Nuclear pulse propulsion

An artist's conception of the Project Orion "basic" spacecraft, powered by nuclear pulse propulsion.

Nuclear pulse propulsion or external pulsed plasma propulsion, is a hypothetical method of spacecraft propulsion that uses nuclear explosions for thrust.[1] It was first developed as Project Orion by DARPA, after a suggestion by Stanislaw Ulam in 1947.[2] Newer designs using inertial confinement fusion have been the baseline for most post-Orion designs, including Project Daedalus and Project Longshot.

Project Orion

A nuclear pulse propulsion unit. The explosive charge ablatively vaporizes the propellant, propelling it away from the charge, and simultaneously creating a plasma out of the propellant. The propellant then goes on to impact the pusher plate at the bottom of the Orion spacecraft, imparting a pulse of 'pushing' energy.

Project Orion was the first serious attempt to design a nuclear pulse rocket. The design effort was carried out at General Atomics in the late 1950s and early 1960s. The idea of Orion was to react small directional nuclear explosives utilizing a variant of the Teller-Ulam two-stage bomb design against a large steel pusher plate attached to the spacecraft with shock absorbers. Efficient directional explosives maximized the momentum transfer, leading to specific impulses in the range of 6,000 seconds, or about thirteen times that of the Space Shuttle Main Engine. With refinements a theoretical maximum of 100,000 seconds (1 MN·s/kg) might be possible. Thrusts were in the millions of tons, allowing spacecraft larger than 8 × 106 tons to be built with 1958 materials.[3]

The reference design was to be constructed of steel using submarine-style construction with a crew of more than 200 and a vehicle takeoff weight of several thousand tons. This low-tech single-stage reference design would reach Mars and back in four weeks from the Earth's surface (compared to 12 months for NASA's current chemically powered reference mission). The same craft could visit Saturn's moons in a seven-month mission (compared to chemically powered missions of about nine years).

A number of engineering problems were found and solved over the course of the project, notably related to crew shielding and pusher-plate lifetime. The system appeared to be entirely workable when the project was shut down in 1965, the main reason being given that the Partial Test Ban Treaty made it illegal (however, before the treaty, the US and Soviet Union had already detonated at least nine nuclear bombs, including thermonuclear bombs, in space, i.e., at altitudes over 100 km: see high altitude nuclear explosions). There were also ethical issues with launching such a vehicle within the Earth's magnetosphere: calculations using the now disputed linear no-threshold model of radiation damage showed that the fallout from each takeoff would kill between 1 and 10 people.[4] In a threshold model, such extremely low levels of thinly distributed radiation would have no associated ill-effects, while under hormesis models, such tiny doses would be negligibly beneficial.[5][6] It should be noted that with the possible use of less efficient clean nuclear bombs for achieving orbit and then more efficient higher yield dirty bombs for travel would bring down the amount of fallout caused from an Earth-based launch by a significant factor.

One useful mission for this near-term technology would be to deflect an asteroid that could collide with the Earth, depicted dramatically in the 1998 film Deep Impact. The extremely high performance would permit even a late launch to succeed, and the vehicle could effectively transfer a large amount of kinetic energy to the asteroid by simple impact,[7] and in the event of an imminent asteroid impact a few predicted deaths from fallout would probably not be considered prohibitive. Also, an automated mission would eliminate the most problematic issues of the design: the shock absorbers.

Orion is one of very few interstellar space drives that could theoretically be constructed with available technology, as discussed in a 1968 paper, Interstellar Transport by Freeman Dyson.

Project Daedalus

Project Daedalus was a study conducted between 1973 and 1978 by the British Interplanetary Society (BIS) to design a plausible interstellar unmanned spacecraft that could reach a nearby star within one human scientist's working lifetime or about 50 years. A dozen scientists and engineers led by Alan Bond worked on the project. At the time fusion research appeared to be making great strides, and in particular, inertial confinement fusion (ICF) appeared to be adaptable as a rocket engine.

ICF uses small pellets of fusion fuel, typically lithium deuteride (6Li2H) with a small deuterium/tritium trigger at the center. The pellets are thrown into a reaction chamber where they are hit on all sides by lasers or another form of beamed energy. The heat generated by the beams explosively compresses the pellet, to the point where fusion takes place. The result is a hot plasma, and a very small "explosion" compared to the minimum size bomb that would be required to instead create the necessary amount of fission.

For Daedalus, this process was run within a large electromagnet which formed the rocket engine. After the reaction, ignited by electron beams in this case, the magnet funnelled the hot gas to the rear for thrust. Some of the energy was diverted to run the ship's systems and engine. In order to make the system safe and energy efficient, Daedalus was to be powered by a helium-3 fuel that would have had to be collected from Jupiter.

Medusa

Conceptual diagram of a Medusa propulsion spacecraft, showing: (A) the payload capsule, (B) the winch mechanism, (C) the optional main tether cable, (D) riser tethers, and (E) the parachute mechanism.
Operating sequence of the Medusa propulsion system. This diagram shows the operating sequence of a Medusa propulsion spacecraft (1) Starting at moment of explosive-pulse unit firing, (2) As the explosive pulse reaches the parachute canopy, (3) Pushes the canopy, accelerating it away from the explosion as the spacecraft plays out the main tether with the winch, generating electricity as it extends, and accelerating the spacecraft, (4) And finally winches the spacecraft forward to the canopy and uses excess electricity for other purposes.

The Medusa design is a type of nuclear pulse propulsion which has more in common with solar sails than with conventional rockets. It was created by Johndale Solem[8] in the 1990s and published in the Journal of the British Interplanetary Society (JBIS).[9]

A Medusa spacecraft would deploy a large “spinnaker” sail ahead of it, attached by separate independent cables, and then launch nuclear explosives forward to detonate between itself and its sail. The sail would be accelerated by the plasma and photonic impulse, running out the tethers as when a fish flees the fisherman, and generating electricity at the “reel”. The spacecraft would then use some of the generated electricity to reel itself up towards the sail, constantly smoothly accelerating as it goes.[10]

In the original design, multiple tethers connected to multiple motor generators. The advantage over the single tether is to increase the distance between the explosion and the tethers, thus reducing damage to the tethers.

For heavy payloads, performance could be improved by taking advantage of lunar materials, for example, wrapping the explosive with lunar rock or water, likely stored previously at a stable Earth-Moon Lagrange point to be subsequently acquired by the Medusa spacecraft.[11]

Medusa performs better than the classical Orion design because its sail intercepts more of the explosive impulse, its shock-absorber stroke is much longer, and all its major structures are in tension and hence can be quite lightweight. Medusa-type ships would be capable of a specific impulse between 50,000 and 100,000 seconds (500 to 1000 kN·s/kg).

Medusa is widely known to the public in the BBC documentary film To Mars By A-Bomb: The Secret History of Project Orion.[12] A short film shows an artist’s conception of how the Medusa spacecraft works “by throwing bombs into a sail that's ahead of it!”[13]

Project Longshot

Project Longshot was a NASA-sponsored research project carried out in conjunction with the US Naval Academy in the late 1980s.[14] Longshot was in some ways a development of the basic Daedalus concept, in that it used magnetically funneled ICF as a rocket. The key difference was that they felt that the reaction could not power both the rocket and the systems, and instead included a 300 kW conventional nuclear reactor for running the ship. The added weight of the reactor reduced performance somewhat, but even using LiD fuel it would be able to reach Alpha Centauri, the closest solar system to our own, in 100 years (approx. velocity of 13,411 km/s, at a distance of 4.5 light years - equivalent to 4.5% of light speed).

Antimatter-catalyzed nuclear pulse propulsion

In the mid-1990s research at the Pennsylvania State University led to the concept of using antimatter to catalyze nuclear reactions. In short, antiprotons would react inside the nucleus of uranium, causing a release of energy that breaks the nucleus apart as in conventional nuclear reactions. Even a small number of such reactions can start the chain reaction that would otherwise require a much larger volume of fuel to sustain. Whereas the "normal" critical mass for plutonium is about 11.8 kilograms (for a sphere at standard density), with antimatter catalyzed reactions this could be well under one gram.

Several rocket designs using this reaction were proposed, ones using all-fission for interplanetary missions, and others using fission-fusion (effectively a very small version of Orion's bombs) for interstellar ones.

MSNW magneto-inertial fusion driven rocket

MSNW Magneto-Inertial Fusion Driven Rocket

Concept graphic of a Fusion Driven Rocket powered Spacecraft arriving at Mars
Designer MSNW LLC
Application Interplanetary
Status Theoretical
Performance
Specific impulse 1,606 s to 5,722 s (depending on fusion gain)
Burn time 1 day to 90 days (10 days optimal with Gain of 40)
References
References [15]
Notes

Fuel: Deuterium-Tritium Cryogenic Pellet

Propellent: Lithium or Aluminum

Power Requirements: 100 kW to 1,000 kW

NASA funded MSNW LLC and the University of Washington in 2011 to study and develop a fusion rocket through the NASA Innovative Advanced Concepts NIAC Program.[16]

The rocket uses a form of magneto-inertial fusion to produce a direct thrust fusion rocket. Powerful magnetic fields cause large metal rings (likely made of lithium, where a set for one pulse has a total mass of 365 grams) to collapse around the deuterium-tritium plasma, compressing it to a fusion state. Energy from these fusion reactions heats and ionizes the shell of metal formed by the crushed rings. The hot, ionized metal is shot out of a magnetic rocket nozzle at a high speed (up to 30 km/s). Repeating this process roughly every minute would propel the spacecraft.[17] The fusion reaction is not self-sustaining and requires electrical energy to induce fusion. With electrical requirements estimated to be between 100 kW to 1,000 kW (300 kW average), spacecraft designs incorporate solar panels to produce the electrical energy needed for the fusion engine.[15]

This approach uses Foil Liner Compression to create a fusion reaction of the proper energy scale to be used for space propulsion. The proof of concept experiment in Redmond, Washington, will use aluminum liners for compression. However, the actual rocket design will run with lithium liners.[18][19]

The performance characteristics of the engine are highly dependent on the Fusion energy gain factor achieved by the reactor. Gains are expected to be between a factor of 20 and 200, with an estimated average of 40. With higher fusions gains comes higher exhaust velocity, higher specific impulse and lower electrical power requirements. The table below summarizes different performance characteristics for a theoretical 90-day Mars transfer at gains of 20, 40 and 200.

FDR parameters for 90 Mars transfer burn[15]
Total Gain Gain of 20 Gain of 40 Gain of 200
Liner Mass (kg) 0.365 0.365 0.365
Specific Impulse (s) 1,606 2,435 5,722
Mass Fraction 0.33 0.47 0.68
Specific Mass (kg/kW) 0.8 0.53 0.23
Mass Propellant (kg) 110,000 59,000 20,000
Mass Initial (kg) 184,000 130,000 90,000
Electrical Power Required (kW) 1,019 546 188

As of April 2013, MSNW has demonstrated subcomponents of the systems: heating deuterium plasma up to fusion temperatures and have concentrated the magnetic fields needed to create fusion. They plan to put the two technologies together for a test before the end of 2013.[15][20]

They will later be scaled up in power and plan to add the necessary fusion fuel (deuterium) by the end (Sept 2014) of the NIAC Study.[21]

See also

References

  1. Bonometti, Joseph A.; P. Jeff Morton. "External Pulsed Plasma Propulsion (EPPP) Analysis Maturation" (PDF). Nasa Marshall Space Flight Center. Retrieved December 24, 2008.
  2. "History of Project Orion". The Story of Orion. 2008–2009.
  3. General Dynamics Corp. (January 1964). "Nuclear Pulse Vehicle Study Condensed Summary Report (General Dynamics Corp.)" (PDF). U.S. Department of Commerce National Technical Information Service. Retrieved December 24, 2008.
  4. Dyson, George. Project Orion – The Atomic Spaceship 1957-1965. Penguin. ISBN 0-14-027732-3
  5. Heyes; et al. (1 October 2006). "Authors' reply". British Journal of Radiology. The British Medical Journal. 79 (946): 855–857. doi:10.1259/bjr/52126615. Retrieved 27 March 2008.
  6. Aurengo; et al. (30 March 2005). "Dose-effect relationships and estimation of the carcinogenic effects of low doses of ionizing radiation" (PDF). Académie des Sciences & Académie nationale de Médecine. Retrieved 27 March 2008.
  7. Solem, J. C. (1994). "Nuclear explosive propelled interceptor for deflecting objects on collision course with Earth". Journal of Spacecraft and Rockets. 31 (4): 707–709.
  8. Gilster, Paul (2004). Centauri Dreams: Imagining and Planning Interstellar Exploration. Copernicus Books, Atlanta Book Company. p. 86. ISBN 038700436X. Retrieved 2015-10-26.
  9. Solem, J. C. (January 1993). "Medusa: Nuclear explosive propulsion for interplanetary travel". Journal of the British Interplanetary Society. 46 (1): 21–26. Bibcode:1993JBIS...46R..21S. ISSN 0007-084X.
  10. Solem, J. C. (June 1994). "Nuclear explosive propulsion for interplanetary travel: Extension of the Medusa concept for higher specific impulse". Journal of the British Interplanetary Society. 47 (6): 229–238. Bibcode:1994JBIS...47..229S. ISSN 0007-084X.
  11. Solem, J. C. (2000). "The Moon and the Medusa - Use of Lunar Assets in Nuclear-Pulse-Propelled Space Travel". Journal of the British Interplanetary Society. 53 (1): 362–370.
  12. British Broadcasting Corp. (BBC). (2003). “To Mars By A-Bomb: The Secret History of Project Orion”, a documentary film.
  13. Stevens, Nick. (2014). “The Medusa - An advanced nuclear pulse spacecraft”, a film.
  14. Beals, Keith A.; et al. "Project Longshot An Unmanned Probe To Alpha Centauri" (PDF). NASA. Retrieved March 14, 2011.
  15. 1 2 3 4 Slough et al. "Nuclear Propulsion through Direct Conversion of Fusion Energy:The Fusion Driven Rocket", NASA
  16. 2011 NIAC Phase I Selections http://www.nasa.gov/directorates/spacetech/niac/slough_nuclear_propulsion.html
  17. “Nuclear Propulsion based on Inductively Driven Liner Compression of Fusion Plasmoids”. Slough, J., Kirtley, D., AIAA Aerospace Sciences Conference, 2011.http://msnwllc.com/Papers/FDR_AIAA_2011.pdf
  18. Mission Design Architecture for the Fusion Driven Rocket. Pancotti, A., Slough, J. Kirtley, D. et al. AIAA Joint Propulsion Conference (2012).http://msnwllc.com/Papers/FDR_JPC_2012.pdf
  19. http://www.nbcnews.com/science/scientists-develop-fusion-rocket-technology-lab-aim-mars-1B9235633
  20. Diep, Francie (2013-04-08). "Fusion Rocket Would Shoot People To Mars In 30 Days". Popsci. Retrieved 2013-04-12.
  21. The Fusion Driven Rocket. Slough, J., Pancotti, A., Kirtley, D., Pfaff, M., Pihl, C., Votroubek, G., NASA NIAC( Phase II) Symposium (Nov, 2012).http://www.msnwllc.com/Papers/NIAC_PhaseII_FDR.pdf

External references

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