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Gliese 143 b

A Huge Neptunian Around a K-Star

The transit of a planet around Gliese 143 has been observed by the TESS space telescope and verified with ground-based obtained radial velocity data. Planet b's orbit near the habitable zone at a distance of 0.1932AU is eccentric (0.325) with twice the mass of Neptune or 30.63 times that of Earth and a period of 35.589 days. Its radius is estimated 0.228 that of Jupiter, or 2.6 that of Earth. The host is a K-class star with 76% the mass, 73% the radius and 0.197 the luminosity of the Sun, while its temperature is about the same.

Image credit: Gabriel Pérez/SMM (IAC)
 Posted on: 2018-12-13
Star Chart | DSS IR Image 🔗
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Overview

Planet DesignationTitleConstellationDistanceSMAPeriodMassRadiusYear
1Proxima bNearest Known ExoplanetCentaurus4.24ly0.04856AU11.1868d1.27⊕2016
2Barnard bSecond Closest Known ExoplanetOphiuchus5.9ly0.02294AU3.1533d3.23⊕2024
3Epsilon Eridani bAsteroid Belts and Controversal PlanetsEridanus10.48ly3.53AU2671d245⊕2000
4Ross 128 bThird Closest Known ExoplanetVirgo11.03ly0.0496AU9.8658d1.35⊕2017
5Tau Ceti ePlanet Needing ConfirmationCetus11.91ly0.538AU162.87d3.29⊕2017
6Luyten's Star bOnly 1.2 Light-Years Away from ProcyonCanis Minor12.2ly0.091101AU18.6498d2.89⊕2017
7Kapteyn's Star cOldest-known Cold ExoplanetPictor12.76ly0.311AU121.54d4.8⊕2014
8Wolf 1061 cTemperate Super-Earth or Super-MarsOphiuchus14.04ly0.089AU17.8719d3.41⊕2015
9Gliese 3323 bLittle Known in Habitable ZoneEridanus17.54ly0.03282AU5.3636d2.02⊕2017
10LTT 1445A bPlanet in Triple Red Dwarf SystemEridanus22.5ly0.022AU5.35876d2.2⊕1.18⊕2019
11Gliese 667C cEarth-like Planet in Triple Star SystemScorpius23.6ly0.125AU28.14d3.71⊕2013
12Gliese 1132 bHeat Planet with AtmosphereVela39.3ly0.0157AU1.62893d1.66⊕1.19⊕2015
13Trappist-1 dSmall but Most Earth-like Known PlanetAquarius39.5ly0.02227AU4.04922d0.297⊕0.78⊕2016
14LHS 1140 bA Massive Super-Earth Inside Habitable ZoneCetus40.67ly0.0946AU24.7372d6.64⊕1.72⊕2017
15Gliese 143 bA Huge Neptunian Around a K-StarReticulum53.2ly0.1915AU35.6125d30.63⊕2.61⊕2019
16TOI-270 bNearby M-Dwarf PlanetsDorado73.23ly0.03197AU3.36015d1.9⊕1.21⊕2019
17Gliese 3470 bEvaporating PlanetCancer95.5ly0.0355AU3.33665d13.4⊕4.57⊕2012
18K2-3 bSuper-Earths Trio in LeoLeo143.9ly0.0747AU10.0547d2.7⊕2.07⊕2015
19K2-288B bDetected by Citizen ScientistsTaurus226ly0.164AU31.3935d4⊕1.90⊕2018
20Kepler-186 fEarth-sized Cold Kepler PlanetCygnus582ly0.432AU129.944d1.4⊕1.16⊕2014

 

Red Dwarfs in a Nutshell

Most of the stars introduced on this page are 'Red Dwarfs'. Actually they represent the most common type of stars. About 73% of all stars in the Milky Way galaxy are dim red dwarfs, featuring less than half the solar surface temperature and low luminosity, but in turn high stellar activity, such as flares and hazardous radiation that can hit red dwarf planets hard potentially prohibiting formation of known lifeforms.

Given its minute energy emission, the habitable zone (HBZ, an imaginary ring where temperatures support liquid water) of a red dwarf is situated near the star, as are planets orbiting inside this zone. The gravitational pull of the star can tidally lock a nearby planet which then faces one hemisphere to the star while the other is enshrouded in darkness - like the Earth moon - the axial rotation period equals the orbital period.

Some densely populated systems, such as TRAPPIST-1, have several planets orbiting in close proximity in that an observer on a planet could see other planets larger than our moon in the sky. Also, the planet may have one or multiple moons themselves. In any case a truly impressive spectacle with fast changes.

 

 

Likelihood of life low because:

  • Low stellar energy flux
  • Tidal lock, tidal heating
  • Narrow habitable zone
  • Stellar variations, flares, stellar 'wind' of charged particles

 

On the other hand, if conditions are favorable:

  • A red dwarf is aged, known for longevity while some are rather inactive.
  • The lower the mass of a red dwarf the longer it will 'live', potentially trillions of years.
  • A planet mass big enough to hold an atmosphere capable of heat transfer.
  • A low orbit eccentricity for stable meteorological conditions.
  • Planets at the outer edge of the HBZ can retain water.
  • Planet may have a solid core and a magnetic field shield.
  • Lots of known lifeforms on Earth developed and are living under brutal conditions.

 

Observation

Due to their low visual luminosity no known red dwarf is visible by the naked eye, not even the nearest such as Proxima Centauri or the solitary Barnard's Star. Others, such as Gliese 667, are triple star systems but anywhere near visual magnitude

 

Image Credit: NASA/ESA/STScl