Fission-fragment rocket: Difference between revisions
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[[Image:Fission fragment propulsion.svg|250px|thumb|right|Fission-fragment propulsion concept<br/>'''a''' fissionable filaments, '''b''' revolving disks,<br/>'''c''' reactor core, '''d''' fragments exhaust]] |
[[Image:Fission fragment propulsion.svg|250px|thumb|right|Fission-fragment propulsion concept<br/>'''a''' fissionable filaments, '''b''' revolving disks,<br/>'''c''' reactor core, '''d''' fragments exhaust]] |
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The '''fission-fragment rocket''' is a [[rocket engine]] design that directly harnesses hot nuclear [[fission product]]s for [[thrust]], as opposed to using a separate fluid as [[working mass]]. The design can, in theory, produce very high [[specific impulse]]s while still being well within the abilities of current technologies |
The '''fission-fragment rocket''' is a [[rocket engine]] design that directly harnesses hot nuclear [[fission product]]s for [[thrust]], as opposed to using a separate fluid as [[working mass]]. The design can, in theory, produce very high [[specific impulse]]s while still being well within the abilities of current technologies. |
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== Design considerations == |
== Design considerations == |
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In traditional [[nuclear thermal rocket]] and related designs |
In traditional [[nuclear thermal rocket]] and related designs, the nuclear energy is generated in some form of "reactor" and used to heat a working fluid to generate thrust. This limits the designs to temperatures that allow the reactor to remain "whole", although clever design can increase this critical temperature into the tens of thousands of degrees. A rocket engine's efficiency is strongly related to the temperature of the exhausted working fluid, and in the case of the most advanced gas-core engines, it corresponds to a specific impulse of about 7000 s (69 kN·s/kg). |
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The temperature of a conventional reactor design is actually the average temperature of the fuel |
The temperature of a conventional reactor design is actually the average temperature of the fuel, the vast majority of which is not actually reacting at any given instance. In fact the atoms undergoing fission are at a temperature of millions of degrees, which is then spread out into the surrounding fuel, resulting in an overall temperature of a few thousand. In the fission-fragment design, it is the individual atoms that actually undergo fission that are used to provide thrust, by extracting them from the rest of the fuel as quickly as possible before their energy is spread out into the surrounding fuel mass. |
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This is easier to achieve than it might sound. By physically arranging the fuel such that the outermost layers of a fuel bundle will be most likely to undergo fission, the high-temperature atoms, the fragments of a nuclear reaction, can "boil" off the surface. Since they will be [[ionized]] due to the high temperatures of the reaction, they can then be handled [[magnet|magnetically]] and channeled to produce thrust. Numerous technological challenges still remain, however. |
This is easier to achieve than it might sound. By physically arranging the fuel such that the outermost layers of a fuel bundle will be most likely to undergo fission, the high-temperature atoms, the fragments of a nuclear reaction, can "boil" off the surface. Since they will be [[ionized]] due to the high temperatures of the reaction, they can then be handled [[magnet|magnetically]] and channeled to produce thrust. Numerous technological challenges still remain, however. |
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== Research == |
== Research == |
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One such design was worked on to some degree by the [[Idaho National Engineering Laboratory]] and [[Lawrence Livermore National Laboratory]]. In their design the fuel was placed into a number of very thin [[carbon]] bundles, each one normally sub-[[Critical mass (nuclear)|critical]]. Bundles were collected and arranged like spokes on a wheel, and several such wheels were stacked on a common shaft to produce a single large cylinder. The entire cylinder was rotated so that some bundles were always in a reactor core where additional surrounding fuel made the bundles go critical. The fission fragments at the surface of the bundles would break free and be channeled for thrust, while the lower-temperature un-reacted fuel would eventually rotate out of the core to cool. The system thus automatically "selected" only the most energetic fuel to become the working mass |
One such design was worked on to some degree by the [[Idaho National Engineering Laboratory]] and [[Lawrence Livermore National Laboratory]]. In their design the fuel was placed into a number of very thin [[carbon]] bundles, each one normally sub-[[Critical mass (nuclear)|critical]]. Bundles were collected and arranged like spokes on a wheel, and several such wheels were stacked on a common shaft to produce a single large cylinder. The entire cylinder was rotated so that some bundles were always in a reactor core where additional surrounding fuel made the bundles go critical. The fission fragments at the surface of the bundles would break free and be channeled for thrust, while the lower-temperature un-reacted fuel would eventually rotate out of the core to cool. The system thus automatically "selected" only the most energetic fuel to become the working mass. |
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[[Image:Dusty plasma bed reactor.svg|400px|right|thumb|Dusty plasma bed reactor<br/> |
[[Image:Dusty plasma bed reactor.svg|400px|right|thumb|Dusty plasma bed reactor<br/> |
Revision as of 19:21, 3 February 2010
The fission-fragment rocket is a rocket engine design that directly harnesses hot nuclear fission products for thrust, as opposed to using a separate fluid as working mass. The design can, in theory, produce very high specific impulses while still being well within the abilities of current technologies.
Design considerations
In traditional nuclear thermal rocket and related designs, the nuclear energy is generated in some form of "reactor" and used to heat a working fluid to generate thrust. This limits the designs to temperatures that allow the reactor to remain "whole", although clever design can increase this critical temperature into the tens of thousands of degrees. A rocket engine's efficiency is strongly related to the temperature of the exhausted working fluid, and in the case of the most advanced gas-core engines, it corresponds to a specific impulse of about 7000 s (69 kN·s/kg).
The temperature of a conventional reactor design is actually the average temperature of the fuel, the vast majority of which is not actually reacting at any given instance. In fact the atoms undergoing fission are at a temperature of millions of degrees, which is then spread out into the surrounding fuel, resulting in an overall temperature of a few thousand. In the fission-fragment design, it is the individual atoms that actually undergo fission that are used to provide thrust, by extracting them from the rest of the fuel as quickly as possible before their energy is spread out into the surrounding fuel mass.
This is easier to achieve than it might sound. By physically arranging the fuel such that the outermost layers of a fuel bundle will be most likely to undergo fission, the high-temperature atoms, the fragments of a nuclear reaction, can "boil" off the surface. Since they will be ionized due to the high temperatures of the reaction, they can then be handled magnetically and channeled to produce thrust. Numerous technological challenges still remain, however.
Research
One such design was worked on to some degree by the Idaho National Engineering Laboratory and Lawrence Livermore National Laboratory. In their design the fuel was placed into a number of very thin carbon bundles, each one normally sub-critical. Bundles were collected and arranged like spokes on a wheel, and several such wheels were stacked on a common shaft to produce a single large cylinder. The entire cylinder was rotated so that some bundles were always in a reactor core where additional surrounding fuel made the bundles go critical. The fission fragments at the surface of the bundles would break free and be channeled for thrust, while the lower-temperature un-reacted fuel would eventually rotate out of the core to cool. The system thus automatically "selected" only the most energetic fuel to become the working mass.
The efficiency of the system is surprising; specific impulses of greater than 100,000 are possible using existing materials. This is high performance, although not that which the technically daunting antimatter rocket could achieve, and the weight of the reactor core and other elements would make the overall performance of the fission-fragment system lower. Nonetheless, the system provides the sort of performance levels that would make an interstellar precursor mission possible.
A newer design proposal by Rodney A. Clark and Robert B. Sheldon theoretically increases efficiency and decreases complexity of a fission fragment rocket at the same time over the bundle proposal.[1] In their design, nanoparticles of fissionable fuel (or even fuel that will naturally radioactively decay) are kept in a vacuum chamber subject to an axial magnetic field (acting as a magnetic mirror) and an external electric field. As the nanoparticles ionize as fission occurs, the dust becomes suspended within the chamber. The incredibly high surface area of the particles makes radiative cooling simple. The axial magnetic field is too weak to affect the motions of the dust particles but strong enough to channel the fragments into a beam which can be decelerated for power, allowed to be emitted for thrust, or a combination of the two. With exhaust velocities of 3 % - 5 % the speed of light and efficiencies up to 90 %, the rocket should be able to achieve over 1,000,000 sec Isp.
See also
References
- ^ Clark, R.; Sheldon, R. Dusty Plasma Based Fission Fragment Nuclear Reactor American Institute of Aeronautics and Astronautics. 15 April 2007.