A 2015 review concluded that the
exoplanets Kepler-62f,
Kepler-186f and
Kepler-442b were likely the best candidates for being potentially habitable. These are at a distance of 990, 490 and 1,120
light-years away, respectively. Of these, Kepler-186f is closest in size to Earth with 1.2 times Earth's radius, and it is located towards the outer edge of the habitable zone around its
red dwarf star. Among
nearest terrestrial exoplanet candidates,
Tau Ceti e is 11.9 light-years away. It is in the inner edge of its planetary system's habitable zone, giving it an estimated average surface temperature of .
Early findings The first discoveries of extrasolar planets in the HZ occurred just a few years after the first extrasolar planets were discovered. However, these early detections were all gas giant-sized, and many were in eccentric orbits. Despite this, studies indicate the possibility of large, Earth-like moons around these planets supporting liquid water. One of the first discoveries was
70 Virginis b, a gas giant initially nicknamed "Goldilocks" due to it being neither "too hot" nor "too cold". Later study revealed temperatures analogous to Venus, ruling out any potential for liquid water.
16 Cygni Bb, also discovered in 1996, has an extremely eccentric orbit that spends only part of its time in the HZ, such an orbit would causes extreme
seasonal effects. In spite of this, simulations have suggested that a sufficiently large companion could support surface water year-round.
Gliese 876 b, discovered in 1998, and
Gliese 876 c, discovered in 2001, are both gas giants discovered in the habitable zone around
Gliese 876 that may also have large moons. Another gas giant,
Upsilon Andromedae d was discovered in 1999 orbiting Upsilon Andromidae's habitable zone. Announced on April 4, 2001,
HD 28185 b is a gas giant found to orbit entirely within its star's circumstellar habitable zone and has a low orbital eccentricity, comparable to that of Mars in the Solar System. Tidal interactions suggest it could harbor habitable Earth-mass satellites in orbit around it for many billions of years, though it is unclear whether such satellites could form in the first place.
HD 69830 d, a gas giant with 17 times the mass of Earth, was found in 2006 orbiting within the circumstellar habitable zone of
HD 69830, 41 light years away from Earth. The following year,
55 Cancri f was discovered within the HZ of its host star
55 Cancri A. Hypothetical satellites with sufficient mass and composition are thought to be able to support liquid water at their surfaces.
Super-Earths in a habitable zone The
Kepler space telescope discovered that most Sun-like stars have close-in planets in the size range between
Earth and
Neptune. These planets have been called
super-Earths but this term has been characterized as deceptive. Subsequent study has shown they have
hydrogen gas atmospheres and they fall into two categories: the larger ones have retain atmospheres but the smaller ones are stipped cores. Models that simulate this
bimodal distribution predict that stellar radiation perhaps combined with heat from planetary cooling drive off the atmosphere causing some of these exoplanets to appear smaller. In general, these exoplanets are not in the habitable zone. Moreover, the processes which strip the hydrogen atmosphere from this type of exoplanet is unlikely to operate on planets in the habitable zone. Thus among this type of exoplanet, those orbital periods closer to the habitable zone more closely resemble
Neptune.
Kepler-22 b, discovered in December 2011 by the Kepler space probe, is the first
transiting exoplanet discovered around a
Sun-like star. With a radius 2.4 times that of Earth, Kepler-22b has been predicted by some to be an ocean planet.
Gliese 667 Cc, discovered in 2011 but announced in 2012, is a super-Earth orbiting in the circumstellar habitable zone of
Gliese 667 C. It is one of the most Earth-like planets known.
Gliese 163 c, discovered in September 2012 in orbit around the red dwarf
Gliese 163 is located 49
light years from Earth. The planet has 6.9 Earth masses and 1.8–2.4 Earth radii, and with its close orbit receives 40 percent more stellar radiation than Earth, leading to surface temperatures of about °
C.
HD 40307 g, a candidate planet tentatively discovered in November 2012, is in the circumstellar habitable zone of
HD 40307. In December 2012,
Tau Ceti e and
Tau Ceti f were found in the circumstellar habitable zone of
Tau Ceti, a Sun-like star 12 light years away. Although more massive than Earth, they are among the least massive planets found to date orbiting in the habitable zone; however, Tau Ceti f, like HD 85512 b, did not fit the new circumstellar habitable zone criteria established by the 2013 Kopparapu study. It is now considered as uninhabitable.
Near Earth-sized planets and Solar analogs (17 April 2014) Recent discoveries have uncovered planets that are thought to be similar in size or mass to Earth. "Earth-sized" ranges are typically defined by mass. The lower range used in many definitions of the super-Earth class is 1.9 Earth masses; likewise, sub-Earths range up to the size of Venus (~0.815 Earth masses). An upper limit of 1.5 Earth radii is also considered, given that above the average planet density rapidly decreases with increasing radius, indicating these planets have a significant fraction of volatiles by volume overlying a rocky core. A genuinely Earth-like planet – an
Earth analog or "Earth twin" – would need to meet many conditions beyond size and mass; such properties are not observable using current technology. A
solar analog (or "solar twin") is a star that resembles the Sun. No solar twin with an exact match as that of the Sun has been found. However, some stars are nearly identical to the Sun and are considered solar twins. An exact solar twin would be a G2V star with a 5,778 K temperature, be 4.6 billion years old, with the correct
metallicity and a 0.1%
solar luminosity variation. Stars with an age of 4.6 billion years are at the most stable state. Proper metallicity and size are also critical to low luminosity variation. Using data collected by NASA's
Kepler space telescope and the
W. M. Keck Observatory, scientists have estimated that 22% of solar-type stars in the Milky Way galaxy have Earth-sized planets in their habitable zone. On 7 January 2013, astronomers from the Kepler team announced the discovery of
Kepler-69c (formerly
KOI-172.02), an Earth-size
exoplanet candidate (1.7 times the radius of Earth) orbiting
Kepler-69, a star similar to the Sun, in the HZ and expected to offer habitable conditions. The discovery of two planets orbiting in the habitable zone of
Kepler-62, by the Kepler team was announced on April 19, 2013. The planets, named
Kepler-62e and
Kepler-62f, are likely solid planets with sizes 1.6 and 1.4 times the radius of Earth, respectively. With a radius estimated at 1.1 Earth,
Kepler-186f, discovery announced in April 2014, is the closest yet size to Earth of an exoplanet confirmed by the transit method though its mass remains unknown and its parent star is not a Solar analog.
Kapteyn b, discovered in June 2014, was thought to is a possible rocky world of about 4.8 Earth masses and about 1.5 Earth radii orbiting the habitable zone of the red subdwarf
Kapteyn's Star, 12.8 light-years away. However, further analysis concluded that this claim was an artefact of stellar rotation and activity. 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.
Kepler-452b, announced on 23 July 2015 is 50% bigger than Earth, likely rocky and takes approximately 385 Earth days to orbit the habitable zone of its
G-class (solar analog) star
Kepler-452. The discovery of a system of three tidally locked planets orbiting the habitable zone of an ultracool dwarf star,
TRAPPIST-1, was announced in May 2016. The discovery is considered significant because it dramatically increases the possibility of smaller, cooler, more numerous and closer stars possessing habitable planets. Two potentially habitable planets, discovered by the K2 mission in July 2016 orbiting around the M dwarf
K2-72 around 227 light years from the Sun:
K2-72c and
K2-72e are both of similar size to Earth and receive similar amounts of stellar radiation. Announced on the 20 April 2017,
LHS 1140b is a super-dense
super-Earth 39 light years away, 6.6 times Earth's mass and 1.4 times radius, its star 15% the mass of the Sun but with much less observable stellar flare activity than most M dwarfs. The planet is one of few observable by both transit and radial velocity that's mass is confirmed with an atmosphere may be studied. Discovered by radial velocity in June 2017, with approximately three times the mass of Earth,
Luyten b orbits within the habitable zone of
Luyten's Star just 12.2 light-years away. At 11 light-years away, the second closest planet,
Ross 128 b, was announced in November 2017 following a decade's radial velocity study of relatively "quiet" red dwarf star Ross 128. At 1.35 times Earth's mass, is it roughly Earth-sized and likely rocky in composition. Discovered in March 2018,
K2-155d is about 1.64 times the radius of Earth, is likely rocky and orbits in the habitable zone of its
red dwarf star 203 light years away. One of the earliest discoveries by the
Transiting Exoplanet Survey Satellite (TESS) announced on July 31, 2019, is a Super-Earth planet
GJ 357 d orbiting the outer edge of a red dwarf 31 light years away.
K2-18b is an exoplanet 124 light-years away, orbiting in the habitable zone of the
K2-18, a red dwarf. This planet is significant for water vapor found in its atmosphere; this was announced on September 17, 2019. In September 2020, astronomers identified 24
superhabitable planet (planets better than Earth) contenders, from among more than 4000 confirmed
exoplanets at present, based on
astrophysical parameters, as well as the
natural history of
known life forms on the
Earth. In the case of planets orbiting in the HZs of red dwarf stars, the extremely close distances to the stars cause
tidal locking, an important factor in habitability. For a tidally locked planet, the
sidereal day is as long as the
orbital period, causing one side to permanently face the host star and the other side to face away. In the past, such tidal locking was thought to cause extreme heat on the star-facing side and bitter cold on the opposite side, making many red dwarf planets uninhabitable; however, three-dimensional climate models in 2013 showed that the side of a red dwarf planet facing the host star could have extensive cloud cover, increasing its
bond albedo and reducing significantly temperature differences between the two sides.
Moons Planetary mass
natural satellites have the potential to be habitable as well. However, these bodies need to fulfill additional parameters, in particular being located within the circumplanetary habitable zones of their host planets. Red dwarfs that have masses less than 20% of that of the Sun cannot have habitable moons around giant planets, as the small size of the circumstellar habitable zone would put a habitable moon so close to the star that it would be stripped from its host planet. In such a system, a moon close enough to its host planet to maintain its orbit would have tidal heating so intense as to eliminate any prospects of habitability. and . Life on a planetary object orbiting outside HZ might hibernate on the cold side as the planet approaches the
apastron where the planet is coolest and become active on approach to the
periastron when the planet is sufficiently warm. ==Alternative habitable zones==