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The Fission Fragment Nuclear Rocket

The Fission Fragment Nuclear Rocket. Ro bert Sheldon and Rod Clark National Space Science & Technology Center Grassmere Dynamics, LLC NSSTC, Huntsville, Alabama May 13, 2005. Abstract.

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The Fission Fragment Nuclear Rocket

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  1. The Fission Fragment Nuclear Rocket Robert Sheldon and Rod Clark National Space Science & Technology Center Grassmere Dynamics, LLC NSSTC, Huntsville, Alabama May 13, 2005

  2. Abstract • NASA's Human Exploration Initiative has refocussed on high-efficiency, high-thrust rocket propulsion, which has returned attention to the potential of nuclear rockets to provide a unique, high-efficiency, high-thrust propulsion technology. There have been many nuclear rocket designs suggested over the past 50 years, some that were developed here at MSFC, but one that has not received much attention is the extreme high-efficiency "fission fragment" rocket, first proposed to our knowledge by George Chapline. • Possessing a specific impulse ISP > 100,000 sec makes fission fragment propulsion second only to pure light (or anti-matter) for raw efficiency. Previous designs suffered (as do most nuclear rocket designs today) from concerns about keeping the nuclear core cool. A recently studied material called "dusty plasma" (such as Saturn's rings) held the secret to a clever solution to the heating problem, since it provides a density intermediate between gasses and liquids. That is, basic research into space physics has provided new materials that can solve old technological problems resulting in improved space capabilities. Think of it as a debt repaid. We will discuss the principles of operation, a schematic design with a weight/size breakdown of the components, and potential mission profiles for this breakthrough technology, with particular attention to radiation hazards.

  3. The Rocket Equation • Vexhaust= Isp * g [d/dt(MV) = 0] • dV = Vexhaust* log( final mass / initial mass) Material Isp Limitation Solid fuel 200-250 fuel-starved LH2/LOX 350-450 fuel-starved Nuclear Thermal 825-925 efficiency-starved Gas Core Nuclear ~2,000 efficiency-starved MHD < 5,000 energy-starved Ion < 10,000 energy-starved Fission Fragment ~1,500,000 fuel-starved Matter-Antimatter ~10,000,000 fuel-starved Photons 30,000,000-both-starved

  4. Mission to the Gravitational Lens at 550AU • Assume we accelerate half-way, decelerate the other half. (Not the most intelligent approach, but good for comparing technologies) so T_trip = 10 years. • Acceleration = 550AU / (5yr)2 = DV / 5yr=.0027 m/s2 • So DV = 425,000 m/s • Isp (m/s/10)Mrocket / Mpayload 1,500,000 1.029 1,000,000 1.04 500,000 1.09 MORAL of Story: 100,000 1.5  DV ~ V_exhaust 10,000 70.6 450 1.2e41

  5. Mf/Mi Comparison Missions

  6. Ideal Rockets

  7. Semi-Ideal Carnot Efficiency • So whether we have gas or plasma confinement, hotter is better for thermal rocket propulsion, but worse for engineering the confinement. Carnot Effic. = (Tf - Ti)/Tf In order to achieve better than thermal efficiency, we must have a non-thermally accelerated rocket. • This can be done with plasma: • Hot gas is ionized = a plasma, with much higher temperatures possible because of magnetic confinement • Plasma responds to additional forces, electric & magnetic, so it can be accelerated (or heated in 1-dimension), with better than Carnot efficiency. • Non-thermal acceleration = high specific-impulse rocket

  8. How to maximize thrust withnon-ideal rockets • Rocket engines convert thermal energy into kinetic energy by means of a Laval nozzle. Therefore maximizing thermal velocity => high temperature + hydrogen atoms • Chemical: Heat=Propellant (LH2/LOX 350s) =H2O @14kK • Nuclear thermal: Heat+propellant (Nerva 800s) =H2 @2kK • Gas Core Nuclear: High heat+H2 (2000s) = H @50kK • Plasmas with “magnetic walls” & nonthermal acceleration • MHD Engines use magnetic fields to produce a 1-D magneto-fluid nozzle for a gain of about 3X. H~100V ISP~2000 • Ion Engines achievie non-thermal velocities from kV electric field acceleration. Xe at 10kV = 100V/nuc  ISP ~ 10,000 • Fission-Fragment achieves non-thermal Velocity from MV nuclear forces. 2MeV/nucl  ISP ~ 1,500,000

  9. NERVA nuclear thermal circa 1968 • 1.5GW Pu239 reactor cooled with GH2 run for >30 minutes, stopped and restarted without incident at Jackass Flats Nevada test site. One version made 4.08GW for 12 minutes. Held the record almost 30 years for the highest power nuclear reactor on Earth. By comparison, the largest hydropower dam is 12GW. • Mass (dry) = 34 ton • Diameter = 10.5 m • Thrust = 867 kN in vacuum • ISP ~ 820second at 1.2GW • Could place men on Mars by 1980. Cancelled in 1972.

  10. JPL Nuclear-Electric Concept Shielding, Fuel Shield shadow terminator Reactor Power Lines, Coolant tubes Cooling Fins Instruments Ion Thrusters

  11. Fission Fragment Concept • Nuclear-Electric converts nuclear energy to heat, heat to electricity, then electricity to propulsion. The overall efficiency isn’t very high. There’s abundant nuclear power, so low efficiency can be tolerated, but now we also have much heat to remove, which in space can only be done with radiators. • If the fission fragments, which contain 90% of the nuclear energy, can be used directly for propulsion, not only is the nuclear power extracted more efficiently, but much less waste heat is generated.

  12. Fuel Fibers • Fuel coated micron-thick fibers, emit >50% of fission fragments away from fiber. Fragments can be directed out of the system as propellant. Since 90% of energy is in fission fragments, then <55% energy is wasted as heat. Still, fibers get hot. Carbon fiber

  13. Chapline’s Fission Fragment Rocket Magnetic yoke Moderator & magnet coils U235 coated micron-thick spoke-fibers rotating fast Fission-fragment exhaust

  14. Enabled Missions

  15. Heat: The hidden killer • So the problem with space nuclear propulsion is NOT raw power, but how to eliminate waste heat. The more efficiently we can generate thrust, the less waste heat produced. • Can we have our cake and eat it too? Can we have a non-thermal nuclear propulsion minimizing waste heat? • Yes. • Fission fragments can escape < 1 micron U235 dust without heating the grains much. The dust radiates heat very effectively, permitting high power levels.

  16. Schematic • Chapline’s rocket with nuclear fissioning dust.

  17. Cool Dust How do we control, suspend, manipulate such a dust grain(s)? Electrostatically.

  18. Dust Clouds Since we need a total amount of U235 to achieve criticality, how do we collect enough dust grains without heating them? Organization.

  19. What is a dusty plasma? Charged dust + plasma = a “plum pudding” Coulomb crystal, or as Cooper-pairs in BCS theory. Note surface tension & crystalline interaction. Auburn University University of Iowa

  20. Fragment Confinement

  21. More on confinement . • B=0.6 T over 1-meter bore is an awesome energy density = pressure. If we could do that we’d be flying a fusion reactor! Instead, we use a multipole magnet toroid, such that the field strength drops as |R – R0|-N , with N>2, from the wall. • This has a magnetic gradient near the wall, producing a strong mirror force, “insulating” the wall from fission fragments. • By Liouville’s theorem, n/B=constant, so fission fragment density peaks at the wall, low in the dusty plasma center. E.g, one pass through dust. • Because the escaping fragments are positive,  net negative charge in the dust cloud. An ambipolar electric field (=some fraction of MeV) develops at edge as well, confining the fragments. • Proper treatment will require full kinetic simulations.

  22. Toroidal MultipoleMagnetic Trap

  23. Power & Thrust • One mirror can be adjusted for either better reflection (more thrust) or better transmission (electric power).

  24. Concept • Field coils on the end control thrust & power • U235 dust • Moderator is lightweight LiH • Multipole permanent magnets on sides contain fragments

  25. Dust suspension FAQs • Can the dust be suspended while the rocket is accelerating? • Yes, 1g is typically no problem for labs. • Will B-field change the dusty-plasma dynamics? • Yes, but not much.

  26. Terrella Lab ( NSSTC)

  27. Levitated Dusty Plasma w/Magnets

  28. Arc discharge on 3μ SiO2 dust grains charges them negative. Probable charge state on dust is –10,000 e/grain. They are trapped in a positive space-charge region adjacent to ring current. The RC is formed by -400V DC glow discharge on NIB magnet, streaming electrons ionize the air, maintain the RC. Phase-space mismatch of streaming electrons and trapped ions produces the space charge. Highly anisotropic B-field contributes as well. The Dust Trap

  29. Langmuir Probe mapping

  30. Discharging Dust • Won’t negatively charged dust discharge from thermionic emission? And won’t 100nm dust have huge corona discharge current? • Yes, but not as much as one might think.

  31. Discharge vs Dust Size

  32. Photoelectrons vs. size

  33. 550 AUPower, Mass, Acceleration • Acceleration = DV / 5yr= 0.002 m/s • The following values are scaled from Chapline’s Am242*-fueled rocket. We have not done a separate neutronic analysis to get the appropriate volumes for LiH moderator and U235 dust. • 10m x 0.5m radius, with 30cm moderator = 5.4 ton • Co-Sm magnets 2cm thick w/Al windings = 1 ton • Graphite superstructure, radiators, liquid Na = 1.6 ton • Assuming that the payload is 1 ton, then total=9 tons • For a trip to 550AU, the fuel is then .02*9=.18 tons • 350 Megawatt reactor (Nerva was 4.08 GW) ~3mg/s • 0.5Ly Oort Cloud5.6 GW consuming 50mg/s

  34. Nuclear Pollution? • Since radioactive fission fragments are emitted from the rocket, how dangerous is this for the Earth? • From the two missions analyzed, we calculated how long each rocket is withing 10 Re of the earth, and how much fuel is burned during this time. • 550 AU mission = 720 g U235 = 3 moles • 0.5 Lightyr mission=3.7 kg U235 = 15 moles • We modelled the transport through the radiation belts, ionosphere & stratosphere and decay lifetimes of 60 decay products. Short-halflife products decay before reaching the surface of earth. Long-halflife products produce almost no radioactivity. We list radioactive products that make it to Earth from 10 moles U235, both by number and curies.

  35. Modelled Pollutionfrom 10moles U235/P239 • By moles (total radioactivity ~10% of U235) • Rb87 .1 = 1 uCu • Sr90 .2 =1800 Cu • Cs135 .3 = 4 mCu • Cs137 .3 =3600 Cu • Nd144 .05 = .01 nCu • By Curies fast diff slow diffusion • Sr90 1800 1800 • Ru108* 204 110 Cosmic Ray production • Cs137 3600 3600 C14 = 266 Cu/yr • Ce144 1900 770 • Pm147* 2300 930

  36. 550AU Mission Concept 350MW Fission Fragment Rocket

  37. Conclusions • An interstellar probe is still a challenge with a nuclear fission-fragment rocket, but 550AU gravitational lens or 1 Lyr Oort Cloud missions are eminently feasible. • We chose these missions to illustrate how close the fission fragment rocket comes to the stuff of science fiction but using the materials found already at hand. • For example, 550 AU is very promising. At 350MW, the rocket is still 1/10 of Nerva power, and could accomplish an even shorter mission than 10yr (or bigger payload than 1 ton.) Nor is pollution a real problem. • Therefore high DV missions are enabled by a promising high-efficiency nuclear technology.

  38. 4Lightyear Alpha CentauriFound-ET-must-go-now-scenario • Acceleration = DV / 25yr= 0.06 m/s • The following values are scaled from Chapline’s Am242*-fueled rocket. We have not done a separate neutronic analysis to get the appropriate volumes for LiH moderator and U235 dust. • 10m x 0.5m radius, with 30cm moderator = 5.4 ton • Co-Sm magnets 2cm thick w/Al windings = 1 ton • Graphite superstructure, radiators, liquid Na = 1.6 ton • Assuming that the payload is 1 ton, then total=9 tons • For a trip to Alpha Centauri, the fuel is then 24*9=240 tons • 208 Gigawatt reactor (Nerva was 4.08 GW) ~1.8g/s

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