Reactionless drive

A reactionless drive (also known by many other names, including as an inertial propulsion engine, a reactionless thruster, a reactionless engine, a bootstrap drive or an inertia drive) is a device to generate motion without a propellant, presumably in contradiction to the law of conservation of momentum.[1] The name comes from Newton's third law, which is usually expressed as, "for every action, there is an equal and opposite reaction." A large number of infeasible devices, such as the "Dean drive", are a staple of science fiction, particularly for space propulsion. To date, no reactionless drive has ever been validated under properly controlled conditions.

Historical attempts

Through the years there have been numerous claims for functional reactionless drive designs using ordinary mechanics (i.e. devices not said to be based on quantum mechanics, relativity or atomic forces or effects). Two of these represent their general classes: The "Dean drive" is perhaps the best known example of a "linear oscillating mechanism" reactionless drive; The "GIT" is perhaps the best known example of a "rotating mechanism" reactionless drive. These two also stand out as they both received much publicity from their promoters and the popular press in their day and both were eventually rejected when proven to not produce any reactionless drive forces. The rise and fall of these devices now serves as cautionary tale for those making and reviewing similar claims.[2]

Dean drive

Main article: Dean drive

The Dean drive was a mechanical device concept promoted by inventor Norman L. Dean. Dean claimed that his device was a "reactionless thruster" and that his working models could demonstrate this effect. He held several private demonstrations but never revealed the exact design of the models nor allowed independent analysis of them.[3][4] Dean's claims of reactionless thrust generation were subsequently shown to be in error and the "thrust" producing the directional motion was likely to be caused by friction between the device and the surface on which the device was resting and would not work in free space.[2][5]

Gyroscopic Inertial Thruster (GIT)

The Gyroscopic Inertial Thruster is a proposed reactionless drive based on the mechanical principles of a rotating mechanism. The concept involves various methods of leverage applied against the supports of a large gyroscope. The supposed operating principle of a GIT is a mass traveling around a circular trajectory at a variable speed. The high-speed part of the trajectory allegedly generates greater centrifugal force than the low, so that there is a greater thrust in one direction than the other.[6] Scottish inventor Sandy Kidd, a former RAF radar technician, investigated the possibility (without success) in the 1980s.[7] He posited that a gyroscope set at various angles could provide a lifting force, defying gravity.[8] In the 1990s, several people sent suggestions to the Space Exploration Outreach Program (SEOP) at NASA recommending that NASA study a gyroscopic inertial drive, especially the developments attributed to the American inventor Robert Cook and the Canadian inventor Roy Thornson.[6] In the 1990s and 2000s, enthusiasts attempted the building and testing of GIT machines.[9] Eric Laithwaite, the "Father of Maglev", received a US patent for his "Propulsion System", which was claimed to create a linear thrust through gyroscopic and inertial forces.[10] After years of theoretical analysis and laboratory testing of actual devices, no rotating (or any other) mechanical device has ever been found to produce unidirectional reactionless thrust in free space.[2]

Quasi-reactionless methods

Several kinds of thrust generating methods are in use, that are sometimes described as reactionless, because these methods do not work like rockets and reaction mass is not carried nor expelled from the spacecraft during their application. However, as such they are merely reaction-mass-less, but they all exchange momentum (react) with an outside agent instead.

Modern approaches

Although the laws of classical physics regard reactionless propulsion as impossible, hypothetical methods based on principles from quantum mechanics, electrodynamics, relativity and nuclear physics have been put forward that would create similar effects without, the authors claim, violating any laws of physics. So far none of these methods has been unambiguously demonstrated to work in free space.

Devices that do not generate thrust

Because there is no well-defined "center of mass" in curved spacetime, general relativity allows a stationary object to, in a sense, "change its position" in a counter-intuitive manner, without violating conservation of momentum.

See also

References

  1. Plait, Phil. "NASA’s Quantum Drive: Cool Your Jets". Phil Plait's Bad Astronomy blog, via Slate. Retrieved 25 November 2014.
  2. 1 2 3 Mills, Marc G.; Thomas, Nicholas E. (July 2006). Responding to Mechanical Antigravity (PDF). 42nd Joint Propulsion Conference and Exhibit. NASA. Archived from the original (PDF) on 2011-10-30.
  3. "Engine With Built-in Wings". Popular Mechanics. Sep 1961.
  4. "Detesters, Phasers and Dean Drives". Analog. June 1976.
  5. Goswami, Amit (2000). The Physicists' View of Nature. Springer. p. 60. ISBN 0-306-46450-0.
  6. 1 2 LaViolette, Paul A. (2008). Secrets of Antigravity Propulsion: Tesla, UFOs, and Classified Aerospace Technology. Inner Traditions / Bear & Co. p. 384. ISBN 1-59143-078-X.
  7. New Scientist 148: 96. 1995. Missing or empty |title= (help)
  8. Childress, David Hatcher (1990). Anti-Gravity & the Unified Field. Lost Science. Adventures Unlimited Press. p. 178. ISBN 0-932813-10-0.
  9. "The Adventures of the Gyroscopic Inertial Flight Team". 1998-08-13.
  10. U.S. Patent 5,860,317
  11. Tethers | Macmillan Space Sciences. Accessed 2008-05-04.
  12. "Special Projects Group via Internet Archive. Accessed 2008-05-04". Web.archive.org. 2002-11-13. Archived from the original on November 13, 2002. Retrieved 2011-06-21.
  13. Charrier, Dimitri S.H. (July 18, 2012). "Micronewton electromagnetic thruster". Applied Physics Letters (American Institute of Physics) 101: 034104. Bibcode:2012ApPhL.101c4104C. doi:10.1063/1.4737940. Retrieved January 4, 2014.
  14. Kakaes, Konstantin. "Warp Factor: A NASA scientist claims to be on the verge of faster-than-light travel: is he for real?, Popular Science, April 2013". PopSci.com. Retrieved 2014-11-22.
  15. http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/20110015936.pdf
  16. http://www.nature.com/scientificamerican/journal/v301/n2/full/scientificamerican0809-38.html
  17. "Swimming Through Empty Space". Science 2.0.

External links

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