Astronomy:TOI-2257 b

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Short description: Exoplanet partially in the habitable zone
TOI-2257 b
Discovery[1]
Discovered bySchanche et al.
Discovery dateNovember 2021
Transit
Orbital characteristics[1]
0.145±0.003 astronomical unit|AU
Eccentricity0.496+0.216
−0.133
Orbital period35.189346(90) d
Inclination89.786°+0.078°
−0.062°
StarTOI-2257
Physical characteristics[1]
Mean radius2.194+0.113
−0.111
 R
Mass5.712+4.288
−2.311
 M
(predicted)
Physics256+61
−17
 K
(−17 °C; 1 °F, equilibrium)

TOI-2257 b is an extremely eccentric (0.496)[2] exoplanet in or near the circumstellar habitable zone of the star TOI-2257, 188 light-years away. It is likely a sub-Neptune exoplanet, with a mass of 5.71 Mearth and a radius of 2.19 Rearth.[3] As a small planet in the habitable zone, it is included in the Planetary Habitability Laboratory's list of potentially habitable exoplanets.[4]

Discovery

The planet was discovered using the transit method, by TESS in November 2021. It has one of the longest orbital periods of any TESS planet. Further observations intend to find possible water vapor in the atmosphere of the planet, as well as any other planets in the system if they exist. The planet is most likely not a false positive, and its existence is supported by photometry and the high-resolution observations of ground-based telescopes.[3]

Properties

Mass, radius, and temperature

The planet has a radius 2.19 times that of Earth. Its mass and density are unknown, although it is predicted to have a mass roughly 3.4-10 times that of Earth based on mass-radius relationships.[1] Based on its size, it is likely a Neptune-like world. Its average equilibrium temperature is 256 K (−17 °C; 1 °F), similar to the average temperature of Alert, Canada on Earth, and varies from approximately 193 K (−80 °C; −112 °F) during aphelion to 373 K (100 °C; 212 °F) at perihelion.[3][5] However, the actual temperature could differ and would also vary throughout the planet's eccentric orbit.[2]

Orbit

The planet has an orbital period of 35.19 days, with an extremely high eccentricity of almost 0.5.[3] It has a semimajor axis of 0.145 AU, approximately half of Mercury's at the point in its orbit nearest to the Sun.[2] According to NASA Exoplanet Exploration, the planet's eccentric orbit takes it through the "too hot" zone (albeit for a very short amount of time), then out to the outer fringes of the habitable zone, near the border with the "too cold" zone.[6]

The planet has the highest eccentricity ever recorded around an M-type star, and the third highest of any known mini-Neptune as of 2021.[7]

Star

The planet's star is M3V, with a temperature of 3,430 K. It has a metallicity of -0.27 and is about 8 billion years old, with ~0.3 times the mass and 0.33 times the radius of the Sun.[3][2] For comparison, the Sun has a temperature of 5,778 K and is 4,572,000,000 years old, with a spectral class of G2V. The metallicity is 0.00.

Habitability

The planet gets 37/50ths of the light that Earth gets from the Sun, putting it well within the habitable zone. However, the planet is likely a mini-Neptune given its size. The planet has an ESI of 0.72, similar to that of Mars and Kepler-22b.[3][4] The equilibrium temperature could range from a comfortable 317 K (44 °C; 111 °F) to a chilly 239 K (−34 °C; −29 °F), both within the thermal amplitude of the Earth.[2] With a greenhouse effect similar in intensity to Earth's, the temperature would be around 289 K (16 °C; 61 °F), and with a greenhouse effect twice as strong as Earth's, 322 K (49 °C; 120 °F).[8] The temperature would vary throughout the planet's eccentric orbit. Due to the planet's habitable-zone location, water vapor is possible in the atmosphere. More detailed characterizations of the planet's atmosphere, including determining whether water vapor is present are expected from the JWST.[3][7]

Tidal locking

Due to the planet's distance from its star, it would likely be tidally locked, with one side always facing the star, if it had a near-circular orbit. Due to its eccentric orbit, it is likely in a spin-orbit resonance instead.[9]

Eccentricity

The planet has an extremely high eccentricity, which could, perhaps, play a part in its habitability. The planet, due to its high eccentricity, could go through frigid winters and sweltering summers. This could compromise its habitability by setting off a runaway greenhouse effect if a long period of time is spent above 320 K (47 °C) or 117 °F, or a runaway glaciation effect if a long period of time is spent far below 273 K (0 °C) or 32 °F. This would cause most or all of the planet to become uninhabitable, regardless of atmospheric conditions that combat tidal locking.[10] On the other hand, the planet's eccentricity could be a factor working against tidal locking in and of itself; the planet would settle into a 3:2 resonance, where the year is 1.5 times as long as the day. Models show that such a planet, if oceanic, would have open water in the lower and middle latitudes and water ice above 60 °N/below 60 °S, much like on our Earth. This model is known as the "striped-ball planet".[11]

In this model, there are four temperature tiers, with the warmest ocean temperatures occurring between 21 °N and °S, the next warmest between 21 and 46° on both sides of the equator, the second coldest between 46 and 62°, and the coldest, cold enough to form sea ice, between 61° and the poles. The freezing temperature of ocean water is assumed to be −1.8 °C (28.8 °F).[11]

See also

References

  1. 1.0 1.1 1.2 1.3 Schanche, N. et al. (January 2022). "TOI-2257 b: A highly eccentric long-period sub-Neptune transiting a nearby M dwarf". Astronomy & Astrophysics 657: A45. doi:10.1051/0004-6361/202142280. Bibcode2022A&A...657A..45S. 
  2. 2.0 2.1 2.2 2.3 2.4 "TOI-2257 | NASA Exoplanet Archive". https://exoplanetarchive.ipac.caltech.edu/overview/TOI-2257%20b#planet_TOI-2257-b_collapsible. 
  3. 3.0 3.1 3.2 3.3 3.4 3.5 3.6 Nowakowski, Tomasz; Phys.org. "Astronomers discover a sub-Neptune exoplanet orbiting nearby star" (in en). https://phys.org/news/2021-11-astronomers-sub-neptune-exoplanet-orbiting-nearby.html. 
  4. 4.0 4.1 "PHL @ UPR Arecibo - The Habitable Exoplanets Catalog" (in en-US). https://phl.upr.edu/projects/habitable-exoplanets-catalog. 
  5. Bern, University of (2022-01-09). "Eccentric Exoplanet Discovered: Sub-Neptune Planet Orbiting in "Habitable Zone" of Red Dwarf Star" (in en-us). https://scitechdaily.com/eccentric-exoplanet-discovered-sub-neptune-planet-orbiting-in-habitable-zone-of-red-dwarf-star/. 
  6. "Exoplanet-catalog" (in en). https://exoplanets.nasa.gov/exoplanet-catalog/8042/toi-2257-b/. 
  7. 7.0 7.1 Lea, Robert (2021-11-15). "Astronomers Find Sub-Neptune Planet That May Have Liquid Water" (in en). https://www.newsweek.com/astronomers-discover-sub-neptune-planet-twice-earths-size-liquid-water-toi-2257b-tess-1649297. 
  8. "Greenhouse effects... also on other planets" (in en). https://www.esa.int/Science_Exploration/Space_Science/Venus_Express/Greenhouse_effects_also_on_other_planets. 
  9. Hasler, Caroline (2022-02-17). "Tidally Locked and Loaded with Questions" (in en-US). http://eos.org/features/tidally-locked-and-loaded-with-questions. 
  10. "Obliquity and eccentricity determine exoplanet habitability". https://www.earthmagazine.org/article/obliquity-and-eccentricity-determine-exoplanet-habitability. 
  11. 11.0 11.1 Wang, Yuwei; Tian, Feng; Hu, Yongyun (July 2014). "Climate Patterns of Habitable Exoplanets in Eccentric Orbits Around M Dwarfs" (in en). The Astrophysical Journal Letters 791 (1): L12. doi:10.1088/2041-8205/791/1/L12. ISSN 2041-8205. Bibcode2014ApJ...791L..12W. 
  12. "NASA's Hubble Finds Water Vapor on Habitable-Zone Exoplanet for 1st Time - NASA Science" (in en). https://science.nasa.gov/missions/hubble/nasas-hubble-finds-water-vapor-on-habitable-zone-exoplanet-for-1st-time/. 
  13. Diamond-Lowe, Hannah; Kreidberg, Laura; Harman, C. E.; Kempton, Eliza M.-R.; Rogers, Leslie A.; Joyce, Simon R. G.; Eastman, Jason D.; King, George W. et al. (October 2022). "The K2-3 System Revisited: Testing Photoevaporation and Core-powered Mass Loss with Three Small Planets Spanning the Radius Valley" (in en). The Astronomical Journal 164 (5): 172. doi:10.3847/1538-3881/ac7807. ISSN 1538-3881. Bibcode2022AJ....164..172D.