat like a searchlight, requiring bulky machinery to slew the mirror to aim the laser.
A phased array. For the usual laser wavelengths this method would need billions of micrometre-size antennas, and no way to make these is known. Phased arrays could theoretically also perform phase-conjugate amplification (see below).
A phase-conjugate laser system. Here, a "finder" or "guide" laser illuminates the target. Any mirror-like ("specular") points on the target reflect light that is sensed by the weapon's primary amplifier. The weapon-power amplifier then amplifies inverted waves in a positive feedback loop, destroying the target with shockwaves as the specular regions evaporate. This avoids the blooming problem because the waves from the target passed through the blooming, and therefore show the most conductive optical path; this automatically corrects for the distortions caused by blooming. Experimental systems using this method usually use special chemicals to form a "phase conjugate mirror". In most systems, the mirror overheats dramatically at weaponized power levels.
A very short pulse that finishes before blooming interferes.
Tailoring the pulse timing, power, and/or wavelength of the laser to induce a shockwave that evacuates the path between the target and the weapon. Without air in the laser's path, blooming will not occur. However, it is difficult to achieve the amount of power needed to blast the air out of the way.
Limiting these weapons to use in vacuum, for example space.
[edit] Evaporated target material shading the target
Another problem with weaponized lasers is that the evaporated material from the surface of the target begins to shade the surface. There are several approaches to this problem:
One is to induce a standing shockwave in the ablation cloud. The shockwave then continues to perform damage.
Another scheme is to scan the target faster than the shockwave.
Another theoretical possibility is to induce plasmic optical mixing at the target. In this scheme, the transparency of the target's ablation cloud to one laser is modulated by another laser, perhaps by tuning the laser to the absorption spectra of the ablation cloud, and inducing population inversion in the cloud. The other laser then induces local lasing in the ablation cloud. The beat frequency that results can induce frequencies that penetrate the ablation cloud.
[edit] High power consumption
One major problem with laser weapons (and directed-energy weapons in general) is their high energy requirements. Existing methods of storing, conducting, transforming, and directing energy are inadequate to produce a convenient hand-held weapon. Existing lasers are inefficient and waste much energy as heat, and thus need much power and bulky cooling equipment to avoid damage by overheating. Simple air cooling could leave an impractical amount of time between when the device can be safely activated again. These problems, which severely limit laser weapon practicality at present, might be offset by:
Cheap high-temperature superconductors to make the weapon more efficient.
A new method of conveniently storing and/or generating large amounts of electricity needed to power the weapon.
If only #2 is available, part of the energy could be used to cool the device.
This problem of storing and/or supplying electrical energy is offset in chemical lasers by using energy released in a suitable chemical reaction instead. Chemical oxygen iodine laser (hydrogen peroxide with iodine) and deuterium fluoride laser (atomic fluorine reacting with deuterium) are two examples of laser types capable of megawatt-range output of a continuous beam. Storing and transporting the chemical fuel presents its own problems with these lasers, and the problems of cooling and overall inefficiency remain.
[edit] The beam being absorbed by obscuration in the air
A laser beam or particle beam passing through air can be absorbed or scattered by rain, snow, dust, fog, smoke, or similar visual obstructions that a bullet would easily brush aside. This effect adds to blooming and worsens the efficiency of the weapon, by wasting more energy to an atmosphere.
[edit] Lack of indirect fire capabilities
Because light is only marginally affected by gravity, and indirect fire requires the use of gravity to strike an enemy from behind cover or not in line-of-sight, lasers cannot be used for indirect fire. Mounting lasers on airborne or space-based platforms may circumvent this limitation simply by getting around or above an obstruction that provides cover or blocks line-of-sight, however.
[edit] Electrolaser
Main article: electrolaser
An electrolaser lets blooming occur, and then sends a powerful electric current down the conducting ionized track of plasma so formed, somewhat like lightning. It functions as a giant high energy long-distance version of the Taser or stun gun.
[edit] Microwaves
Microwave guns powerful enough to injure humans are possible.
Active Denial System is a microwave source, to heat the water in the target's skin and thus cause incapacitating pain. It is being developed by the Air Force Research Laboratory in New Mexico by researchers working with Raytheon for riot-control duty in Iraq. While intended to cause severe pain while leaving no lasting damage, some concern has been voiced as to if the system could cause irreversible damage to the eyes. However, such damage, being non-lethal, would still be preferable to the damage caused by conventional munitions. There has yet to be testing for long-term side effects of exposure to the microwave beam. It can destroy unshielded electronics.
See VMADS (Vehicle-Mounted Active Denial System)
Microwave weapons also have considerable anti-material applications, as they are capable of disabling or destroying unhardened electronics. The components of a microwave weapon - a power source, microwave generator and an antenna - are all readily available, and civilians have successfully built and tested simple devices in this category.
The United States, in cooperation with the Canadian Government, built and successfully tested a microwave gun. It was shown working on a willing soldier (a Canadian) on American and Canadian television.
[edit] Pulsed Energy Projectile
Main article: Pulsed Energy Projectile
Pulsed Energy Projectile or PEP systems emit an infrared laser pulse which creates rapidly expanding plasma when meeting the target. The resulting sound, shock and electromagnetic waves stun the target and cause pain and temporary paralysis. The weapon is under development and is intended to be used as a non-lethal weapon in crowd control.
[edit] MIRACL
Main article: MIRACL
The Mid-Infrared Advanced Chemical Laser is an experimental U.S. Navy deuterium fluoride laser which was tested against an Air Force satellite in 1997.
[edit] THEL
Main article: Tactical High Energy Laser
THEL (Tactical High Energy Laser) is a weaponized deuterium fluoride laser developed in a joint research project of Israel and the U.S. It is designed to shoot down aircraft and missiles. See also National Missile Defense.
[edit] Airborne Laser
Main article: Airborne Laser
The U.S. Air Force's Airborne Laser, or Advanced tactical laser, is a plan to mount a CO2 gas laser or COIL chemical laser on a modified Boeing 747 and use it to shoot down missiles. [1]
[edit] Ultraviolet laser
HSV Technologies of San Diego is developing a laser weapon to paralyze animals (testing for later use on humans) by an electric charge generated by the laser beam. It is described as an ultraviolet laser and not an electrolaser.
[edit] Electric beam in a vacuum
In a vacuum (e.g. in space), an electric discharge can travel a potentially unlimited distance at a velocity slightly slower than the speed of light. This is because there is no significant electric resistance to the flow of electric current in a vacuum. This would make such devices useful to destroy the electrical and electronic parts of satellites and spacecraft. However, in a vacuum the electric current cannot ride a laser beam, and some other means must be used to keep the electron beam on track and to prevent it from dispersing: see particle beam.
[edit] Particle beam weapons
Particle beam weapons can use charged or neutral particles, and can be either endoatmospheric or exoatmospheric. Particle beams as beam weapons are theoretically possible, but practical weapons have not been demonstrated. Certain types of particle beams have the advantage of being self-focusing in the atmosphere.
Blooming is not limited to lasers, but is also a problem in particle beam weapons. Energy that would otherwise be focused on the target spreads out; the beam becomes less effective.
Thermal blooming occurs in both charged and neutral particle beams, and occurs when particles bump into one another under the effects of thermal vibration, or bump into air molecules.
Electrical blooming occurs only in charged particle beams, as ions of like charge repel one another.
[edit] Plasma weapons
Plasma weapons fire a beam or bolt of plasma, which is excited matter consisting of electrons and also protons or nuclei. Examples are:
The MARAUDER (Magnetically Accelerated Ring to Achieve Ultra-high Directed Energy and Radiation). See this link for more details; the antiaircraft potential of such a system is mentioned.
This article explains theories about ball lightning, which may be a type of plasma, which if weaponized could produce beam weapons guided in the same sense as an Anti-tank guided missile
The plasma rifle is a staple of science fiction. There may have been influence from the real plasma torch used to cut metal.
The discontinued Shiva Star project was to be a system for shooting down incoming missiles with projectiles of plasma traveling at speeds from 3,000 kilometers per second to 10,000 kilometers per second.
[edit] Urban legends
[edit] Engine-stopping rays
Engine-stopping rays are a variant that occurs in fiction and myth. Such stories were circulating in Britain around 1938. The tales varied but in general terms told of tourists whose car engine suddenly died and were then approached by a German soldier who told them that they had to wait. The soldier returned a short time later to say that the engine would now work and the tourists drove off. A possible origin of some of these stories arises from the testing of the television transmitter in Feldberg, Germany. Because electrical noise from car engines would interfere with field strength measurements, sentries would stop all traffic in the vicinity for the twenty minutes or so needed for a test. A distorted retelling of the events might give rise to the idea that a transmission killed the engine (Jones 1978).
A shoulder-mounted engine-stopping weapon was a central plot element in episode 303 of BBC espionage drama serial Bugs, in which it was referred to as an "engine killer".
A directed-energy weapon is a type of energy weapon that directs energy in a particular direction by a means other than a projectile. It transfers energy to a target for a desired effect. Some of these weapons are real or practicable; some are science fiction. The energy is in various forms:
-Electromagnetic radiation (typically lasers or masers).
-Particles with mass (particle beam weapons).
-Fictional weapons often use some sort of radiation or energetic particle that does not exist in the real world; or where the physical nature of the energy and its means of transmission is not detailed and the visible effects would be impossible in the real world.
Some of these weapons are known as death rays or rayguns and are usually portrayed as projecting energy at a person or object to kill or destroy.
Some lethal directed-energy weapons are under active research and development, but most examples of such weapons appear in science fiction (or non-functional toys and film props).
Contents [hide]
1 Types
2 Lasers
2.1 Tactical considerations
2.2 Problems with lasers
2.2.1 Blooming
2.2.2 Evaporated target material shading the target
2.2.3 High power consumption
2.2.4 The beam being absorbed by obscuration in the air
2.2.5 Lack of indirect fire capabilities
2.3 Electrolaser
2.4 Microwaves
2.5 Pulsed Energy Projectile
2.6 MIRACL
2.7 THEL
2.8 Airborne Laser
2.9 Ultraviolet laser
3 Electric beam in a vacuum
4 Particle beam weapons
5 Plasma weapons
6 Urban legends
6.1 Engine-stopping rays
7 Low-powered lasers
8 History
8.1 Mythology
8.2 Ancient inventors
8.3 Grindell-Matthews
8.4 Robert Watson-Watt
8.5 Tesla
8.6 H.G. Wells
8.7 Nazis
8.8 Star Wars
9 See also
10 External links
11 References
[edit] Types
Broadly defined, directed-energy weapons can be categorised according to the type of energy used (sound, radio, light, particles, plasma, etc) and the intended effects on the target (physical damage, interference with senses and guidance, disorientation, disabling machinery, incapacitating people, etc).
This article restricts itself to weapons designed to cause physical damage with electromagnetic or particle beams. For some other weapons see:-
For weapons to interfere with communications, i.e. jamming, see Electronic countermeasures, Electronic warfare, Radio jamming, and Radar jamming.
For weapons to blind or disorient or interfere with the human eye or electronic sensors see Dazzler (weapon). This is the first verifiable use of directed-energy as a weapon (as opposed to jamming) and dates from World War II.
For particle beams see also Particle beam weapon.
For laser weapons see this article and Laser applications.
For sonic and ultrasonic beam weapons see Sonic weaponry.
For some devices which may be confused with directed-energy weapons see:-
Laser designators are usually infrared lasers used for selective illumination of a target for navigating a laser-guided bomb. They are relatively high-power, often using a solid-state laser, eg Nd:YAG or Eu:YAG.
The term electroshock gun includes two sorts of weapons, but neither of these is a directed-energy weapon, despite its name:
The electric shock prod administers an electric shock on contact. It is not strictly a gun, as it does not cause any effect at a distance.
Guns which fire an electrified projectile.
Occasionally science fiction authors misuse the name "thermic lance" to mean a raygun, but the real thermal lance is not a gun.
For directed-energy weapons in fiction see this article and Raygun.
[edit] Lasers
Lasers are very well known in science fiction as a type of raygun. In the real world, lasers are often used for sighting, ranging and targeting for guns; but the laser beam is not the source of the weapon's firepower.
Laser weapons usually generate brief high-energy pulses. A million joules delivered as a laser pulse is roughly the same energy as 200g of high explosive, and has the same basic effect on a target. The primary damage mechanism is mechanical shear, caused by reaction (like a rocket) when the surface of the target is explosively evaporated.
Most existing weaponized lasers are gas dynamic lasers. Fuel, or a powerful turbine, pushes the lasing media through a circuit or series of orifices. The high-pressures and heating cause the medium to form a plasma and lase. A major difficulty with these systems is preserving the high-precision mirrors and windows of the laser resonating cavity. Most systems use a low-powered "oscillator" laser to generate a coherent wave, and then amplify it. Some experimental laser amplifiers do not use windows or mirrors, but have open orifices, which cannot be destroyed by high energies.
There is research on real lasers as non-lethal weapons. See Dazzler (weapon).
[edit] Tactical considerations
Lasers have three main advantages over conventional weaponry:
Laser beams travel at the speed of light, unlike projectile weapons, so there is no need in terrestrial applications to aim ahead to allow for the target moving while the shot travels as the transit time over such distances is virtually zero.
Some lasers run on electricity which can be cheaply generated, reducing the need for expensive and finite ammunition. However, getting portable electric power sources of sufficient energy capacity is a problem.
Because light has a practically nil ratio (exactly 1 / c) of momentum to energy, lasers produce negligible recoil.
Since lasers can theoretically defeat artillery and missile attacks, any group fielding an effective laser system will gain decisive advantages in ground, air and space combat. Under radar control, lasers have shot artillery shells in flight, including mortar rounds. This suggests that a primary application of lasers might be as part of a defensive system.
The main difficulty with currently practical lasers is the high expense and fragility of their mirrors and mirror-pointing systems.
Some believe that mirrors or other countermeasures can reduce the effectiveness of high energy lasers. This has not been demonstrated. Small defects in mirrors absorb energy, and the defects rapidly expand across the surface. Protective mirroring on the outside of a target could easily be made less effective by incidental damage and by dust and dirt on its surface.
[edit] Problems with lasers
[edit] Blooming
Laser beams begin to cause plasma breakdown in the air at energy densities of around a megajoule per square centimeter. This effect, called "blooming", causes the laser to defocus and to lose energy to the atmosphere. It can be more severe if there is fog, smoke, or dust in the air.
There are several ways to stop or reduce blooming:
The beam can be distributed over a large mirror that focuses the power on the target, to keep energy density in the air too low for blooming to happen. This requires a large, very precise, fragile mirror, mounted somewhat like a searchlight, requiring bulky machinery to slew the mirror to aim the laser.
A phased array. For the usual laser wavelengths this method would need billions of micrometre-size antennas, and no way to make these is known. Phased arrays could theoretically also perform phase-conjugate amplification (see below).
A phase-conjugate laser system. Here, a "finder" or "guide" laser illuminates the target. Any mirror-like ("specular") points on the target reflect light that is sensed by the weapon's primary amplifier. The weapon-power amplifier then amplifies inverted waves in a positive feedback loop, destroying the target with shockwaves as the specular regions evaporate. This avoids the blooming problem because the waves from the target passed through the blooming, and therefore show the most conductive optical path; this automatically corrects for the distortions caused by blooming. Experimental systems using this method usually use special chemicals to form a "phase conjugate mirror". In most systems, the mirror overheats dramatically at weaponized power levels.
A very short pulse that finishes before blooming interferes.
Tailoring the pulse timing, power, and/or wavelength of the laser to induce a shockwave that evacuates the path between the target and the weapon. Without air in the laser's path, blooming will not occur. However, it is difficult to achieve the amount of power needed to blast the air out of the way.
Limiting these weapons to use in vacuum, for example space.
[edit] Evaporated target material shading the target
Another problem with weaponized lasers is that the evaporated material from the surface of the target begins to shade the surface. There are several approaches to this problem:
One is to induce a standing shockwave in the ablation cloud. The shockwave then continues to perform damage.
Another scheme is to scan the target faster than the shockwave.
Another theoretical possibility is to induce plasmic optical mixing at the target. In this scheme, the transparency of the target's ablation cloud to one laser is modulated by another laser, perhaps by tuning the laser to the absorption spectra of the ablation cloud, and inducing population inversion in the cloud. The other laser then induces local lasing in the ablation cloud. The beat frequency that results can induce frequencies that penetrate the ablation cloud.
[edit] High power consumption
One major problem with laser weapons (and directed-energy weapons in general) is their high energy requirements. Existing methods of storing, conducting, transforming, and directing energy are inadequate to produce a convenient hand-held weapon. Existing lasers are inefficient and waste much energy as heat, and thus need much power and bulky cooling equipment to avoid damage by overheating. Simple air cooling could leave an impractical amount of time between when the device can be safely activated again. These problems, which severely limit laser weapon practicality at present, might be offset by:
Cheap high-temperature superconductors to make the weapon more efficient.
A new method of conveniently storing and/or generating large amounts of electricity needed to power the weapon.
If only #2 is available, part of the energy could be used to cool the device.
This problem of storing and/or supplying electrical energy is offset in chemical lasers by using energy released in a suitable chemical reaction instead. Chemical oxygen iodine laser (hydrogen peroxide with iodine) and deuterium fluoride laser (atomic fluorine reacting with deuterium) are two examples of laser types capable of megawatt-range output of a continuous beam. Storing and transporting the chemical fuel presents its own problems with these lasers, and the problems of cooling and overall inefficiency remain.
[edit] The beam being absorbed by obscuration in the air
A laser beam or particle beam passing through air can be absorbed or scattered by rain, snow, dust, fog, smoke, or similar visual obstructions that a bullet would easily brush aside. This effect adds to blooming and worsens the efficiency of the weapon, by wasting more energy to an atmosphere.
[edit] Lack of indirect fire capabilities
Because light is only marginally affected by gravity, and indirect fire requires the use of gravity to strike an enemy from behind cover or not in line-of-sight, lasers cannot be used for indirect fire. Mounting lasers on airborne or space-based platforms may circumvent this limitation simply by getting around or above an obstruction that provides cover or blocks line-of-sight, however.
[edit] Electrolaser
Main article: electrolaser
An electrolaser lets blooming occur, and then sends a powerful electric current down the conducting ionized track of plasma so formed, somewhat like lightning. It functions as a giant high energy long-distance version of the Taser or stun gun.
[edit] Microwaves
Microwave guns powerful enough to injure humans are possible.
Active Denial System is a microwave source, to heat the water in the target's skin and thus cause incapacitating pain. It is being developed by the Air Force Research Laboratory in New Mexico by researchers working with Raytheon for riot-control duty in Iraq. While intended to cause severe pain while leaving no lasting damage, some concern has been voiced as to if the system could cause irreversible damage to the eyes. However, such damage, being non-lethal, would still be preferable to the damage caused by conventional munitions. There has yet to be testing for long-term side effects of exposure to the microwave beam. It can destroy unshielded electronics.
See VMADS (Vehicle-Mounted Active Denial System)
Microwave weapons also have considerable anti-material applications, as they are capable of disabling or destroying unhardened electronics. The components of a microwave weapon - a power source, microwave generator and an antenna - are all readily available, and civilians have successfully built and tested simple devices in this category.
The United States, in cooperation with the Canadian Government, built and successfully tested a microwave gun. It was shown working on a willing soldier (a Canadian) on American and Canadian television.
[edit] Pulsed Energy Projectile
Main article: Pulsed Energy Projectile
Pulsed Energy Projectile or PEP systems emit an infrared laser pulse which creates rapidly expanding plasma when meeting the target. The resulting sound, shock and electromagnetic waves stun the target and cause pain and temporary paralysis. The weapon is under development and is intended to be used as a non-lethal weapon in crowd control.
[edit] MIRACL
Main article: MIRACL
The Mid-Infrared Advanced Chemical Laser is an experimental U.S. Navy deuterium fluoride laser which was tested against an Air Force satellite in 1997.
[edit] THEL
Main article: Tactical High Energy Laser
THEL (Tactical High Energy Laser) is a weaponized deuterium fluoride laser developed in a joint research project of Israel and the U.S. It is designed to shoot down aircraft and missiles. See also National Missile Defense.
[edit] Airborne Laser
Main article: Airborne Laser
The U.S. Air Force's Airborne Laser, or Advanced tactical laser, is a plan to mount a CO2 gas laser or COIL chemical laser on a modified Boeing 747 and use it to shoot down missiles. [1]
[edit] Ultraviolet laser
HSV Technologies of San Diego is developing a laser weapon to paralyze animals (testing for later use on humans) by an electric charge generated by the laser beam. It is described as an ultraviolet laser and not an electrolaser.
[edit] Electric beam in a vacuum
In a vacuum (e.g. in space), an electric discharge can travel a potentially unlimited distance at a velocity slightly slower than the speed of light. This is because there is no significant electric resistance to the flow of electric current in a vacuum. This would make such devices useful to destroy the electrical and electronic parts of satellites and spacecraft. However, in a vacuum the electric current cannot ride a laser beam, and some other means must be used to keep the electron beam on track and to prevent it from dispersing: see particle beam.
[edit] Particle beam weapons
Particle beam weapons can use charged or neutral particles, and can be either endoatmospheric or exoatmospheric. Particle beams as beam weapons are theoretically possible, but practical weapons have not been demonstrated. Certain types of particle beams have the advantage of being self-focusing in the atmosphere.
Blooming is not limited to lasers, but is also a problem in particle beam weapons. Energy that would otherwise be focused on the target spreads out; the beam becomes less effective.
Thermal blooming occurs in both charged and neutral particle beams, and occurs when particles bump into one another under the effects of thermal vibration, or bump into air molecules.
Electrical blooming occurs only in charged particle beams, as ions of like charge repel one another.
[edit] Plasma weapons
Plasma weapons fire a beam or bolt of plasma, which is excited matter consisting of electrons and also protons or nuclei. Examples are:
The MARAUDER (Magnetically Accelerated Ring to Achieve Ultra-high Directed Energy and Radiation). See this link for more details; the antiaircraft potential of such a system is mentioned.
This article explains theories about ball lightning, which may be a type of plasma, which if weaponized could produce beam weapons guided in the same sense as an Anti-tank guided missile
The plasma rifle is a staple of science fiction. There may have been influence from the real plasma torch used to cut metal.
The discontinued Shiva Star project was to be a system for shooting down incoming missiles with projectiles of plasma traveling at speeds from 3,000 kilometers per second to 10,000 kilometers per second.
[edit] Urban legends
[edit] Engine-stopping rays
Engine-stopping rays are a variant that occurs in fiction and myth. Such stories were circulating in Britain around 1938. The tales varied but in general terms told of tourists whose car engine suddenly died and were then approached by a German soldier who told them that they had to wait. The soldier returned a short time later to say that the engine would now work and the tourists drove off. A possible origin of some of these stories arises from the testing of the television transmitter in Feldberg, Germany. Because electrical noise from car engines would interfere with field strength measurements, sentries would stop all traffic in the vicinity for the twenty minutes or so needed for a test. A distorted retelling of the events might give rise to the idea that a transmission killed the engine (Jones 1978).
A shoulder-mounted engine-stopping weapon was a central plot element in episode 303 of BBC espionage drama serial Bugs, in which it was referred to as an "engine killer".