Intergalactic travel

Stars in the Large Magellanic Cloud, a dwarf galaxy. At a distance of 160,000 light-years, the LMC is the third closest galaxy to the Milky Way.

Intergalactic travel is the term used for hypothetical manned or unmanned travel between galaxies. Due to the enormous distances between our own galaxy the Milky Way and even its closest neighborshundreds of thousands to millions of light-yearsany such venture would be far more technologically demanding than even interstellar travel. Intergalactic distances are roughly a hundred-thousandfold (five orders of magnitude) greater than their interstellar counterparts.[lower-alpha 1]

The technology required to travel between galaxies is far beyond humanity's present capabilities, and currently only the subject of speculation, hypothesis, and science fiction.

However, scientifically speaking, there is nothing to indicate that intergalactic travel is impossible. There are in fact several conceivable methods of doing it; to date there have been a few people who have studied intergalactic travel in a serious manner.[1][2][3]

The difficulties of intergalactic travel

Due to the size of the distances involved any serious attempt to travel between galaxies would require methods of propulsion far beyond what is currently thought possible in order to bring a large craft close to the speed of light.

According to the current understanding of physics, an object within space-time cannot exceed the speed of light,[4] which means an attempt to travel to any other galaxy would be a journey of millions of earth years via conventional flight.

Manned travel at a speed not close to the speed of light, would require either that we overcome our own mortality with technologies like radical life extension or traveling with a generation ship. If traveling at a speed closer to the speed of light, time dilation would allow intergalactic travel in a timespan of decades of on-ship time.

These challenges also mean a return trip would be very difficult.

Possible methods

Extreme long-duration voyages

Voyages to other galaxies at sub-light speeds would require voyage times anywhere from hundreds of thousands to many millions of years. To date only one design such as this has ever been made.[1]

Hypervelocity stars

Theorized in 1988,[5] and observed in 2005,[6] there are stars moving faster than the escape velocity of the Milky Way, and are traveling out into intergalactic space.[7] There are several theories for their existence. One of the mechanisms would be that the supermassive black hole at the center of the Milky Way ejects stars from the galaxy at a rate of about one every hundred thousand years. Another theorized mechanism might be a supernova explosion in a binary system.[8]

These stars travel at speeds up to about 3,000 km/second. However, recently (November 2014) stars going up to a significant fraction of the speed of light have been postulated, based on numerical methods.[9] Called Semi-Relativistic Hypervelocity Stars by the authors, these would be ejected by mergers of supermassive black holes in colliding galaxies. And, the authors think, will be detectable by forthcoming telescopes.[10]

These could be used by entering into an orbit around them and waiting.[11][12]

Stellar engines

Another proposal is to artificially propel a star in the direction of another galaxy.[13][14]

Time dilation

While it takes light approximately 2.54 million years to traverse the gulf of space between Earth and, for instance, the Andromeda Galaxy, it would take a much shorter amount of time from the point of view of a traveler at close to the speed of light due to the effects of time dilation; the time experienced by the traveler depending both on velocity (anything less than the speed of light) and distance traveled (length contraction). Intergalactic travel for humans is therefore possible, in theory, from the point of view of the traveller.[15]

Accelerating to speeds closer to the speed of light with a relativistic rocket would allow the on-ship travel time to be drastically lower, but would require very large amounts of energy. A way to do this is space travel using constant acceleration. Traveling to the Andromeda Galaxy, 2 million light years away, would take 28 years on-ship time with a constant acceleration of 1g and a deceleration of 1g after reaching half way, to be able to stop.

Going to the Andromeda Galaxy at this acceleration would require 4 100 000 kg fuel per kg payload using the unrealistic assumption of a 100% efficient engine that converts matter to energy. Decelerating at the halfway point in order to stop dramatically increases the fuel requirements to 42 trillion kg fuel per kg payload. This is ten times the mass of Mt Everest required in fuel for each kg of payload. As the fuel contributes to the total mass of the ship, carrying more fuel also increases the energy required to travel at a certain acceleration and extra fuel added to make up for the increased mass would further contribute to the problem.[16]

The fuel requirements of going to the Andromeda Galaxy with constant acceleration means that either the payload has to be very small, the spaceship has to be very large or it has to collect fuel or receive energy on the way through other means.

Possible faster-than-light methods

The Alcubierre drive is a highly hypothetical concept that is able to impulse a spacecraft to speeds faster than light. (The spaceship itself would not move faster than light, but the space around it would.) This could in theory allow practical intergalactic travel. There is no known way to create the space-distorting wave this concept needs to work, but the metrics of the equations comply with relativity and the limit of light speed.[17]

See also

References

  1. 1 2 Burruss, Robert Page; Colwell, J. (September–October 1987). "Intergalactic Travel: The Long Voyage From Home". The Futurist. 21 (5): 29–33.
  2. Fogg, Martyn (November 1988). "The Feasibility of Intergalactic Colonisation and its Relevance to SETI". Journal of the British Interplanetary Society. 41 (11): 491–496.
  3. Armstrong, Stuart; Sandberg, Anders. "Eternity in six hours: intergalactic spreading of intelligent life and sharpening the Fermi paradox" (PDF). Future of Humanity Institute, Philosophy Department, Oxford University.
  4. "Star Trek's Warp Drive: Not Impossible". space.com. 6 May 2009.
  5. Hills, J. G. (1988). "Hyper-velocity and tidal stars from binaries disrupted by a massive Galactic black hole". Nature. 331 (6158): 687–689. Bibcode:1988Natur.331..687H. doi:10.1038/331687a0.
  6. Brown, Warren R.; Geller, Margaret J.; Kenyon, Scott J.; Kurtz, Michael J. (2005). "Discovery of an Unbound Hypervelocity Star in the Milky Way Halo". Astrophysical Journal. 622 (1): L33–L36. arXiv:astro-ph/0501177Freely accessible. Bibcode:2005ApJ...622L..33B. doi:10.1086/429378.
  7. "The Hyper Velocity Star Project: The stars". The Hyper-Velocity Star Project. 6 September 2009. Retrieved 20 September 2014.
  8. Watzke, Megan (28 November 2007). "Chandra discovers cosmic cannonball". Newswise.
  9. Guillochon, James; Loeb, Abraham (18 Nov 2014). "The Fastest Unbound Stars in the Universe". arXiv:1411.5022Freely accessible.
  10. Guillochon, James; Loeb, Abraham (18 Nov 2014). "Observational Cosmology With Semi-Relativistic Stars". arXiv:1411.5030v1Freely accessible.
  11. Villard, Ray (24 May 2010). "The Great Escape: Intergalactic Travel is Possible". Discovery News. Retrieved October 2010. Check date values in: |access-date= (help)
  12. Gilster, Paul (26 June 2014). "Intergalactic Travel via Hypervelocity Stars". centauri-dreams.org. Retrieved 16 September 2014.
  13. Gilster, Paul (27 June 2014). "Stars as Stellar Engines". centauri-dreams.org. Retrieved 16 September 2014.
  14. Gilster, Paul (30 June 2014). "Building the Bowl of Heaven". centauri-dreams.org. Retrieved 16 September 2014.
  15. Gilster, Paul (25 June 2014). "Sagan's Andromeda Crossing". centauri-dreams.org. Retrieved 16 September 2014.
  16. http://math.ucr.edu/home/baez/physics/Relativity/SR/Rocket/rocket.html
  17. Alcubierre, Miguel (1994). "The warp drive: hyper-fast travel within general relativity". Classical and Quantum Gravity. 11 (5): L73–L77. arXiv:gr-qc/0009013Freely accessible. Bibcode:1994CQGra..11L..73A. doi:10.1088/0264-9381/11/5/001.

Notes

  1. Between small galaxies, which are the majority of galaxies, distances are typically a few hundred thousand light-years. Between large galaxies like the Milky Way and M31, they are typically a few million light-years.
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