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Super-Earth

April 11, 2024

This article is about the planet type. For the fictional polity, see Helldivers and Helldivers II.

A Super-Earth is a type of exoplanet with a mass higher than Earth's, but substantially below those of the Solar System's ice giants, Uranus and Neptune, which are 14.5 and 17 times Earth's, respectively.[1] The term "super-Earth" refers only to the mass of the planet, and so does not imply anything about the surface conditions or habitability. The alternative term "gas dwarfs" may be more accurate for those at the higher end of the mass scale, although "mini-Neptunes" is a more common term.

Illustration of the inferred size of the super-Earth CoRoT-7b (center) in comparison with Earth and Neptune

Definition edit

 
Artist's impression of the super-Earth exoplanet LHS 1140b.[2]

In general, super-Earths are defined by their masses. The term does not imply temperatures, compositions, orbital properties, habitability, or environments. While sources generally agree on an upper bound of 10 Earth masses[1][3][4] (~69% of the mass of Uranus, which is the Solar System's giant planet with the least mass), the lower bound varies from 1[1] or 1.9[4] to 5,[3] with various other definitions appearing in the popular media.[5][6][7] The term "super-Earth" is also used by astronomers to refer to planets bigger than Earth-like planets (from 0.8 to 1.2 Earth-radius), but smaller than mini-Neptunes (from 2 to 4 Earth-radii).[8][9] This definition was made by the Kepler space telescope personnel.[10] Some authors further suggest that the term Super-Earth might be limited to rocky planets without a significant atmosphere, or planets that have not just atmospheres but also solid surfaces or oceans with a sharp boundary between liquid and atmosphere, which the four giant planets in the Solar System do not have.[11] Planets above 10 Earth masses are termed massive solid planets,[12] mega-Earths,[13][14] or gas giant planets,[15] depending on whether they are mostly rock and ice or mostly gas.

History and discoveries edit

 
Illustration of the inferred size of the super-Earth Kepler-10b (right) in comparison with Earth

First edit

 
Sizes of Kepler Planet Candidates – based on 2,740 candidates orbiting 2,036 stars as of November 4, 2013 (NASA)

The first super-Earths were discovered by Aleksander Wolszczan and Dale Frail around the pulsar PSR B1257+12 in 1992. The two outer planets (Poltergeist and Phobetor) of the system have masses approximately four times Earth—too small to be gas giants.

The first super-Earth around a main-sequence star was discovered by a team under Eugenio Rivera in 2005. It orbits Gliese 876 and received the designation Gliese 876 d (two Jupiter-sized gas giants had previously been discovered in that system). It has an estimated mass of 7.5 Earth masses and a very short orbital period of about 2 days. Due to the proximity of Gliese 876 d to its host star (a red dwarf), it may have a surface temperature of 430–650 kelvin[16] and be too hot to support liquid water.[17]

First in habitable zone edit

In April 2007, a team headed by Stéphane Udry based in Switzerland announced the discovery of two new super-Earths within the Gliese 581 planetary system,[18] both on the edge of the habitable zone around the star where liquid water may be possible on the surface. With Gliese 581c having a mass of at least 5 Earth masses and a distance from Gliese 581 of 0.073 astronomical units (6.8 million mi, 11 million km), it is on the "warm" edge of the habitable zone around Gliese 581 with an estimated mean temperature (without considering effects from an atmosphere) of −3 degrees Celsius with an albedo comparable to Venus and 40 degrees Celsius with an albedo comparable to Earth. Subsequent research suggested Gliese 581c had likely suffered a runaway greenhouse effect like Venus.

 
Mass and radius values for transiting super-Earths in context of other detected exoplanets and selected composition models. The "Fe" line defines planets made purely of iron, and "H2O" for those made of water. Those between the two lines, and closer to the Fe line, are most likely solid rocky planets, while those near or above the water line are more likely gas and/or liquid. Planets in the Solar System are on the chart, labeled with their astronomical symbols.

Others by year edit

2006 edit

Two further super-Earths were discovered in 2006: OGLE-2005-BLG-390Lb with a mass of 5.5 Earth masses, which was found by gravitational microlensing, and HD 69830 b with a mass of 10 Earth masses.[1]

2008 edit

The smallest super-Earth found as of 2008 was MOA-2007-BLG-192Lb. The planet was announced by astrophysicist David P. Bennett for the international MOA collaboration on June 2, 2008.[19][20] This planet has approximately 3.3 Earth masses and orbits a brown dwarf. It was detected by gravitational microlensing.

In June 2008, European researchers announced the discovery of three super-Earths around the star HD 40307, a star that is only slightly less massive than the Sun. Planets have at least the following minimum masses: 4.2, 6.7, and 9.4 times Earth's. The planets were detected by the radial velocity method by the HARPS (High Accuracy Radial Velocity Planet Searcher) in Chile.[21]

In addition, the same European research team announced a planet 7.5 times the mass of Earth orbiting the star HD 181433. This star also has a Jupiter-like planet that orbits it every three years.[22]

2009 edit

Planet COROT-7b, with a mass estimated at 4.8 Earth masses and an orbital period of only 0.853 days, was announced on 3 February 2009. The density estimate obtained for COROT-7b points to a composition including rocky silicate minerals similar to that of the Solar System's four inner planets, a new and significant discovery.[23] COROT-7b, discovered right after HD 7924 b, is the first super-Earth discovered that orbits a main sequence star that is G class or larger.[24]

The discovery of Gliese 581e with a minimum mass of 1.9 Earth masses was announced on 21 April 2009. It was at the time the smallest extrasolar planet discovered around a normal star and the closest in mass to Earth. Being at an orbital distance of just 0.03 AU and orbiting its star in just 3.15 days, it is not in the habitable zone,[25] and may have 100 times more tidal heating than Jupiter's volcanic satellite Io.[26]

A planet found in December 2009, GJ 1214 b, is 2.7 times as large as Earth and orbits a star much smaller and less luminous than the Sun. "This planet probably does have liquid water," said David Charbonneau, a Harvard professor of astronomy and lead author of an article on the discovery.[27] However, interior models of this planet suggest that under most conditions it does not have liquid water.[28]

By November 2009, a total of 30 super-Earths had been discovered, 24 of which were first observed by HARPS.[29]

2010 edit

Discovered on 5 January 2010, a planet HD 156668 b with a minimum mass of 4.15 Earth masses, is the least massive planet detected by the radial velocity method.[30] The only confirmed radial velocity planet smaller than this planet is Gliese 581e at 1.9 Earth masses (see above). On 24 August, astronomers using ESO's HARPS instrument announced the discovery of a planetary system with up to seven planets orbiting a Sun-like star, HD 10180, one of which, although not yet confirmed, has an estimated minimum mass of 1.35 ± 0.23 times that of Earth, which would be the lowest mass of any exoplanet found to date orbiting a main-sequence star.[31] Although unconfirmed, there is a 98.6% probability that this planet does exist.[32]

The National Science Foundation announced on 29 September the discovery of a fourth super-Earth (Gliese 581g) orbiting within the Gliese 581 planetary system. The planet has a minimum mass 3.1 times that of Earth and a nearly circular orbit at 0.146 AU with a period of 36.6 days, placing it in the middle of the habitable zone where liquid water could exist and midway between the planets c and d. It was discovered using the radial velocity method by scientists at the University of California at Santa Cruz and the Carnegie Institution of Washington.[33][34][35] However, the existence of Gliese 581 g has been questioned by another team of astronomers, and it is currently listed as unconfirmed at The Extrasolar Planets Encyclopaedia.[36]

2011 edit

On 2 February, the Kepler Space Observatory mission team released a list of 1235 extrasolar planet candidates, including 68 candidates of approximately "Earth-size" (Rp < 1.25 Re) and 288 candidates of "super-Earth-size" (1.25 Re < Rp < 2 Re).[37][38] In addition, 54 planet candidates were detected in the "habitable zone." Six candidates in this zone were less than twice the size of the Earth [namely: KOI 326.01 (Rp=0.85), KOI 701.03 (Rp=1.73), KOI 268.01 (Rp=1.75), KOI 1026.01 (Rp=1.77), KOI 854.01 (Rp=1.91), KOI 70.03 (Rp=1.96) – Table 6][37] A more recent study found that one of these candidates (KOI 326.01) is in fact much larger and hotter than first reported.[39] Based on the latest Kepler findings, astronomer Seth Shostak estimates "within a thousand light-years of Earth" there are "at least 30,000 of these habitable worlds."[40] Also based on the findings, the Kepler Team has estimated "at least 50 billion planets in the Milky Way" of which "at least 500 million" are in the habitable zone.[41]

On 17 August, a potentially habitable super-Earth HD 85512 b was found using the HARPS as well as a three super-Earth system 82 G. Eridani.[42] On HD 85512 b, it would be habitable if it exhibits more than 50% cloud cover.[43][44] Then less than a month later, a flood of 41 new exoplanets, including 10 super-Earths, were announced.[45]

On 5 December 2011, the Kepler space telescope discovered its first planet within the habitable zone or "Goldilocks region" of its Sun-like star. Kepler-22b is 2.4 times the radius of the Earth and occupies an orbit 15% closer to its star than the Earth to the Sun. This is compensated for, however, as the star, with a spectral type G5V, is slightly dimmer than the Sun (G2V). Thus, surface temperatures would still allow liquid water on its surface.

On 5 December 2011, the Kepler team announced that they had discovered 2,326 planetary candidates, of which 207 are similar in size to Earth, 680 are super-Earth-size, 1,181 are Neptune-size, 203 are Jupiter-size and 55 are larger than Jupiter. Compared to the February 2011 figures, the number of Earth-size and super-Earth-size planets increased by 200% and 140% respectively. Moreover, 48 planet candidates were found in the habitable zones of surveyed stars, marking a decrease from the February figure; this was due to the more stringent criteria in use in the December data.

 
Artist's impression of 55 Cancri e in front of its parent star.[46]

In 2011, a density of 55 Cancri e was calculated which turned out to be similar to Earth's. At the size of about 2 Earth radii, it was the largest planet until 2014, which was determined to lack a significant hydrogen atmosphere.[47][48]

On 20 December 2011, the Kepler team announced the discovery of the first Earth-size exoplanets, Kepler-20e and Kepler-20f, orbiting a Sun-like star, Kepler-20.

Planet Gliese 667 Cb (GJ 667 Cb) was announced by HARPS on 19 October 2009, together with 29 other planets, while Gliese 667 Cc (GJ 667 Cc) was included in a paper published on 21 November 2011. More detailed data on Gliese 667 Cc were published in early February 2012.

2012 edit

In September 2012, the discovery of two planets orbiting Gliese 163[49] was announced.[50][51] One of the planets, Gliese 163 c, about 6.9 times the mass of Earth and somewhat hotter, was considered to be within the habitable zone.[50][51]

2013 edit

On 7 January 2013, astronomers from the Kepler space observatory announced the discovery of Kepler-69c (formerly KOI-172.02), an Earth-like exoplanet candidate (1.5 times the radius of Earth) orbiting a star similar to the Sun in the habitable zone and possibly a "prime candidate to host alien life".[52]

In April 2013, using observations by NASA's Kepler mission team led by William Borucki, of the agency's Ames Research Center, found five planets orbiting in the habitable zone of a Sun-like star, Kepler-62, 1,200 light years from Earth. These new super-Earths have radii of 1.3, 1.4, 1.6, and 1.9 times that of Earth. Theoretical modelling of two of these super-Earths, Kepler-62e and Kepler-62f, suggests both could be solid, either rocky or rocky with frozen water.[53]

On 25 June 2013, three "super Earth" planets have been found orbiting a nearby star at a distance where life in theory could exist, according to a record-breaking tally announced on Tuesday by the European Southern Observatory. They are part of a cluster of as many as seven planets that circle Gliese 667C, one of three stars located a relatively close 22 light years from Earth in the constellation of Scorpio, it said. The planets orbit Gliese 667C in the so-called Goldilocks Zone — a distance from the star at which the temperature is just right for water to exist in liquid form rather than being stripped away by stellar radiation or locked permanently in ice.[citation needed]

2014 edit

In May 2014, previously discovered Kepler-10c was determined to have the mass comparable to Neptune (17 Earth masses). With the radius of 2.35 R🜨, it is currently the largest known planet likely to have a predominantly rocky composition.[54] At 17 Earth masses, it is well above the 10 Earth mass upper limit that is commonly used for the term 'super-Earth' so the term mega-Earth has been proposed.[14] However, in July 2017, more careful analysis of HARPS-N and HIRES data showed that Kepler-10c was much less massive than originally thought, instead around 7.37 (6.18 to 8.69) ME with a mean density of 3.14 g/cm3. Instead of a primarily rocky composition, the more accurately determined mass of Kepler-10c suggests a world made almost entirely of volatiles, mainly water.[55]

2015 edit

On 6 January 2015, NASA announced the 1000th confirmed exoplanet discovered by the Kepler space telescope. Three of the newly confirmed exoplanets were found to orbit within habitable zones of their related stars: two of the three, Kepler-438b and Kepler-442b, are near-Earth-size and likely rocky; the third, Kepler-440b, is a super-Earth.[56]

On 30 July 2015, Astronomy & Astrophysics said they found a planetary system with three super-Earths orbiting a bright, dwarf star. The four-planet system, dubbed HD 219134, had been found 21 light years from Earth in the M-shaped northern hemisphere of constellation Cassiopeia, but it is not in the habitable zone of its star. The planet with the shortest orbit is HD 219134 b, and is Earth's closest known rocky, and transiting, exoplanet.[57][58][59]

2016 edit

In February 2016, it was announced that NASA's Hubble Space Telescope had detected hydrogen and helium (and suggestions of hydrogen cyanide), but no water vapor, in the atmosphere of 55 Cancri e, the first time the atmosphere of a super-Earth exoplanet was analyzed successfully.[60]

In August 2016, astronomers announced the detection of Proxima b, an Earth-sized exoplanet that is in the habitable zone of the red dwarf star Proxima Centauri, the closest star to the Sun.[61] Due to its closeness to Earth, Proxima b may be a flyby destination for a fleet of interstellar StarChip spacecraft currently being developed by the Breakthrough Starshot project.[61]

2018 edit

In February 2018, K2-141b, a rocky ultra-short period planet (USP) Super-Earth, with a period of 0.28 days orbiting the host star K2-141 (EPIC 246393474) was reported.[62] Another Super-Earth, K2-155d, is discovered.[63]

In July 2018, the discovery of 40 Eridani b was announced.[64] At 16 light-years it is the closest super-Earth known, and its star is the second-brightest hosting a super-Earth.[65][64]

2019 edit

In July 2019, the discovery of GJ 357 d was announced. Thirty-one light-years from the Solar System, the planet is at least 6.1 ME.

2021 edit

In 2021, the exoplanet G 9-40 b was discovered.

2022 edit

In 2022, the discovery of a super-Earth around the red dwarf star Ross 508 was reported. Part of the planet's elliptical orbit takes it within the habitable zone.[66]

2024 edit

On 31 January 2024 NASA reported the discovery of a super-Earth called TOI-715 b located in the habitable zone of a red dwarf star about 137 light-years away.[67][68]

Solar System edit

Main article: Planet Nine

The Solar System contains no known super-Earths, because Earth is the largest terrestrial planet in the Solar System, and all larger planets have both at least 14 times the mass of Earth and thick gaseous atmospheres without well-defined rocky or watery surfaces; that is, they are either gas giants or ice giants, not terrestrial planets. In January 2016, the existence of a hypothetical super-Earth ninth planet in the Solar System, referred to as Planet Nine, was proposed as an explanation for the orbital behavior of six trans-Neptunian objects, but it is speculated to also be an ice giant like Uranus or Neptune.[69][70] A refined model in 2019 constrains it to around five Earth masses;[71] planets of this mass are probably mini-Neptunes.[72]

Characteristics edit

Density and bulk composition edit

 
Comparison of sizes of planets with different compositions[73]

Due to the larger mass of super-Earths, their physical characteristics may differ from Earth's; theoretical models for super-Earths provide four possible main compositions according to their density: low-density super-Earths are inferred to be composed mainly of hydrogen and helium (mini-Neptunes); super-Earths of intermediate density are inferred to either have water as a major constituent (ocean planets), or have a denser core enshrouded with an extended gaseous envelope (gas dwarf or sub-Neptune). A super-Earth of high density is believed to be rocky and/or metallic, like Earth and the other terrestrial planets of the Solar System. A super-Earth's interior could be undifferentiated, partially differentiated, or completely differentiated into layers of different composition. Researchers at Harvard Astronomy Department have developed user-friendly online tools to characterize the bulk composition of the super-Earths.[74][75] A study on Gliese 876 d by a team around Diana Valencia[1] revealed that it would be possible to infer from a radius measured by the transit method of detecting planets and the mass of the relevant planet what the structural composition is. For Gliese 876 d, calculations range from 9,200 km (1.4 Earth radii) for a rocky planet and very large iron core to 12,500 km (2.0 Earth radii) for a watery and icy planet. Within this range of radii the super-Earth Gliese 876 d would have a surface gravity between 1.9g and 3.3g (19 and 32 m/s2). However, this planet is not known to transit its host star.

The limit between rocky planets and planets with a thick gaseous envelope is calculated with theoretical models. Calculating the effect of the active XUV saturation phase of G-type stars over the loss of the primitive nebula-captured hydrogen envelopes in extrasolar planets, it's obtained that planets with a core mass of more than 1.5 Earth-mass (1.15 Earth-radius max.), most likely cannot get rid of their nebula captured hydrogen envelopes during their whole lifetime.[76] Other calculations point out that the limit between envelope-free rocky super-Earths and sub-Neptunes is around 1.75 Earth-radii, as 2 Earth-radii would be the upper limit to be rocky (a planet with 2 Earth-radii and 5 Earth-masses with a mean Earth-like core composition would imply that 1/200 of its mass would be in a H/He envelope, with an atmospheric pressure near to 2.0 GPa or 20,000 bar).[77] Whether or not the primitive nebula-captured H/He envelope of a super-Earth is entirely lost after formation also depends on the orbital distance. For example, formation and evolution calculations of the Kepler-11 planetary system show that the two innermost planets Kepler-11b and c, whose calculated mass is ≈2 M🜨 and between ≈5 and 6 M🜨 respectively (which are within measurement errors), are extremely vulnerable to envelope loss.[78] In particular, the complete removal of the primordial H/He envelope by energetic stellar photons appears almost inevitable in the case of Kepler-11b, regardless of its formation hypothesis.[78]

If a super-Earth is detectable by both the radial-velocity and the transit methods, then both its mass and its radius can be determined; thus its average bulk density can be calculated. The actual empirical observations are giving similar results as theoretical models, as it's found that planets larger than approximately 1.6 Earth-radius (more massive than approximately 6 Earth-masses) contain significant fractions of volatiles or H/He gas (such planets appear to have a diversity of compositions that is not well-explained by a single mass-radius relation as that found in rocky planets).[79][80] After measuring 65 super-Earths smaller than 4 Earth-radii, the empirical data points out that Gas Dwarves would be the most usual composition: there is a trend where planets with radii up to 1.5 Earth-radii increase in density with increasing radius, but above 1.5 radii the average planet density rapidly decreases with increasing radius, indicating that these planets have a large fraction of volatiles by volume overlying a rocky core.[81][82][83] Another discovery about exoplanets' composition is that about the gap or rarity observed for planets between 1.5 and 2.0 Earth-radii, which is explained by a bimodal formation of planets (rocky Super-Earths below 1.75 and sub-Neptunes with thick gas envelopes being above such radii).[9]

Additional studies, conducted with lasers at the Lawrence Livermore National Laboratory and the OMEGA laboratory at the University of Rochester, show that the magnesium-silicate internal regions of the planet would undergo phase changes under the immense pressures and temperatures of a super-Earth planet, and that the different phases of this liquid magnesium silicate would separate into layers.[citation needed]

Geologic activity edit

Further theoretical work by Valencia and others suggests that super-Earths would be more geologically active than Earth, with more vigorous plate tectonics due to thinner plates under more stress. In fact, their models suggested that Earth was itself a "borderline" case, just barely large enough to sustain plate tectonics.[84] However, other studies determined that strong convection currents in the mantle acting on strong gravity would make the crust stronger and thus inhibit plate tectonics. The planet's surface would be too strong for the forces of magma to break the crust into plates.[85]

Evolution edit

New research suggests that the rocky centres of super-Earths are unlikely to evolve into terrestrial rocky planets like the inner planets of the Solar System because they appear to hold on to their large atmospheres. Rather than evolving into a planet composed mainly of rock with a thin atmosphere, the small rocky core remains engulfed by its large hydrogen-rich envelope.[86][87]

Theoretical models show that Hot Jupiters and Hot Neptunes can evolve by hydrodynamic loss of their atmospheres to Mini-Neptunes (as it could be the Super-Earth GJ 1214 b),[88] or even to rocky planets known as chthonian planets (after migrating towards the proximity of their parent star). The amount of the outermost layers that is lost depends on the size and the material of the planet and the distance from the star.[78] In a typical system, a gas giant orbiting 0.02 AU around its parent star loses 5–7% of its mass during its lifetime, but orbiting closer than 0.015 AU can mean evaporation of the whole planet except for its core.[89][90]

The low densities inferred from observations imply that a fraction of the super-Earth population has substantial H/He envelopes, which may have been even more massive soon after formation.[91] Therefore, contrary to the terrestrial planets of the solar system, these super-Earths must have formed during the gas-phase of their progenitor protoplanetary disk.[92]

Temperatures edit

Since the atmospheres, albedo and greenhouse effects of super-Earths are unknown, the surface temperatures are unknown and generally only an equilibrium temperature is given. For example, the black-body temperature of the Earth is 255.3 K (−18 °C or 0 °F ).[93] It is the greenhouse gases that keep the Earth warmer. Venus has a black-body temperature of only 184.2 K (−89 °C or −128 °F ) even though Venus has a true temperature of 737 K (464 °C or 867 °F ).[94] Though the atmosphere of Venus traps more heat than Earth's, NASA lists the black-body temperature of Venus based on the fact that Venus has an extremely high albedo (Bond albedo 0.90, Visual geometric albedo 0.67),[94] giving it a lower black body temperature than the more absorbent (lower albedo) Earth.

Magnetic field edit

Earth's magnetic field results from its flowing liquid metallic core, but in super-Earths the mass can produce high pressures with large viscosities and high melting temperatures, which could prevent the interiors from separating into different layers and so result in undifferentiated coreless mantles. Magnesium oxide, which is rocky on Earth, can be a liquid metal at the pressures and temperatures found in super-Earths and could generate a magnetic field in the mantles of super-Earths.[95] That said, super-Earth magnetic fields are yet to be detected observationally.

Habitability edit

Further information: Planetary habitability and astrobiology

According to one hypothesis,[96] super-Earths of about two Earth masses may be conducive to life. The higher surface gravity would lead to a thicker atmosphere, increased surface erosion and hence a flatter topography. The result could be an "archipelago planet" of shallow oceans dotted with island chains ideally suited for biodiversity. A more massive planet of two Earth masses would also retain more heat within its interior from its initial formation much longer, sustaining plate tectonics (which is vital for regulating the carbon cycle and hence the climate) for longer. The thicker atmosphere and stronger magnetic field would also shield life on the surface against harmful cosmic rays.[97]

See also edit

References edit

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External links edit

  •   Media related to Super-Earths at Wikimedia Commons
  • Why is the Earth called a unique planet in our solar system ?

April 11, 2024
super, earth, this, article, about, planet, type, fictional, polity, helldivers, helldivers, type, exoplanet, with, mass, higher, than, earth, substantially, below, those, solar, system, giants, uranus, neptune, which, times, earth, respectively, term, super, . This article is about the planet type For the fictional polity see Helldivers and Helldivers II A Super Earth is a type of exoplanet with a mass higher than Earth s but substantially below those of the Solar System s ice giants Uranus and Neptune which are 14 5 and 17 times Earth s respectively 1 The term super Earth refers only to the mass of the planet and so does not imply anything about the surface conditions or habitability The alternative term gas dwarfs may be more accurate for those at the higher end of the mass scale although mini Neptunes is a more common term Illustration of the inferred size of the super Earth CoRoT 7b center in comparison with Earth and Neptune Contents 1 Definition 2 History and discoveries 2 1 First 2 2 First in habitable zone 2 3 Others by year 2 3 1 2006 2 3 2 2008 2 3 3 2009 2 3 4 2010 2 3 5 2011 2 3 6 2012 2 3 7 2013 2 3 8 2014 2 3 9 2015 2 3 10 2016 2 3 11 2018 2 3 12 2019 2 3 13 2021 2 3 14 2022 2 3 15 2024 3 Solar System 4 Characteristics 4 1 Density and bulk composition 4 2 Geologic activity 4 3 Evolution 4 4 Temperatures 4 5 Magnetic field 4 6 Habitability 5 See also 6 References 7 External linksDefinition edit nbsp Artist s impression of the super Earth exoplanet LHS 1140b 2 In general super Earths are defined by their masses The term does not imply temperatures compositions orbital properties habitability or environments While sources generally agree on an upper bound of 10 Earth masses 1 3 4 69 of the mass of Uranus which is the Solar System s giant planet with the least mass the lower bound varies from 1 1 or 1 9 4 to 5 3 with various other definitions appearing in the popular media 5 6 7 The term super Earth is also used by astronomers to refer to planets bigger than Earth like planets from 0 8 to 1 2 Earth radius but smaller than mini Neptunes from 2 to 4 Earth radii 8 9 This definition was made by the Kepler space telescope personnel 10 Some authors further suggest that the term Super Earth might be limited to rocky planets without a significant atmosphere or planets that have not just atmospheres but also solid surfaces or oceans with a sharp boundary between liquid and atmosphere which the four giant planets in the Solar System do not have 11 Planets above 10 Earth masses are termed massive solid planets 12 mega Earths 13 14 or gas giant planets 15 depending on whether they are mostly rock and ice or mostly gas History and discoveries edit nbsp Illustration of the inferred size of the super Earth Kepler 10b right in comparison with EarthFirst edit nbsp Sizes of Kepler Planet Candidates based on 2 740 candidates orbiting 2 036 stars as of November 4 2013 NASA The first super Earths were discovered by Aleksander Wolszczan and Dale Frail around the pulsar PSR B1257 12 in 1992 The two outer planets Poltergeist and Phobetor of the system have masses approximately four times Earth too small to be gas giants The first super Earth around a main sequence star was discovered by a team under Eugenio Rivera in 2005 It orbits Gliese 876 and received the designation Gliese 876 d two Jupiter sized gas giants had previously been discovered in that system It has an estimated mass of 7 5 Earth masses and a very short orbital period of about 2 days Due to the proximity of Gliese 876 d to its host star a red dwarf it may have a surface temperature of 430 650 kelvin 16 and be too hot to support liquid water 17 First in habitable zone edit In April 2007 a team headed by Stephane Udry based in Switzerland announced the discovery of two new super Earths within the Gliese 581 planetary system 18 both on the edge of the habitable zone around the star where liquid water may be possible on the surface With Gliese 581c having a mass of at least 5 Earth masses and a distance from Gliese 581 of 0 073 astronomical units 6 8 million mi 11 million km it is on the warm edge of the habitable zone around Gliese 581 with an estimated mean temperature without considering effects from an atmosphere of 3 degrees Celsius with an albedo comparable to Venus and 40 degrees Celsius with an albedo comparable to Earth Subsequent research suggested Gliese 581c had likely suffered a runaway greenhouse effect like Venus nbsp Mass and radius values for transiting super Earths in context of other detected exoplanets and selected composition models The Fe line defines planets made purely of iron and H2O for those made of water Those between the two lines and closer to the Fe line are most likely solid rocky planets while those near or above the water line are more likely gas and or liquid Planets in the Solar System are on the chart labeled with their astronomical symbols Others by year edit 2006 edit Two further super Earths were discovered in 2006 OGLE 2005 BLG 390Lb with a mass of 5 5 Earth masses which was found by gravitational microlensing and HD 69830 b with a mass of 10 Earth masses 1 2008 edit The smallest super Earth found as of 2008 was MOA 2007 BLG 192Lb The planet was announced by astrophysicist David P Bennett for the international MOA collaboration on June 2 2008 19 20 This planet has approximately 3 3 Earth masses and orbits a brown dwarf It was detected by gravitational microlensing In June 2008 European researchers announced the discovery of three super Earths around the star HD 40307 a star that is only slightly less massive than the Sun Planets have at least the following minimum masses 4 2 6 7 and 9 4 times Earth s The planets were detected by the radial velocity method by the HARPS High Accuracy Radial Velocity Planet Searcher in Chile 21 In addition the same European research team announced a planet 7 5 times the mass of Earth orbiting the star HD 181433 This star also has a Jupiter like planet that orbits it every three years 22 2009 edit Planet COROT 7b with a mass estimated at 4 8 Earth masses and an orbital period of only 0 853 days was announced on 3 February 2009 The density estimate obtained for COROT 7b points to a composition including rocky silicate minerals similar to that of the Solar System s four inner planets a new and significant discovery 23 COROT 7b discovered right after HD 7924 b is the first super Earth discovered that orbits a main sequence star that is G class or larger 24 The discovery of Gliese 581e with a minimum mass of 1 9 Earth masses was announced on 21 April 2009 It was at the time the smallest extrasolar planet discovered around a normal star and the closest in mass to Earth Being at an orbital distance of just 0 03 AU and orbiting its star in just 3 15 days it is not in the habitable zone 25 and may have 100 times more tidal heating than Jupiter s volcanic satellite Io 26 A planet found in December 2009 GJ 1214 b is 2 7 times as large as Earth and orbits a star much smaller and less luminous than the Sun This planet probably does have liquid water said David Charbonneau a Harvard professor of astronomy and lead author of an article on the discovery 27 However interior models of this planet suggest that under most conditions it does not have liquid water 28 By November 2009 a total of 30 super Earths had been discovered 24 of which were first observed by HARPS 29 2010 edit Discovered on 5 January 2010 a planet HD 156668 b with a minimum mass of 4 15 Earth masses is the least massive planet detected by the radial velocity method 30 The only confirmed radial velocity planet smaller than this planet is Gliese 581e at 1 9 Earth masses see above On 24 August astronomers using ESO s HARPS instrument announced the discovery of a planetary system with up to seven planets orbiting a Sun like star HD 10180 one of which although not yet confirmed has an estimated minimum mass of 1 35 0 23 times that of Earth which would be the lowest mass of any exoplanet found to date orbiting a main sequence star 31 Although unconfirmed there is a 98 6 probability that this planet does exist 32 The National Science Foundation announced on 29 September the discovery of a fourth super Earth Gliese 581g orbiting within the Gliese 581 planetary system The planet has a minimum mass 3 1 times that of Earth and a nearly circular orbit at 0 146 AU with a period of 36 6 days placing it in the middle of the habitable zone where liquid water could exist and midway between the planets c and d It was discovered using the radial velocity method by scientists at the University of California at Santa Cruz and the Carnegie Institution of Washington 33 34 35 However the existence of Gliese 581 g has been questioned by another team of astronomers and it is currently listed as unconfirmed at The Extrasolar Planets Encyclopaedia 36 2011 edit On 2 February the Kepler Space Observatory mission team released a list of 1235 extrasolar planet candidates including 68 candidates of approximately Earth size Rp lt 1 25 Re and 288 candidates of super Earth size 1 25 Re lt Rp lt 2 Re 37 38 In addition 54 planet candidates were detected in the habitable zone Six candidates in this zone were less than twice the size of the Earth namely KOI 326 01 Rp 0 85 KOI 701 03 Rp 1 73 KOI 268 01 Rp 1 75 KOI 1026 01 Rp 1 77 KOI 854 01 Rp 1 91 KOI 70 03 Rp 1 96 Table 6 37 A more recent study found that one of these candidates KOI 326 01 is in fact much larger and hotter than first reported 39 Based on the latest Kepler findings astronomer Seth Shostak estimates within a thousand light years of Earth there are at least 30 000 of these habitable worlds 40 Also based on the findings the Kepler Team has estimated at least 50 billion planets in the Milky Way of which at least 500 million are in the habitable zone 41 On 17 August a potentially habitable super Earth HD 85512 b was found using the HARPS as well as a three super Earth system 82 G Eridani 42 On HD 85512 b it would be habitable if it exhibits more than 50 cloud cover 43 44 Then less than a month later a flood of 41 new exoplanets including 10 super Earths were announced 45 On 5 December 2011 the Kepler space telescope discovered its first planet within the habitable zone or Goldilocks region of its Sun like star Kepler 22b is 2 4 times the radius of the Earth and occupies an orbit 15 closer to its star than the Earth to the Sun This is compensated for however as the star with a spectral type G5V is slightly dimmer than the Sun G2V Thus surface temperatures would still allow liquid water on its surface On 5 December 2011 the Kepler team announced that they had discovered 2 326 planetary candidates of which 207 are similar in size to Earth 680 are super Earth size 1 181 are Neptune size 203 are Jupiter size and 55 are larger than Jupiter Compared to the February 2011 figures the number of Earth size and super Earth size planets increased by 200 and 140 respectively Moreover 48 planet candidates were found in the habitable zones of surveyed stars marking a decrease from the February figure this was due to the more stringent criteria in use in the December data nbsp Artist s impression of 55 Cancri e in front of its parent star 46 In 2011 a density of 55 Cancri e was calculated which turned out to be similar to Earth s At the size of about 2 Earth radii it was the largest planet until 2014 which was determined to lack a significant hydrogen atmosphere 47 48 On 20 December 2011 the Kepler team announced the discovery of the first Earth size exoplanets Kepler 20e and Kepler 20f orbiting a Sun like star Kepler 20 Planet Gliese 667 Cb GJ 667 Cb was announced by HARPS on 19 October 2009 together with 29 other planets while Gliese 667 Cc GJ 667 Cc was included in a paper published on 21 November 2011 More detailed data on Gliese 667 Cc were published in early February 2012 2012 edit In September 2012 the discovery of two planets orbiting Gliese 163 49 was announced 50 51 One of the planets Gliese 163 c about 6 9 times the mass of Earth and somewhat hotter was considered to be within the habitable zone 50 51 2013 edit On 7 January 2013 astronomers from the Kepler space observatory announced the discovery of Kepler 69c formerly KOI 172 02 an Earth like exoplanet candidate 1 5 times the radius of Earth orbiting a star similar to the Sun in the habitable zone and possibly a prime candidate to host alien life 52 In April 2013 using observations by NASA s Kepler mission team led by William Borucki of the agency s Ames Research Center found five planets orbiting in the habitable zone of a Sun like star Kepler 62 1 200 light years from Earth These new super Earths have radii of 1 3 1 4 1 6 and 1 9 times that of Earth Theoretical modelling of two of these super Earths Kepler 62e and Kepler 62f suggests both could be solid either rocky or rocky with frozen water 53 On 25 June 2013 three super Earth planets have been found orbiting a nearby star at a distance where life in theory could exist according to a record breaking tally announced on Tuesday by the European Southern Observatory They are part of a cluster of as many as seven planets that circle Gliese 667C one of three stars located a relatively close 22 light years from Earth in the constellation of Scorpio it said The planets orbit Gliese 667C in the so called Goldilocks Zone a distance from the star at which the temperature is just right for water to exist in liquid form rather than being stripped away by stellar radiation or locked permanently in ice citation needed 2014 edit In May 2014 previously discovered Kepler 10c was determined to have the mass comparable to Neptune 17 Earth masses With the radius of 2 35 R it is currently the largest known planet likely to have a predominantly rocky composition 54 At 17 Earth masses it is well above the 10 Earth mass upper limit that is commonly used for the term super Earth so the term mega Earth has been proposed 14 However in July 2017 more careful analysis of HARPS N and HIRES data showed that Kepler 10c was much less massive than originally thought instead around 7 37 6 18 to 8 69 ME with a mean density of 3 14 g cm3 Instead of a primarily rocky composition the more accurately determined mass of Kepler 10c suggests a world made almost entirely of volatiles mainly water 55 2015 edit On 6 January 2015 NASA announced the 1000th confirmed exoplanet discovered by the Kepler space telescope Three of the newly confirmed exoplanets were found to orbit within habitable zones of their related stars two of the three Kepler 438b and Kepler 442b are near Earth size and likely rocky the third Kepler 440b is a super Earth 56 On 30 July 2015 Astronomy amp Astrophysics said they found a planetary system with three super Earths orbiting a bright dwarf star The four planet system dubbed HD 219134 had been found 21 light years from Earth in the M shaped northern hemisphere of constellation Cassiopeia but it is not in the habitable zone of its star The planet with the shortest orbit is HD 219134 b and is Earth s closest known rocky and transiting exoplanet 57 58 59 2016 edit In February 2016 it was announced that NASA s Hubble Space Telescope had detected hydrogen and helium and suggestions of hydrogen cyanide but no water vapor in the atmosphere of 55 Cancri e the first time the atmosphere of a super Earth exoplanet was analyzed successfully 60 In August 2016 astronomers announced the detection of Proxima b an Earth sized exoplanet that is in the habitable zone of the red dwarf star Proxima Centauri the closest star to the Sun 61 Due to its closeness to Earth Proxima b may be a flyby destination for a fleet of interstellar StarChip spacecraft currently being developed by the Breakthrough Starshot project 61 2018 edit In February 2018 K2 141b a rocky ultra short period planet USP Super Earth with a period of 0 28 days orbiting the host star K2 141 EPIC 246393474 was reported 62 Another Super Earth K2 155d is discovered 63 In July 2018 the discovery of 40 Eridani b was announced 64 At 16 light years it is the closest super Earth known and its star is the second brightest hosting a super Earth 65 64 2019 edit In July 2019 the discovery of GJ 357 d was announced Thirty one light years from the Solar System the planet is at least 6 1 ME 2021 edit In 2021 the exoplanet G 9 40 b was discovered 2022 edit In 2022 the discovery of a super Earth around the red dwarf star Ross 508 was reported Part of the planet s elliptical orbit takes it within the habitable zone 66 2024 edit On 31 January 2024 NASA reported the discovery of a super Earth called TOI 715 b located in the habitable zone of a red dwarf star about 137 light years away 67 68 Solar System editMain article Planet Nine The Solar System contains no known super Earths because Earth is the largest terrestrial planet in the Solar System and all larger planets have both at least 14 times the mass of Earth and thick gaseous atmospheres without well defined rocky or watery surfaces that is they are either gas giants or ice giants not terrestrial planets In January 2016 the existence of a hypothetical super Earth ninth planet in the Solar System referred to as Planet Nine was proposed as an explanation for the orbital behavior of six trans Neptunian objects but it is speculated to also be an ice giant like Uranus or Neptune 69 70 A refined model in 2019 constrains it to around five Earth masses 71 planets of this mass are probably mini Neptunes 72 Characteristics editDensity and bulk composition edit nbsp Comparison of sizes of planets with different compositions 73 Due to the larger mass of super Earths their physical characteristics may differ from Earth s theoretical models for super Earths provide four possible main compositions according to their density low density super Earths are inferred to be composed mainly of hydrogen and helium mini Neptunes super Earths of intermediate density are inferred to either have water as a major constituent ocean planets or have a denser core enshrouded with an extended gaseous envelope gas dwarf or sub Neptune A super Earth of high density is believed to be rocky and or metallic like Earth and the other terrestrial planets of the Solar System A super Earth s interior could be undifferentiated partially differentiated or completely differentiated into layers of different composition Researchers at Harvard Astronomy Department have developed user friendly online tools to characterize the bulk composition of the super Earths 74 75 A study on Gliese 876 d by a team around Diana Valencia 1 revealed that it would be possible to infer from a radius measured by the transit method of detecting planets and the mass of the relevant planet what the structural composition is For Gliese 876 d calculations range from 9 200 km 1 4 Earth radii for a rocky planet and very large iron core to 12 500 km 2 0 Earth radii for a watery and icy planet Within this range of radii the super Earth Gliese 876 d would have a surface gravity between 1 9g and 3 3g 19 and 32 m s2 However this planet is not known to transit its host star The limit between rocky planets and planets with a thick gaseous envelope is calculated with theoretical models Calculating the effect of the active XUV saturation phase of G type stars over the loss of the primitive nebula captured hydrogen envelopes in extrasolar planets it s obtained that planets with a core mass of more than 1 5 Earth mass 1 15 Earth radius max most likely cannot get rid of their nebula captured hydrogen envelopes during their whole lifetime 76 Other calculations point out that the limit between envelope free rocky super Earths and sub Neptunes is around 1 75 Earth radii as 2 Earth radii would be the upper limit to be rocky a planet with 2 Earth radii and 5 Earth masses with a mean Earth like core composition would imply that 1 200 of its mass would be in a H He envelope with an atmospheric pressure near to 2 0 GPa or 20 000 bar 77 Whether or not the primitive nebula captured H He envelope of a super Earth is entirely lost after formation also depends on the orbital distance For example formation and evolution calculations of the Kepler 11 planetary system show that the two innermost planets Kepler 11b and c whose calculated mass is 2 M and between 5 and 6 M respectively which are within measurement errors are extremely vulnerable to envelope loss 78 In particular the complete removal of the primordial H He envelope by energetic stellar photons appears almost inevitable in the case of Kepler 11b regardless of its formation hypothesis 78 If a super Earth is detectable by both the radial velocity and the transit methods then both its mass and its radius can be determined thus its average bulk density can be calculated The actual empirical observations are giving similar results as theoretical models as it s found that planets larger than approximately 1 6 Earth radius more massive than approximately 6 Earth masses contain significant fractions of volatiles or H He gas such planets appear to have a diversity of compositions that is not well explained by a single mass radius relation as that found in rocky planets 79 80 After measuring 65 super Earths smaller than 4 Earth radii the empirical data points out that Gas Dwarves would be the most usual composition there is a trend where planets with radii up to 1 5 Earth radii increase in density with increasing radius but above 1 5 radii the average planet density rapidly decreases with increasing radius indicating that these planets have a large fraction of volatiles by volume overlying a rocky core 81 82 83 Another discovery about exoplanets composition is that about the gap or rarity observed for planets between 1 5 and 2 0 Earth radii which is explained by a bimodal formation of planets rocky Super Earths below 1 75 and sub Neptunes with thick gas envelopes being above such radii 9 Additional studies conducted with lasers at the Lawrence Livermore National Laboratory and the OMEGA laboratory at the University of Rochester show that the magnesium silicate internal regions of the planet would undergo phase changes under the immense pressures and temperatures of a super Earth planet and that the different phases of this liquid magnesium silicate would separate into layers citation needed Geologic activity edit Further theoretical work by Valencia and others suggests that super Earths would be more geologically active than Earth with more vigorous plate tectonics due to thinner plates under more stress In fact their models suggested that Earth was itself a borderline case just barely large enough to sustain plate tectonics 84 However other studies determined that strong convection currents in the mantle acting on strong gravity would make the crust stronger and thus inhibit plate tectonics The planet s surface would be too strong for the forces of magma to break the crust into plates 85 Evolution edit New research suggests that the rocky centres of super Earths are unlikely to evolve into terrestrial rocky planets like the inner planets of the Solar System because they appear to hold on to their large atmospheres Rather than evolving into a planet composed mainly of rock with a thin atmosphere the small rocky core remains engulfed by its large hydrogen rich envelope 86 87 Theoretical models show that Hot Jupiters and Hot Neptunes can evolve by hydrodynamic loss of their atmospheres to Mini Neptunes as it could be the Super Earth GJ 1214 b 88 or even to rocky planets known as chthonian planets after migrating towards the proximity of their parent star The amount of the outermost layers that is lost depends on the size and the material of the planet and the distance from the star 78 In a typical system a gas giant orbiting 0 02 AU around its parent star loses 5 7 of its mass during its lifetime but orbiting closer than 0 015 AU can mean evaporation of the whole planet except for its core 89 90 The low densities inferred from observations imply that a fraction of the super Earth population has substantial H He envelopes which may have been even more massive soon after formation 91 Therefore contrary to the terrestrial planets of the solar system these super Earths must have formed during the gas phase of their progenitor protoplanetary disk 92 Temperatures edit Since the atmospheres albedo and greenhouse effects of super Earths are unknown the surface temperatures are unknown and generally only an equilibrium temperature is given For example the black body temperature of the Earth is 255 3 K 18 C or 0 F 93 It is the greenhouse gases that keep the Earth warmer Venus has a black body temperature of only 184 2 K 89 C or 128 F even though Venus has a true temperature of 737 K 464 C or 867 F 94 Though the atmosphere of Venus traps more heat than Earth s NASA lists the black body temperature of Venus based on the fact that Venus has an extremely high albedo Bond albedo 0 90 Visual geometric albedo 0 67 94 giving it a lower black body temperature than the more absorbent lower albedo Earth Magnetic field edit Earth s magnetic field results from its flowing liquid metallic core but in super Earths the mass can produce high pressures with large viscosities and high melting temperatures which could prevent the interiors from separating into different layers and so result in undifferentiated coreless mantles Magnesium oxide which is rocky on Earth can be a liquid metal at the pressures and temperatures found in super Earths and could generate a magnetic field in the mantles of super Earths 95 That said super Earth magnetic fields are yet to be detected observationally Habitability edit Further information Planetary habitability and astrobiology According to one hypothesis 96 super Earths of about two Earth masses may be conducive to life The higher surface gravity would lead to a thicker atmosphere increased surface erosion and hence a flatter topography The result could be an archipelago planet of shallow oceans dotted with island chains ideally suited for biodiversity A more massive planet of two Earth masses would also retain more heat within its interior from its initial formation much longer sustaining plate tectonics which is vital for regulating the carbon cycle and hence the climate for longer The thicker atmosphere and stronger magnetic field would also shield life on the surface against harmful cosmic rays 97 See also editEarth analog Planet with environment similar to Earth s Extraterrestrial liquid water Liquid water naturally occurring outside Earth Hot Neptune Planet with a mass similar to Uranus or Neptune orbiting close to its star Super Neptune Planet larger than Neptune but smaller than Saturn List of nearest terrestrial exoplanet candidates Sub Earth Planet smaller than Earth TOI 1452 b Super Earth orbiting TOI 1452References edit a b c d e Valencia V Sasselov D D O Connell R J 2007 Radius and structure models of the first super earth planet The Astrophysical Journal 656 1 545 551 arXiv astro ph 0610122 Bibcode 2007ApJ 656 545V doi 10 1086 509800 S2CID 17656317 Newly Discovered Exoplanet May be Best Candidate in Search for Signs of Life Transiting rocky super Earth found in 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