A substellar object, sometimes called a substar, is an astronomical object the mass of which is smaller than the smallest mass at which hydrogen fusion can be sustained (approximately 0.08 solar masses). This definition includes brown dwarfs and former stars similar to EF Eridani B, and can also include objects of planetary mass, regardless of their formation mechanism and whether or not they are associated with a primary star.[1][2][3][4]

Assuming that a substellar object has a composition similar to the Sun's and at least the mass of Jupiter (approximately 10−3 solar masses), its radius will be comparable to that of Jupiter (approximately 0.1 solar radii) regardless of the mass of the substellar object (brown dwarfs are less than 75 Jupiter masses). This is because the center of such a substellar object at the top range of the mass (just below the hydrogen-burning limit) is quite degenerate, with a density of ≈103 g/cm3, but this degeneracy lessens with decreasing mass until, at the mass of Jupiter, a substellar object has a central density less than 10 g/cm3. The density decrease balances the mass decrease, keeping the radius approximately constant.[5]

Substellar objects like brown dwarfs do not have enough mass to fuse hydrogen and helium, hence do not undergo the usual stellar evolution that limits the lifetime of stars.

A substellar object with a mass just below the hydrogen-fusing limit may ignite hydrogen fusion temporarily at its center. Although this will provide some energy, it will not be enough to overcome the object's ongoing gravitational contraction. Likewise, although an object with mass above approximately 0.013 solar masses will be able to fuse deuterium for a time, this source of energy will be exhausted in approximately 106 to 108 years (1100 million years). Apart from these sources, the radiation of an isolated substellar object comes only from the release of its gravitational potential energy, which causes it to gradually cool and shrink. A substellar object in orbit about a star will shrink more slowly as it is kept warm by the star, evolving towards an equilibrium state where it emits as much energy as it receives from the star.[6]

Substellar objects are cool enough to have water vapor in their atmosphere. Infrared spectroscopy can detect the distinctive color of water in gas giant size substellar objects, even if they are not in orbit about a star.[7]

Classification

William Duncan MacMillan proposed in 1918 the classification of substellar objects into three categories based on their density and phase state: solid, transitional and dark (non-stellar) gaseous.[8] Solid objects include Earth, smaller terrestrial planets and moons; with Uranus and Neptune (as well as later mini-Neptune and Super Earth planets) as transitional objects between solid and gaseous. Saturn, Jupiter and large gas giant planets are in a fully "gaseous" state.

Substellar companion

Earth and space bound observatories observe Gliese 229 and its companion, which is perhaps 2040 Jupiter masses in size[9]

A substellar object may be a companion of a star,[9] such as an exoplanet or brown dwarf that is orbiting a star.[10] Objects as low as 823 Jupiter masses have been called substellar companions.[11]

Objects orbiting a star are often called planets below 13 Jupiter masses and brown dwarves above that.[12] Companions at that planet-brown dwarf borderline have been called Super-Jupiters, such as that around the star Kappa Andromedae.[13] Nevertheless, objects as small as 8 Jupiter masses have been called brown dwarves.[14]

A substellar companion is thought to exist in the binary star system SDSS 1212.[15] Substellar companions have been confirmed by analyzing astrometric data from Hipparcos.[16]

See also

References

  • Quoted as Chabrier and Baraffe: Chabrier, Gilles; Baraffe, Isabelle (September 2000). "Theory of Low-Mass Stars and Substellar Objects". Annual Review of Astronomy and Astrophysics. 38: 337–377. arXiv:astro-ph/0006383. Bibcode:2000ARA&A..38..337C. doi:10.1146/annurev.astro.38.1.337. S2CID 59325115.
  1. §3, What Is a Planet?, Steven Soter, Astronomical Journal, 132, #6 (December 2006), pp. 2513–2519.
  2. Chabrier and Baraffe, pp. 337–338
  3. Alula Australis Archived 2006-08-24 at the Wayback Machine, Jim Kaler, in Stars, a collection of web pages. Accessed on line September 17, 2007.
  4. A search for substellar members in the Praesepe and σ Orionis clusters, B. M. González-García, M. R. Zapatero Osorio, V. J. S. Béjar, G. Bihain, D. Barrado Y Navascués, J. A. Caballero, and M. Morales-Calderón, Astronomy and Astrophysics 460, #3 (December 2006), pp. 799–810.
  5. Chabrier and Baraffe, §2.1.1, 3.1, Figure 3
  6. Chabrier and Baraffe, §4.1, Figures 6–8
  7. Hille, Karl (2018-01-11). "Hubble Finds Substellar Objects in the Orion Nebula". NASA. Retrieved 2018-01-30.
  8. MacMillan, W. D. (July 1918). "On stellar evolution". Astrophysical Journal. 48: 35–49. Bibcode:1918ApJ....48...35M. doi:10.1086/142412.
  9. 1 2 STScI-1995-48
  10. Mugrauer, M., et al - Direct detection of a substellar companion to the young nearby star PZ Telescopii (2010)
  11. S. Geier, et al - Discovery of a Close Substellar Companion to the Hot Subdwarf Star HD 149382 (2009)
  12. Boss, A. P.; Basri, Gibor; Kumar, Shiv S.; Liebert, James; Martín, Eduardo L.; Reipurth, B.; "Nomenclature: Brown Dwarfs, Gas Giant Planets, and ?", in Brown Dwarfs, Proceedings of IAU Symposium #211, held 20–24 May 2002 at University of Hawaii, Honolulu
  13. Astronomers Directly Image Massive Star's 'Super-Jupiter'11.19.12
  14. Discovery of a Planetary-Mass Brown Dwarf with a Circumstellar Disk, Luhman, et al., 2005
  15. Detection of Substellar Companion in Interacting Binary
  16. Sabine Reffert, Andreas Quirrenbach - Mass constraints on substellar companion candidates from the re-reduced Hipparcos intermediate astrometric data: Nine confirmed planets and two confirmed brown dwarfs (2011)
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.