Interacting galaxy

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Short description: Galaxies with interacting gravitational fields
NGC 3169 (left) and NGC 3166 (right) display some curious features, demonstrating that each member of the duo is close enough to feel the distorting gravitational influence of the other. Image from the Wide Field Imager on the MPG/ESO 2.2-metre telescope at the La Silla Observatory.

Interacting galaxies (colliding galaxies) are galaxies whose gravitational fields result in a disturbance of one another. An example of a minor interaction is a satellite galaxy disturbing the primary galaxy's spiral arms. An example of a major interaction is a galactic collision, which may lead to a galaxy merger.

Satellite interaction

A giant galaxy interacting with its satellites is common. A satellite's gravity could attract one of the primary's spiral arms. Alternatively, the secondary satellite can dive into the primary galaxy, as in the Sagittarius Dwarf Elliptical Galaxy diving into the Milky Way. That can possibly trigger a small amount of star formation. Such orphaned clusters of stars were sometimes referred to as "blue blobs" before they were recognized as stars.[1] File:Galaxy Collision Animation- James Webb Space Telescope Science.webm

Galaxy collision

Two galaxing merging into NGC 5256.

Colliding galaxies are common during galaxy evolution.[2] The extremely tenuous distribution of matter in galaxies means these are not collisions in the traditional sense of the word, but rather gravitational interactions.

Colliding may lead to merging if two galaxies collide and do not have enough momentum to continue traveling after the collision. As with other galaxy collisions, the merging of two galaxies may create a starburst region of new stars.[3] In that case, they fall back into each other and eventually merge into one galaxy after many passes through each other. If one of the colliding galaxies is much larger than the other, it will remain largely intact after the merger. The larger galaxy will look much the same, while the smaller galaxy will be stripped apart and become part of the larger galaxy. When galaxies pass through each other, unlike during mergers, they largely retain their material and shape after the pass.

Galactic collisions are now frequently simulated on computers, which use realistic physics principles, including the simulation of gravitational forces, gas dissipation phenomena, star formation, and feedback. Dynamical friction slows the relative motion of galaxy pairs, which may possibly merge at some point, according to the initial relative energy of the orbits. A library of simulated galaxy collisions can be found at the Paris Observatory website GALMER.[4]

Gallery

Galactic cannibalism

2MASX J16270254+4328340 galaxy has merged with another galaxy leaving a fine mist, made of millions of stars, spewing from it in long trails.[12]

Galactic cannibalism is a common phenomenon.[13] It refers to the process in which a large galaxy, through tidal gravitational interactions with a companion, merges with that companion. The most common result of the gravitational merger between two or more galaxies is a larger irregular galaxy, but elliptical galaxies may also result.

It has been suggested that galactic cannibalism is currently occurring between the Milky Way and the Large and Small Magellanic Clouds. Streams of gravitationally-attracted hydrogen arcing from these dwarf galaxies to the Milky Way is taken as evidence for the theory.

Galaxy harassment

Galaxy harassment is a type of interaction between a low-luminosity galaxy and a brighter one that takes place within rich galaxy clusters, such as Virgo and Coma, where galaxies are moving at high relative speeds and suffering frequent encounters with other systems of the cluster due to the high galactic density.

According to computer simulations, the interactions convert the affected galaxy disks into disturbed barred spiral galaxies and produces starbursts followed by, if more encounters occur, loss of angular momentum and heating of their gas. The result would be the conversion of (late type) low-luminosity spiral galaxies into dwarf spheroidals and dwarf ellipticals.[14]

Evidence for the hypothesis had been claimed by studying early-type dwarf galaxies in the Virgo Cluster and finding structures, such as disks and spiral arms, which suggest they are former disc systems transformed by the above-mentioned interactions.[15] However, the existence of similar structures in isolated early-type dwarf galaxies, such as LEDA 2108986, has undermined this hypothesis[16][17]

Notable interacting galaxies

Montage of some well known interacting galaxies
Name Type Distance
(million ly)
Magnitude Notes
Milky Way Galaxy, LMC and SMC SBc/SB(s)m/SB(s)m pec 0 Satellites interacting with their primary
Whirlpool Galaxy (M51) SAc (SB0-a) 37 +8.4 Satellite interacting with its primary
NGC 1097 SB(s)bc (E6) 45 +9.5 Satellite interacting with its primary
Butterfly galaxies NGC 4567/8 SA(rs)bc / SA(rs)bc 60 +10.9 Early phase of interaction
NGC 2207 and IC 2163 SAc/SAbc 114 +11 galaxies going through the first phase in galactic collision
Mice Galaxies (NGC 4676A and NGC 4676B) S0/SB(s)ab 300 +13.5 galaxies going through the second phase in galactic collision
Antennae Galaxies (NGC 4038/9) SAc/SBm 45 +10.3 galaxies going through the third phase in galactic collision
NGC 520 S 100 +11.3 galaxies going through the third phase in galactic collision
NGC 2936 Irr 352 +12.9 ?

Future collision of the Milky Way with Andromeda

Main page: Astronomy:Andromeda–Milky Way collision

Astronomers have estimated the Milky Way Galaxy will collide with the Andromeda Galaxy in about 4.5 billion years. It is thought that the two spiral galaxies will eventually merge to become an elliptical galaxy[18][19] or perhaps a large disc galaxy.[20]

See also

References

  1. "HubbleSite: News - Hubble Finds that "Blue Blobs" in Space Are Orphaned Clusters of Stars". http://hubblesite.org/news_release/news/2008-02. 
  2. "How the Hubble Space Telescope Changed Our View of the Cosmos". April 21, 2015. https://www.space.com/29157-hubble-space-telescope-science-legacy.html. 
  3. Gianopoulos, Andrea (2022-02-18). "Galaxy Collision Creates 'Space Triangle' in New Hubble Image". http://www.nasa.gov/image-feature/goddard/2022/galaxy-collision-creates-space-triangle-in-new-hubble-image. 
  4. "GALMER". http://galmer.obspm.fr. 
  5. "Galactic Creatures at Play" (in en). https://www.spacetelescope.org/images/potw1931a/. 
  6. "Close encounter". https://www.spacetelescope.org/images/potw1719a/. 
  7. "A close galactic pair". https://www.spacetelescope.org/images/heic1709a/. 
  8. "Two become one". http://www.spacetelescope.org/images/potw1552a/. 
  9. "Galactic soup". ESA/Hubble Picture of the Week. http://www.spacetelescope.org/images/potw1432a/. 
  10. "The messy result of a galactic collision". ESA/Hubble Picture of the Week. http://www.spacetelescope.org/images/potw1321a/. 
  11. "Defying cosmic convention". https://www.spacetelescope.org/images/potw1712a/. 
  12. "The last waltz". http://www.spacetelescope.org/images/potw1547a/. 
  13. "APOD: 2010 July 17 - Galaxies in the River". https://apod.nasa.gov/apod/ap100717.html. 
  14. "Galaxy Harassment". https://supernova.lbl.gov/~evlinder/umass/sumold/nk/harass.html. 
  15. Barazza, F. D.; Binggeli, B.; Jerjen, H. (2002-09-01). "More evidence for hidden spiral and bar features in bright early-type dwarf galaxies". Astronomy and Astrophysics 391 (3): 823–831. doi:10.1051/0004-6361:20020875. ISSN 0004-6361. Bibcode2002A&A...391..823B. https://ui.adsabs.harvard.edu/abs/2002A&A...391..823B. 
  16. Graham, Alister W.; Janz, Joachim; Penny, Samantha J.; Chilingarian, Igor V.; Ciambur, Bogdan C.; Forbes, Duncan A.; Davies, Roger L. (2017-05-01). "Implications for the Origin of Early-type Dwarf Galaxies: A Detailed Look at the Isolated Rotating Early-type Dwarf Galaxy LEDA 2108986 (CG 611), Ramifications for the Fundamental Plane's {S}_{K}^{2} Kinematic Scaling, and the Spin-Ellipticity Diagram". The Astrophysical Journal 840 (2): 68. doi:10.3847/1538-4357/aa6e56. ISSN 0004-637X. Bibcode2017ApJ...840...68G. 
  17. Janz, Joachim; Penny, Samantha J.; Graham, Alister W.; Forbes, Duncan A.; Davies, Roger L. (2017-07-01). "Implications for the origin of early-type dwarf galaxies - the discovery of rotation in isolated, low-mass early-type galaxies". Monthly Notices of the Royal Astronomical Society 468 (3): 2850–2864. doi:10.1093/mnras/stx634. ISSN 0035-8711. Bibcode2017MNRAS.468.2850J. https://ui.adsabs.harvard.edu/abs/2017MNRAS.468.2850J. 
  18. whose gravitational interactions will fling various celestial bodies outward, evicting them from the resulting elliptical galaxy.Hazel Muir (2007-05-14). "Galactic merger to 'evict' Sun and Earth". New Scientist. https://www.newscientist.com/article/dn11852-galactic-merger-to-evict-sun-and-earth.html#.VDVdDvl_uVB. 
  19. Astronomy, June 2008, page 28, by Abraham Loeb and T.J.Cox
  20. Junko Ueda (2014). "Cold molecular gas in merger remnants. I. Formation of molecular gas disks". The Astrophysical Journal Supplement Series 214 (1): 1. doi:10.1088/0067-0049/214/1/1. Bibcode2014ApJS..214....1U. 

External links




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