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WISEA 1810−1010

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WISEA 1810-1010

near-infrared image of WISEA 1810-1010
Observation data
Epoch J2000      Equinox J2000
Constellation Serpens
Right ascension 18h 10m 06.18s
Declination −10° 10′ 00.5″
Characteristics
Evolutionary stage brown dwarf
Spectral type esdT3:[1]
Apparent magnitude (J) 17.264 ± 0.020
Apparent magnitude (H) 16.500 ± 0.018
Apparent magnitude (K) 17.162 ± 0.081
Astrometry
Radial velocity (Rv)45.6 ±3.5[2] km/s
Proper motion (μ) RA: -1027.0±3.5 mas/yr[2]
Dec.: -246.4±3.6 mas/yr[2]
Parallax (π)112.5 ± 8.1 mas[2]
Distance29 ± 2 ly
(8.9 ± 0.6 pc)
Absolute bolometric
magnitude
 (Mbol)
19.850+0.082
−0.074
Details
Mass17+56
−12
[2] MJup
Radius0.65+0.31
−0.19
[2] RJup
Surface gravity (log g)5.0±0.25[2] cgs
Temperature800±100[2] K
Metallicity [Fe/H]−1.5±0.5[2] dex
Other designations
WISEA J181006.18-101000.5, CWISEP J181006.00-101001.1
Database references
SIMBADdata

WISEA J181006.18-101000.5 or WISEA 1810-1010 is a substellar object in the constellation Serpens about 8.9 parsec or 29 light-years distant from earth.[2] It stands out because of its peculiar colors matching both L-type and T-type objects, likely due to its very low metallicity. Together with WISEA 0414−5854 it is the first discovered extreme subdwarf (esd) of spectral type T.[3] Lodieu et al. describe WISEA 1810-1010 as a water vapor dwarf due to its atmosphere being dominated by hydrogen and water vapor.[2]

Discovery

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WISEA 1810-1010 was first identified with the NEOWISE proper motion survey in 2016, but the proper motion could not be confirmed because of the high density of background stars in this field near the galactic plane. In 2020 the object was re-examined with the WiseView tool by the researchers of the Backyard Worlds project and was found to have significant proper motion. Additionally the object was independently discovered by the citizen scientist Arttu Sainio via the Backyard Worlds project.[3]

Observations

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The object was initially observed by the Backyard Worlds researchers from US and Canada with Keck/NIRES and Palomar/TripleSpec.[3] Later it was observed by another team from Spain, UK and Poland with NOT/ALFOSC, GTC/multiple instruments and Calar Alto/Omega2000.[2]

Analysis of the Keck and Palomar spectrum found that WISEA 1810-1010 has much deeper 1.15 μm (Y/J-band) absorption when compared to the extreme subdwarf of spectral type L7 2MASS 0532+8246, but the shape of the H-band is similar to this esdL7. The Y- and J-band spectrum does match better with spectra from subdwarfs with early spectral type T.[3]

Distance and physical properties

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The distance was first poorly constrained at either 14 or 67 parsec,[3] but using archived and new data the parallax was measured, which constrained the distance to 8.9+0.7
−0.6
 pc
.[2]

The object has a mass of 17+56
−12
 MJ
, which makes this object a brown dwarf or a sub-brown dwarf, with a temperature of 700 to 900 K.[2] A spectral type of esdT3: was estimated based on a new work that introduced a new classification scheme for cold subdwarfs. The prefix esd stands for "extreme subdwarfs" and the double point stands for a highly uncertain numerical spectral type. Best-fitted SAND models find a temperature and radius similar to the previous estimate by Lodieu et al. The motion of WISEA 1810-1010 was used to predict a 91% probability of thin disk membership and a 9% probability of thick disk membership. It is however noted that high probability of thin disk membership, does not rule out thick disk membership.[1]

Atmosphere

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The only chemicals detected in the atmosphere of WISEA 1810-1010 are hydrogen and strong absorption due to water vapor. This is surprising because T-dwarfs are defined by methane in their atmosphere and the hotter L-dwarfs are partly defined by carbon monoxide in their atmosphere. Both are missing in WISEA 1810-1010. The missing of carbon monoxide and methane can be explained by a carbon-deficient and metal-poor atmosphere. Alternatively the spectrum could be explained by an oxygen-enhanced atmosphere.[2]

Model spectra suggest a very metal-poor atmosphere with .[2]

Spectral type

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Schneider et al. noted first the similarities of the spectrum with both L-dwarfs and T-dwarfs. The tentative classification as esdT0.0±1.0 was given due to the low estimated temperature.[3] The discovery by Lodieu et al. that methane was not present in the near-infrared spectrum raised the question if a T-dwarf classification was possible. Methane is a key diagnostic feature for T-dwarfs.[2] Jun-Yan Zhang et al. noted that WISEA 1810 cannot be classified as an L-dwarf either because of some key differences, such as:[4]

  • A redder W1-W2 color.
  • Missing hydrides (such as FeH), which become stronger in metal-poor L-dwarfs.
  • L-subdwarfs have little water absorptions, but WISEA 1810 has deep water absorptions

JWST observations of the methane band and other molecules in the mid-infrared of WISEA 1810 or other proposed esdT might resolve the question if these objects can be classified as T-dwarfs. If these objects cannot be classified as T-dwarfs, they might be given a new spectral type. Jun-Yan Zhang et al. proposed the letters H or Z (therefore H-dwarf or Z-dwarf). New esdT (or H/Z-dwarfs) might be discovered in the future with ESA's Euclid and the Rubin Observatory.[4]

See also

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References

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  1. ^ a b Burgasser, Adam J.; Schneider, Adam C.; Meisner, Aaron M.; Caselden, Dan; Hsu, Chih-Chun; Gerasimov, Roman; Aganze, Christian; Softich, Emma; Karpoor, Preethi; Theissen, Christopher A.; Brooks, Hunter; Bickle, Thomas P.; Gagné, Jonathan; Artigau, Étienne; Marsset, Michaël; Rothermich, Austin; Faherty, Jacqueline K.; Kirkpatrick, J. Davy; Kuchner, Marc J.; Andersen, Nikolaj Stevnbak; Beaulieu, Paul; Colin, Guillaume; Gantier, Jean Marc; Gramaize, Leopold; Hamlet, Les; Hinckley, Ken; Kabatnik, Martin; Kiwy, Frank; Martin, David W.; Massat, Diego H.; Pendrill, William; Sainio, Arttu; Schümann, Jörg; Thévenot, Melina; Walla, Jim; Wędracki, Zbigniew; the Backyard Worlds: Planet 9 Collaboration (2 November 2024). "New Cold Subdwarf Discoveries from Backyard Worlds and a Metallicity Classification System for T Subdwarfs". arXiv:2411.01378 [astro-ph].{{cite arXiv}}: CS1 maint: numeric names: authors list (link)
  2. ^ a b c d e f g h i j k l m n o p Lodieu, N.; Zapatero Osorio, M. R.; Martín, E. L.; Rebolo López, R.; Gauza, B. (1 July 2022). "Physical properties and trigonometric distance of the peculiar dwarf WISE J181005.5−101002.3". Astronomy and Astrophysics. 663: A84. arXiv:2206.13097. Bibcode:2022A&A...663A..84L. doi:10.1051/0004-6361/202243516. ISSN 0004-6361. S2CID 249836684.
  3. ^ a b c d e f Schneider, Adam C.; Burgasser, Adam J.; Gerasimov, Roman; Marocco, Federico; Gagné, Jonathan; Goodman, Sam; Beaulieu, Paul; Pendrill, William; Rothermich, Austin; Sainio, Arttu; Kuchner, Marc J.; Caselden, Dan; Meisner, Aaron M.; Faherty, Jacqueline K.; Mamajek, Eric E. (1 July 2020). "WISEA J041451.67-585456.7 and WISEA J181006.18-101000.5: The First Extreme T-type Subdwarfs?". The Astrophysical Journal. 898 (1): 77. arXiv:2007.03836. Bibcode:2020ApJ...898...77S. doi:10.3847/1538-4357/ab9a40. ISSN 0004-637X. S2CID 220403370.
  4. ^ a b Jun-Yan Zhang, Jerry; Lodieu, Nicolas; Martín, Eduardo (August 2023). "Optical Properties of Metal-poor T Dwarf Candidates". p. 12. arXiv:2308.10617 [astro-ph.SR].