Gliese 876 c

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Gliese 876 c
Jkv.Gliese876.c.png
An artist's impression of Gliese 876 c
Discovery [1] [2]
Discovered by California and Carnegie Planet Search Team
Discovery site Lick and Keck Observatories
Discovery dateJanuary 9, 2001
Doppler spectroscopy
Orbital characteristics [3]
Epoch 2,450,602.09311  BJD
0.136044+0.000021
−0.000022  AU
Eccentricity 0.2571±0.0019
30.0972+0.0071
−0.0073 d
292.55+1
−0.99 º
Inclination 53.06±0.85 º [note 1]
51.09+0.77
−0.78 º
Semi-amplitude 87.46+0.3
−0.29  m/s
Star Gliese 876
Physical characteristics [3]
Mass 265.6±2.7  M🜨 [note 2]

Gliese 876 c is an exoplanet orbiting the red dwarf Gliese 876, taking about 30 days to complete an orbit. The planet was discovered in April 2001 and is the second planet in order of increasing distance from its star.

Contents

Discovery

At the time of discovery, Gliese 876 was already known to host an extrasolar planet designated Gliese 876 b. On January 9, 2001, it was announced that further analysis of the star's radial velocity had revealed the existence of a second planet in the system, which was designated Gliese 876 c. [2] [1] The orbital period of Gliese 876 c was found to be exactly half that of the outer planet, which meant that the radial velocity signature of the second planet was initially interpreted as a higher eccentricity of the orbit of Gliese 876 b.

Host star

The planet orbits a (M-type) star named Gliese 876. The star has a mass of 0.33 M and a radius of around 0.36 R. It has a surface temperature of 3350 K and is 2.55 billion years old. In comparison, the Sun is about 4.6 billion years old [4] and has a surface temperature of 5778 K. [5]

Orbit and mass

The orbits of the planets of Gliese 876. Gliese 876 c is the second planet from the star Gliese 876. Gliese876Orbits.svg
The orbits of the planets of Gliese 876. Gliese 876 c is the second planet from the star Gliese 876.

Gliese 876 c is in a 1:2:4 Laplace resonance with the outer planets Gliese 876 b and Gliese 876 e: for every orbit of planet e, planet b completes two orbits and planet c completes four. [6] This leads to strong gravitational interactions between the planets, [7] causing the orbital elements to change rapidly as the orbits precess. [6] [8] This is the second known example of a Laplace resonance, the first being Jupiter's moons Io, Europa and Ganymede.

The orbital semimajor axis is only 0.13 AU, around a third of the average distance between Mercury and the Sun, and is more eccentric than the orbit of any of the major planets of the Sun's Solar System. [6] Despite this, it is located in the inner regions of the system's habitable zone, since Gliese 876 is such an intrinsically faint star. [9]

A limitation of the radial velocity method used to detect Gliese 876 c is that only a lower limit on the planet's mass can be obtained. This is because the measured mass value depends on the inclination of the orbit, which is not determined by the radial velocity measurements. However, in a resonant system such as Gliese 876, gravitational interactions between the planets can be used to determine the true masses. Using this method, the inclination of the orbit can be determined, revealing the planet's true mass to be 0.72 times that of Jupiter. [6]

Characteristics

Based on its high mass, Gliese 876 c is likely to be a gas giant with no solid surface. Since it was detected indirectly through its gravitational effects on the star, properties such as its radius, composition, and temperature are unknown. Assuming a composition similar to Jupiter and an environment close to chemical equilibrium, the planet is predicted to have a cloudless upper atmosphere. [10]

Gliese 876 c lies at the inner edge of the system's habitable zone. While the prospects for life on gas giants are unknown, it might be possible for a large moon of the planet to provide a habitable environment. Unfortunately tidal interactions between a hypothetical moon, the planet, and the star could destroy moons massive enough to be habitable over the lifetime of the system. [11] In addition it is unclear whether such moons could form in the first place. [12]

This planet, like b and e, has likely migrated inward. [13]

See also

Notes

  1. The inclination assumes the planets in the system are coplanar, long-term orbital stability simulations strongly favor low mutual inclinations.
  2. Uncertainties in the planetary masses and semimajor axes do not take into account the uncertainty in the mass of the star.

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<span class="mw-page-title-main">Gliese 876</span> Star in the constellation Aquarius

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<span class="mw-page-title-main">55 Cancri c</span> Extrasolar planet in the constellation Cancer

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<span class="mw-page-title-main">Gliese 876 d</span> Super-Earth orbiting Gliese 876

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<span class="mw-page-title-main">Gliese 876 b</span> Extrasolar planet orbiting Gliese 876

Gliese 876 b is an exoplanet orbiting the red dwarf Gliese 876. It completes one orbit in approximately 61 days. Discovered in June 1998, Gliese 876 b was the first planet to be discovered orbiting a red dwarf.

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<span class="mw-page-title-main">GJ 3021 b</span> Extrasolar planet in the constrellation Hydrus

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Gliese 849 b is an extrasolar planet approximately 29 light years away in the constellation of Aquarius. It is the first long-period Jupiter-like planet discovered around a red dwarf, announced in August 2006 by the California and Carnegie Planet Search team using the radial velocity technique. The previously longest-period Jupiter-like planet around a red dwarf was Gliese 876 b. There are, however, two disproven longer period Jupiter-like planets around Lalande 21185. There are indications of a possible second companion. The planet's mass is less than that of Jupiter, though only the minimum mass is known. The distance of the planet is 2.35 AU and it takes 5.17 years to revolve in a circular orbit.

<span class="mw-page-title-main">Gliese 876 e</span> Exoplanet orbiting the star Gliese 876

Gliese 876 e is an exoplanet orbiting the star Gliese 876 in the constellation of Aquarius. It is in a 1:2:4 Laplace resonance with the planets Gliese 876 c and Gliese 876 b: for each orbit of planet e, planet b completes two orbits and planet c completes four. This configuration is the second known example of a Laplace resonance after Jupiter's moons Io, Europa and Ganymede. Its orbit takes 124 days to complete.

<span class="mw-page-title-main">Discoveries of exoplanets</span> Detecting planets located outside the Solar System

An exoplanet is a planet located outside the Solar System. The first evidence of an exoplanet was noted as early as 1917, but was not recognized as such until 2016; no planet discovery has yet come from that evidence. What turned out to be the first detection of an exoplanet was published among a list of possible candidates in 1988, though not confirmed until 2003. The first confirmed detection came in 1992, with the discovery of terrestrial-mass planets orbiting the pulsar PSR B1257+12. The first confirmation of an exoplanet orbiting a main-sequence star was made in 1995, when a giant planet was found in a four-day orbit around the nearby star 51 Pegasi. Some exoplanets have been imaged directly by telescopes, but the vast majority have been detected through indirect methods, such as the transit method and the radial-velocity method. As of 1 September 2023, there are 5,506 confirmed exoplanets in 4,065 planetary systems, with 878 systems having more than one planet. This is a list of the most notable discoveries.

References

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