Plasma propulsion engine

An early plasma propulsion engine from the Lewis Research Center in Cleveland, Ohio in 1961

A plasma thruster during test firing

Artist rendition of VASIMR plasma engine

A plasma propulsion engine is a type of electric propulsion that generates thrust from a quasi-neutral plasma. This is in contrast to ion thruster engines, which generates thrust through extracting an ion current from plasma source, which is then accelerated to high velocities using grids/anodes. These exist in many forms (see electric propulsion). Plasma thrusters do not typically use high voltage grids or anodes/ cathodes to accelerate the charged particles in the plasma, but rather uses currents and potentials which are generated internally in the plasma to accelerate the plasma ions. While this results in a lower exhaust velocities by virtue of the lack of high accelerating voltages, this type of thruster has a number of interesting advantages. The lack of high voltage grids of anodes removes a possible limiting element as a result of grid ion erosion. The plasma exhaust is 'quasi- neutral', which means that ion and electrons exist in equal number, which allows simply ion- electron recombination in the exhaust to neutralise the exhaust plume, removing the need for an electron gun (hollow cathode). This type of thruster often generates the source plasma using radio frequency of microwave energy, using an external antenna. This fact, combined with the absence of hollow cathodes (which are very sensitive to all but the few noble gases) allows the intriguing possibility of being able to use this type of thruster on a huge range of propellants, from argon, to carbon dioxide, air mixtures to astronaut urine. ^[1]

Plasma engines are better suited for long-distance interplanetary space travel missions.^[2]

In recent years, many agencies have developed several forms of plasma-fueled engines, including the European Space Agency, Iranian Space Agency and Australian National University, which have co-developed a more advanced type described as a double layer thruster.^[3]^[4] However, this form of plasma engine is only one of many types.

Engine types

Helicon double layer thrusters

Main article: Helicon double-layer thruster

Helicon double-layer thrusters use radio waves to create a plasma and a magnetic nozzle to focus and accelerate the plasma away from the rocket engine. A Mini-Helicon Plasma Thruster, ideal for space maneuvers, runs off of nitrogen, and the fuel has an exhaust velocity (specific impulse) 10 times that of chemical rockets.^[5]^[6]

Magnetoplasmadynamic thrusters

Main article: Magnetoplasmadynamic thruster

Magnetoplasmadynamic thrusters (MPD) use the Lorentz force (a force resulting from the interaction between a magnetic field and an electric current) to generate thrust - The electric charge flowing through the plasma in the presence of a magnetic field causing the plasma to accelerate due to the generated magnetic force. The Lorentz force is also crucial to the operation of most pulsed plasma thruster

Pulsed inductive thrusters

Main article: Pulsed inductive thruster

Pulsed inductive thrusters (PIT) also use the Lorentz force to generate thrust, but unlike the magnetoplasmadynamic thruster, they do not use any electrode, preventing their erosion. Ionization and electric currents in the plasma are induced by a rapidly varying magnetic field.

Electrodeless plasma thrusters

Main article: Electrodeless plasma thruster

Electrodeless plasma thrusters use the ponderomotive force which acts on any plasma or charged particle when under the influence of a strong electromagnetic energy density gradient to accelerate both electrons and ions of the plasma in the same direction, thereby able to operate without neutralizer.

SPT

Hall effect thrusters

Main article: Hall effect thruster

Hall effect thrusters (also called stationary plasma thrusters SPT) combine a strong localized static magnetic field perpendicular to the electric field created between an upstream anode and a downstream cathode called neutralizer, to create a "virtual cathode" (area of high electron density) at the exit of the device. This virtual cathode then attracts the ions formed inside the thruster closer to the anode. Finally the accelerated ion beam is neutralized by some of the electrons emitted by the neutralizer. Serial production of Hall effect thruster started in Soviet Union in the 1970s. One of the early variants, SPT-100 is now produced under license by European Snecma Moteurs under the name PPS-1350. Similarly BPT-4000 and PPS-5000 are closely related to SPT-140. SPT-290 has a thrust of 1.5N, 5-30 kW power and specific impulse 30 km/s, efficiency 65% and weight 23 kg.

VASIMR

Main article: Variable Specific Impulse Magnetoplasma Rocket

VASIMR, short for Variable Specific Impulse Magnetoplasma Rocket, uses radio waves to ionize a propellant into a plasma. Then, a magnetic field accelerates the plasma from the rocket engine, generating thrust. The VASIMR is being developed by Ad Astra Rocket Company, headquartered in Houston, TX. A Nova Scotia, Canada-based company Nautel, is producing the 200 kW RF generators required to ionize the propellant. Some component tests and "Plasma Shoot" experiments are performed in a Liberia, Costa Rica laboratory. This project is led by former NASA astronaut Dr. Franklin Chang-Díaz (CRC-USA).

The Costa Rican Aerospace Alliance has announced development of an exterior support for the VASIMR to be fitted outside the International Space Station. This phase of the plan to test the VASIMR in space is expected to be conducted in 2016. A projected 200 megawatt VASIMR engine could reduce the time to travel from Earth to Jupiter or Saturn from six years to fourteen months, and from Earth to Mars from 6 months to 39 days.^[7]

References

↑ "Australian National University develops helicon plasma thruster". Dvice. January 2010. Retrieved 8 June 2012.
↑ "N.S. company helps build plasma rocket". cbcnews. January 2010. Retrieved 24 July 2012.
↑ "Plasma engine passes initial test". BBC News. 14 December 2005.
↑ PRL - Helicon Double Layer Thruster Development
↑ Elizabeth A. Thomson (2009). "MIT rocket aims for cheaper nudges in space". MIT. Retrieved 24 July 2012.
↑ MIT (2009). "Scientists develop new plasma thruster". UPI. Retrieved 24 July 2012.
↑ Zyga, Lisa (2009). Plasma Rocket Could Travel to Mars in 39 Days, http://phys.org/news174031552.html Physorg

External links

Plasma Propulsion in Space - A.I.P. October, 2000
Mini-Helicon Plasma Thruster

Spacecraft propulsion

Chemical
rockets

State	Liquid-fuel rocket Solid-fuel rocket Hybrid rocket

Propellants	Liquid propellants Cryogenic Hypergolic Monopropellant Bipropellant Staged combustion cycle Expander cycle Gas-generator cycle Tap-off cycle Pressure-fed engine Pump-fed engine Electric pump-fed engine Tripropellant

Electrical
thrusters

Electrostatic	Colloid thruster Ion thruster Gridded Hall effect thruster Field-emission electric propulsion Ionocraft

Electromagnetic	Pulsed inductive thruster Magnetoplasmadynamic thruster Electrodeless plasma thruster VASIMR

Electrothermal	Pulsed plasma thruster Helicon Double Layer Thruster Arcjet rocket Resistojet rocket

Other	MagBeam High Power Electric Propulsion Mass driver Resonant cavity thruster

Nuclear
propulsion

Closed system	Nuclear electric rocket Nuclear thermal rocket Radioisotope Salt-water Gas core "Lightbulb"

Open system	Nuclear pulse propulsion Antimatter-catalyzed Pulsed nuclear thermal rocket‎ Fusion rocket Bussard ramjet Fission-fragment rocket Fission sail Nuclear photonic rocket

Other

Spaceflight portal

Emerging technologies

Fields

Displays

Next generation	FED FLCD iMoD Laser LPD OLED OLET QD-LED SED TPD TDEL TMOS

Screenless	Bionic contact lens Head-mounted display Head-up display Optical head-mounted display Virtual retinal display

Other	Autostereoscopy Flexible display Holographic display Computer-generated holography Multi-primary color display Ultra HD Volumetric display

Electronics

Energy

Production	Airborne wind turbine Artificial photosynthesis Biofuels Carbon-neutral fuel Concentrated solar power Fusion power Home fuel cell Hydrogen economy Methanol economy Molten salt reactor Nantenna Photovoltaic pavement Space-based solar power Vortex engine

Storage	Beltway battery Compressed air energy storage Flywheel energy storage Grid energy storage Lithium–air battery Molten salt battery Nanowire battery Research in lithium-ion batteries Silicon–air battery Thermal energy storage Ultracapacitor

Other	Smart grid Wireless power

IT and
communications

Manufacturing

Launch	Fusion rocket Non-rocket spacelaunch Mass driver Orbital ring Space elevator Space fountain Space tether Reusable launch system

Propulsion	Beam-powered propulsion Ion thruster Laser propulsion Plasma propulsion engine Helicon thruster VASIMR Project Orion Nuclear pulse propulsion Solar sail

Other	Interstellar travel Propellant depot

Transport

Aerial	Adaptive compliant wing Aeroscraft Backpack helicopter Delivery drone Flying car High-altitude platform Jet pack Pulse detonation engine Scramjet Spaceplane Skylon Supersonic transport

Land	Airless tire Tweel Alternative fuel vehicle Hydrogen vehicle Driverless car Ground effect train Maglev train Personal rapid transit Vactrain ET3 Global Alliance Hyperloop Vehicular communication systems

Pipeline	Pneumatic transport Automated vacuum collection Foodtubes