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Next Evolutionary Xenon Thruster (NEXT) |
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 NEXT
is one of the projects in the solar electric propulsion technology
area. This project is developing the next generation
ion engine technology and is managed by the NASA Glenn Research
Center. NEXT is a propulsion system that could revolutionize
the way we send science missions deeper into the solar system. The
thruster uses xenon gas and electrical power to drive future
spacecraft. The goal of NEXT program is to develop an ion
thruster capable of supporting several key NASA missions in
the next decade. The thruster system will enable NASA
to reach destinations in our solar system that cannot be reached
by conventional chemical propulsion.
The major feature of NEXT is a thruster that utilized design
knowledge gained from the ion thruster that successfully propelled
the Deep Space 1 to a flyby of asteroid Braille and the comet
Borrelly. NEXT will have a significant increase in power
compared to that of Deep Space 1's ion thruster while increasing
efficiency and system performance characteristics. Advanced
power processing, xenon propellant management and thruster gimbal
technologies are also being developed by the team to complete
the NEXT ion propulsion system
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+ Next
Evolutionary Xenon Thruster (NEXT) Fact Sheet 
+ Next
Evolutionary Xenon Thruster (NEXT) Image Gallery |
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Thruster Technologies |
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 Ion
Thrusters
An ion propulsion system's efficient use of fuel and electrical
power enable modern spacecraft to travel farther, faster, and
cheaper than any other propulsion technology currently available. Ion
thrusters are currently used for stationkeeping on communication
satellites and for main propulsion on deep space probes.
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+ Ion
Propulsion Fact Sheet
+ Ion
Propulsion Research at Glenn |
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 Hall
Thrusters
Hall thrusters use an electric field to accelerate ions, similar
to Ion thrusters. Hall thrusters utilize a radial magnetic
field to generate an azimuthal Hall current. This current
interacts with the radial magnetic field producing a volumetric
(j X B) accelerating force on the plasma. As with gridded
ion thrusters, Hall thrusters can be categorized according to
their respective power sources.
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+ Hall
Thruster Images |
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Solar Sails |
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 Solar
sail propulsion uses the Sun's energy to enable travel through
space, much the way wind pushes sailboats across water. The
technology bounces a stream of solar energy particles called
photons off giant, reflective sails made of lightweight material
40 to 100 times thinner than a piece of writing paper. The
continuous pressure provides sufficient thrust to perform
maneuvers, such as hovering at a point in space and rotating
the space vehicle's plane of orbit, which would require too
much propellant for conventional rocket systems. Because
the Sun provides the necessary propulsive energy, solar sails
also require no onboard propellant, thus reducing payload
mass.
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+ Solar
Sail Image Gallery
+ Solar
Sail Video Gallery
+ Solar
Sail Fact Sheet |
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Advanced Chemical |
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 Chemical
propulsion systems have historically been the primary means
for transportation of payloads in space because they generate
the very large amounts of thrust required to overcome the effect
of Earth's gravity.
Many advanced chemical propellants are being analyzed and tested
to determine their performance and applicability to in-space
propulsion. Chemical rocket systems include solid, cryogenic
liquid, and storable liquid propellants, as well as hybrid and
cold gas rockets. |
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+ Advanced
Chemical Fact Sheet |
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Aerocapture |
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 Aerocapture
is another form of propellantless propulsion. This technology
uses the atmosphere of a destination to achieve a velocity change
necessary to be captured into orbit. |
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+ Aerocapture
Fact Sheet |
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Mission and Systems Analysis |
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 Mission
and systems analysis looks at NASA missions to optimize trajectories,
trip times and payload delivered. These studies help determine
what technologies are needed to achieve the desired Science
objectives. These studies also compare technologies, spacecraft
concepts and designs to most efficiently goals. |
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+ Mission
and Systems Analysis
Fact Sheet |
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Emerging Technologies |
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 NASA's
In-Space Propulsion Technologies Program is developing experiments
to demonstrate tether-based propulsion - which draws power
from the Sun and uses the magnetic field surrounding the Earth
to propel spacecraft without the use of on-board propellant. The
innovative technology could dramatically reduce the cost of
raising the orbits of other spacecraft, including those destined
for deep-space missions.
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+ Click
here to view the In-Space Propulsion Image Gallery |
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The Glenn Research Center's In-Space Propulsion
program is teamed up with the Marshall
Space Flight Center. You can read about their ongoing
In-Space Propulsion efforts here. |
