Extrasolar planet
An extrasolar planet, or exoplanet, is a planet beyond the Solar System, orbiting around other stars. As of September 2008, 309 exoplanets have been detected and confirmed
Extrasolar planets became a subject of scientific investigation in the mid-19th century. Astronomers generally supposed that some existed, but it was not known how common they were and how similar they were to the planets of the Solar System. The first confirmed detections were made in the 1990s; since 2000, more than 15 have been discovered every year. The frequency of detection is increasing with 61 planets detected in 2007. It is estimated that at least 10% of sun-like stars have planets, and the true proportion may be much higher.
Currently, Gliese 581 d, the third planet of the red dwarf star Gliese 581 (approximately 20 light years from Earth), appears to be the best example yet discovered of a possible terrestrial exoplanet which orbits close to the habitable zone of space surrounding its star. Going by strict terms, it appears to reside outside the "Goldilocks Zone", but the greenhouse effect may raise the planet's surface temperature to that which would support liquid water.
Retracted discoveries
Unconfirmed until 1988, extrasolar planets have long been assumed as plausible, and speculation on planets circling around the fixed stars dates to at least the early 18th century, with Isaac Newton's General Scholium (1713), which has "And if the fixed Stars are the centers of other like systems, these, being form'd by the like wise counsel, must be all subject to the dominion of One" (trans. Motte 1729).
Claims about detection of exoplanets have been made from the 19th century. Some of the earliest involve the binary star 70 Ophiuchi. In 1855, Capt. W. S. Jacob at the East India Company's Madras Observatory reported that orbital anomalies made it "highly probable" that there was a "planetary body" in this system.
In 1991, Andrew Lyne, M. Bailes and S.L. Shemar claimed to have discovered a pulsar planet in orbit around PSR 1829-10, using pulsar timing variations.
Confirmed discoveries
The first published discovery to have received subsequent confirmation was made in 1988 by the Canadian astronomers Bruce Campbell, G. A. H. Walker, and S. Yang.
The following year, additional observations were published that supported the reality of the planet orbiting Gamma Cephei,
In early 1992, radio astronomers Aleksander Wolszczan and Dale Frail announced the discovery of planets around another pulsar, PSR 1257+12.
On October 6 1995, Michel Mayor and Didier Queloz of the University of Geneva announced the first definitive detection of an exoplanet orbiting an ordinary main-sequence star (51 Pegasi).
To date, 309 exoplanets have been found,
Detection methods
Planets are extremely faint light sources compared to their parent stars. At visible wavelengths, they usually have less than a millionth of their parent star's brightness. In addition to the intrinsic difficulty of detecting such a faint light source, the parent star causes a glare that washes it out.
For those reasons, current telescopes can only directly image exoplanets under exceptional circumstances. Specifically, it may be possible when the planet is especially large (considerably larger than Jupiter), widely separated from its parent star, and hot so that it emits intense infrared radiation.
The vast majority of known extrasolar planets have been discovered through indirect methods:
 Astrometry: Astrometry consists of precisely measuring a star's position in the sky and observing the ways in which that position changes over time. If the star has a planet, then the gravitational influence of the planet will cause the star itself to move in a tiny circular or elliptical orbit about their common center of mass (see video on the right).
Radial velocity or Doppler method: Variations in the speed with which the star moves towards or away from Earth — that is, variations in the radial velocity of the star with respect to Earth — can be deduced from the displacement in the parent star's spectral lines due to the Doppler effect[An especially simple and inexpensive method for measuring radial velocity is “externally dispersed interferometry.” See the following Web site: http://www.spectralfringe.org/EDI/ . See also: Erskine, Edelstein, Harbeck and Lloyd, “Externally dispersed interferometry for planetary studies,” in Techniques and Instrumentation for Detection of Exoplanets II, Daniel R. Coulter, ed., Proceedings of the SPIE *, vol. 5905, pages 249-260 (2005). (14 page extract). (* SPIE = Society of Photo-optical Instrumentation Engineers; renamed: International Society for Optical Engineering)]. This has been by far the most productive technique used.
Pulsar timing: A pulsar (the small, ultradense remnant of a star that has exploded as a supernova) emits radio waves extremely regularly as it rotates. Slight anomalies in the timing of its observed radio pulses can be used to track changes in the pulsar's motion caused by the presence of planets.
Transit method: If a planet crosses (or transits) in front of its parent star's disk, then the observed brightness of the star drops by a small amount. The amount by which the star dims depends on its size and on the size of the planet.
Gravitational microlensing: Microlensing occurs when the gravitational field of a star acts like a lens, magnifying the light of a distant background star. Possible planets orbiting the foreground star can cause detectable anomalies in the lensing event light curve.
Circumstellar disks: Disks of space dust surround many stars, and this dust can be detected because it absorbs ordinary starlight and re-emits it as infrared radiation. Features in dust disks may suggest the presence of planets.
Eclipsing binary: In an eclipsing double star system, the planet can be detected by finding variability in minima as it goes back and forth. It is the most reliable method for detecting planets in binary star systems.
Orbital phase: Like the phase of the Moon and Venus, extrasolar planets also have phases. Orbital phases depends on inclination of the orbit. By studying orbital phases scientists can calculate particle sizes in the atmospheres of planets.
Polarimetry: Stellar light becomes polarized when it interacts with atmospheric molecules, which could be detected with a polarimeter. So far one planet has been studied by this method.
Not counting a few exceptions, all known extrasolar planet candidates have been found using ground-based telescopes. However, many of the methods can yield better results if the observing telescope is located above the restless atmosphere. COROT (launched in December 2006) is the only active space mission dedicated to extrasolar planet search. Hubble Space Telescope has also found or confirmed a few planets. There are many planned or proposed space missions such as Kepler, New Worlds Mission, Darwin, Space Interferometry Mission, Terrestrial Planet Finder, and PEGASE.
Nomenclature
The most common way of naming extrasolar planets is almost similar to the naming of binary stars, except a lowercase letter is used for the planet (while an uppercase letter is for stars). A lowercase letter is placed after the star name, starting with "b" for the first planet found in the system (51 Pegasi b). The next planet found in the system could be labeled the next letter in the alphabet. For instance, any more planets found around 51 Pegasi would be cataloged as "51 Pegasi c" and then "51 Pegasi d", and so on. If two planets are discovered around the same time, the closest one to the star gets the next letter, while the last planet would get the last letter. For example, in the Gliese 876 system, the most recently discovered planet is referred to as Gliese 876 d, despite the fact that it is closer to the star than Gliese 876 b and Gliese 876 c. The suffix "a" was intended to refer specifically to the primary, as opposed to the system as a whole, but this did not catch on. The planet 55 Cancri f is currently the first and only planet to have "f" in its name (being the fifth planet found in the 55 Cancri system), with no letters currently beyond "f" (the highest letter currently in use).
Only two planetary systems have planets that are named "unusual". Before the discovery of 51 Pegasi b in 1995, two pulsar planets (PSR B1257+12B and PSR B1257+12C) were discovered from pulsar timing of their dead star. Being that there was no official way of naming planets at the time, they were called "B" and "C" (similar to how planets are named today). However, uppercase letters were used, most likely because of the way binary stars were named. When a third planet was discovered, it was designated PSR B1257+12A (simply because the planet was closer than the other two).
If the planet orbits in a non-circumbinary system, the letter of the star is added to the name. If the planet orbits the primary star of the system, and the secondary stars were either discovered after the planet or are relatively far form the primary star and planet, the name is usually omitted. For example, Tau Boötis b orbits in a binary system, but because the secondary star was both discovered after the planet and very far from the primary star and planet, the term "Tau Boötis Ab" is rarely to never used. However (in the cases of 16 Cygni Bb and 83 Leonis Bb), if the planet orbits a secondary star of the system, the star's name is always used. Some planets have received unofficial (informal) names that can be compared to the planets of the Solar system. The most noted planets that have been given names include: Osiris (HD 209458 b), Bellerophon (51 Pegasi b), and Methuselah (PSR B1620-26 b). The International Astronomical Union (IAU) currently has no plans to officially name extrasolar planets, considering it impractical,[Planets Around Other Stars. Retrieved on 2008-07-17] but the idea may work if only a few planets get officially named (similar to how only a few stars have traditional names and always use it).
Definition
According to the International Astronomical Union's working definition of "planet," a planet must orbit a star.
There have also been reports of free-floating planetary-mass objects (ones not orbiting any star), sometimes called "rogue planets" or "interstellar planets". Such objects are not discussed in this article since they are outside the working definition of "planet". For more information, see rogue planet.
Stellar characteristics
Most known exoplanets orbit stars roughly similar to our own Sun, that is, main-sequence stars of spectral categories F, G, or K. One reason is simply that planet search programs have tended to concentrate on such stars. But even after taking this into account, statistical analysis suggests that lower-mass stars (red dwarfs, of spectral category M) are either less likely to have planets or have planets that are themselves of lower mass and hence harder to detect.
Stars are composed mainly of the light elements hydrogen and helium. They also contain a small fraction of heavier elements such as iron, and this fraction is referred to as a star's metallicity. Stars of higher metallicity are much more likely to have planets, and the planets they have tend to be more massive than those of lower-metallicity stars.
In careful spectroscopic observations it is found that rotational velocity drops off abruptly after spectral class F2 stars. It should be noted that the Sun is a G2 Class star (which is, after F2.) Ninety eight percent of the angular momentum of the solar system derives from the orbital motions of the planets. In an isolated system, angular momentum must be conserved, so, of course, the remaining 2 percent lies with the sun. Therefore it seems that the angular momentum of the Sun has been transferred to the planets, that would otherwise cause the Sun to rotate 50 times faster than it currently does (approximately 2 km/sec.) If this hypothesis is correct, slowly rotating stars are so because a large portion of their angular momentum has been transferred elsewhere, perhaps to orbiting planets. Since ninety three percent of all main sequence stars are later than F2, it would seem that the bulk of stars in the galaxy may have planets, unless alternative methods of angular momentum transfer are proven likely.
Measured properties
Most known extrasolar planet candidates have been discovered using indirect methods and therefore only certain physical and orbital parameters can be determined. The radial velocity method provides all orbital elements except for inclination, including orbital period, semi-major axis, Orbital eccentricity, angular distance, longitude of periastron, time of periastron, and semi-amplitude. The unknown inclination results in unknown mass and therefore usually only the minimum mass is given. In some cases it may be a much more massive object such as brown dwarf or red dwarf star instead. However, if the planet's orbit is nearly perpendicular to sky (inclination close to 90°), the planet can be seen transiting its star and therefore its true mass and radius can be measured. Furthermore, astrometric observations and dynamical studies in multiple planet systems can be used to constrain the mass of a planet.
Spectroscopic measurements during the transit can be used to study a transiting planet's atmospheric composition.
Selection effect
The vast majority of exoplanets found so far have high masses. As of August 2008, all but twelve of them have more than ten times the mass of Earth.[ Many are considerably more massive than Jupiter, the most massive planet in the Solar System. However, these high masses are in large part due to an observational selection effect: all detection methods are much more likely to discover massive planets. This bias makes statistical analysis difficult, but it appears that lower-mass planets are actually more common than higher-mass ones, at least within a broad mass range that includes all giant planets. In addition, the fact that astronomers have found several planets only a few times more massive than Earth, despite the great difficulty of detecting them, indicates that such planets are fairly common.][ According to 2008 data from the Harps (High Accuracy Radial velocity Planet Searcher) spectrograph instrument in Chile, about one star in 14 may have gas giant planets, while one in three probably has rocky planets of below 30 Earth masses.][BBC News online: Trio of 'super-Earths' discovered, June 16, 2008, 16:07 GMT. page accessed June 17, 2008]
Many exoplanets orbit much closer around their parent star than any planet in our own Solar System orbits around the Sun. Again, that is mainly an observational selection effect. The radial-velocity method is most sensitive to planets with such small orbits. Astronomers were initially very surprised by these "hot Jupiters," but it is now clear that most exoplanets (or at least, most high-mass exoplanets) have much larger orbits, some located in habitable zones where suitable for liquid water and life. It appears plausible that in most exoplanetary systems, there are one or two giant planets with orbits comparable in size to those of Jupiter and Saturn in our own Solar System.
The eccentricity of an orbit is a measure of how elliptical (elongated) it is. Most known exoplanets have quite eccentric orbits. This is not an observational selection effect, since a planet can be detected about a star equally well regardless of the eccentricity of its orbit. The prevalence of elliptical orbits is a major puzzle, since current theories of planetary formation strongly suggest planets should form with circular (that is, non-eccentric) orbits. One possible theory is that small companions such as T dwarfs (methane-bearing brown dwarfs) can hide in such solar systems and can cause the orbits of planets to be extreme.
Unanswered questions
Many unanswered questions remain about the properties of exoplanets, such as the details of their composition and the likelihood of possessing moons. The recent discovery that several surveyed exoplanets lacked water showed that there is still much more to be learned about the properties of exoplanets. Another question is whether they might support life. Several planets do have orbits in their parent star's habitable zone, where it should be possible for Earth-like conditions to prevail. Most of those planets are giant planets more similar to Jupiter than to Earth; if these planets have large moons, the moons might be a more plausible abode of life. Detection of life (other than an advanced civilization) at interstellar distances, however, is a tremendously challenging technical task that will not be feasible for many years, even if such life is commonplace.
First discoveries
The first milestone in the discovery of extrasolar planets was in 1992, when Wolszczan and Frail published results in the journal Nature indicating that pulsar planets existed around PSR B1257+12.[ Wolszczan had discovered the millisecond pulsar in question in 1990 at the Arecibo radio observatory. These were the first exoplanets ever verified, and they are still considered highly unusual in that they orbit a pulsar.]
The first verified discovery of an exoplanet (51 Pegasi b) orbiting a main sequence star (51 Pegasi) was announced by Michel Mayor and Didier Queloz in Nature on October 6, 1995.[ Astronomers were initially surprised by this "hot Jupiter" but soon set out to find other similar planets with great success.]
Other notable discoveries
Since that time, other notable discoveries have included:
1996 to 2006
;1996, 47 Ursae Majoris b: This Jupiter-like planet was the first long-period planet discovered, orbiting at 2.11 AU from the star with the eccentricity of 0.049. There is a second companion that orbits at 3.39 AU with the eccentricity of 0.220 ± 0.028 and a period of 2190 ± 460 days.
;1998, Gliese 876 b: The first planet found that orbits around a red dwarf star (Gliese 876). It orbits closer to the star than Mercury is to the Sun. More planets have subsequently been discovered closer to the star.
;1999, Upsilon Andromedae: The first multiple-planetary system to be discovered around a main sequence star. It contains three planets, all are Jupiter-like. Planets b, c, d are announced in 1996, 1999, and 1999 respectively. Their masses are 0.687, 1.97, and 3.93 MJ; they orbit at 0.0595, 0.830, and 2.54 AU respectively.
;1999, HD 209458 b: This exoplanet, originally discovered with the radial-velocity method, became the first exoplanet to be seen transiting its parent star. The transit detection conclusively confirmed the existence of the planets suspected to be responsible for the radial velocity measurements.
;2001, HD 209458 b: Astronomers using the Hubble Space Telescope announced that they had detected the atmosphere of HD 209458 b. They found the spectroscopic signature of sodium in the atmosphere, but at a smaller intensity than expected, suggesting that high clouds obscure the lower atmospheric layers.
;2001, Iota Draconis b: The first planet discovered around the giant star Iota Draconis, an orange giant. This provides evidence for a survival and behavior of planetary systems around giant stars. Giant stars have pulsations that can mimic the presence of planets. The planet is very massive and has a very eccentric orbit. It orbits the average distance of 27.5% further from its star than Earth to the Sun.
;2003, PSR B1620-26 b: On July 10, using information obtained from the Hubble Space Telescope, a team of scientists led by Steinn Sigurdsson confirmed the oldest extrasolar planet yet. The planet is located in the globular star cluster M4, about 5,600 light years from Earth in the constellation Scorpius. This is the only planet known to orbit around a stellar binary; one of the stars in the binary is a pulsar and the other is a white dwarf. The planet has a mass twice that of Jupiter, and is estimated to be 13 billion years old.
;2004, Mu Arae c: In August, a planet orbiting Mu Arae with a mass of approximately 14 times that of the Earth was discovered with the European Southern Observatory's HARPS spectrograph. Depending on its composition, it is the first published "hot Neptune" or "super-Earth".
;2004, 2M1207 b: The first planet around a brown dwarf. The planet is also the first to be directly imaged (in infrared). It has 5 Jupiter mass while other estimates give a slightly lower mass. It orbits at 55 AU from the brown dwarf. The brown dwarf mass is only 25 Jupiters. The temperature of gas giant planet is very hot (1250 K), mostly due to gravitational contraction.
;2005, Gliese 876 d: In June, a third planet orbiting the red dwarf star Gliese 876 was announced. With a mass estimated at 7.5 times that of Earth, it is currently the second-lightest known exoplanet that orbits an ordinary main-sequence star. It may be rocky in composition. The planet orbits at 0.021 AU with a period of 1.94 days.
;2005, HD 149026 b: In July, a planet with the largest core known was announced. The planet, HD 149026 b, orbits the star HD 149026, and has a core that was then estimated to be 70 Earth masses (as of 2008, 80-110), accounting for at least two-thirds of the planet's mass.
;2006, OGLE-2005-BLG-390Lb: On January 25, the discovery of OGLE-2005-BLG-390Lb was announced. This is the most distant and probably the coldest exoplanet found to date. It is believed that it orbits a red dwarf star around 21,500 light years from Earth, towards the center of the Milky Way galaxy. It was discovered using gravitational microlensing, and is estimated to have a mass of 5.5 times that of Earth, making it the least massive known exoplanet to orbit an ordinary main-sequence star. Prior to this discovery, the few known exoplanets with comparably low masses had only been discovered on orbits very close to their parent stars, but this planet is estimated to have a relatively wide separation of 2.6 AU from its parent star.
;2006, HD 69830: A planetary system with three Neptune-mass planets. It is the first triple planetary system around a Sun-like star without any Jupiter-like planets. All three planets were announced on May 18 by Lovis. All three orbit within 1 AU. The planets b, c, d have masses of 10, 12, and 18 Earths respectively. The outermost planet d appears to be in the habitable zone, sheparding the asteroid belt.
2007 to 2008
;2007, HD 209458 b and HD 189733 b: On February 21, 2007, NASA and Nature released news that HD 209458 b and HD 189733 b were the first two extrasolar planets to have their spectra directly observed.[NASA's Spitzer First To Crack Open Light of Faraway Worlds Spitzer.caltech.edu 2007-02-21 Retrieved on 2008-07-17][A spectrum of an extrasolar planet Nature.com 2007-02-01 Nature 445, 892-895 (22 February 2007); doi:10.1038/nature05636 Retrieved on 2008-07-17] This was long seen as the first mechanism by which extrasolar but non-intelligent life forms could be searched for, by way of influence on a planet's atmosphere. A group of investigators led by Dr. Jeremy Richardson of NASA's Goddard Space Flight Center were first to publication, in the February 22 issue of Nature. Richardson et al. spectrally measured HD 209458 b's atmosphere in the range of 7.5 to 13.2 micrometres. The results defied theoretical expectations in several ways. The spectrum had been predicted to have a peak at 10 micrometres which would have indicated water vapor in the atmosphere, but such a peak was absent, indicating no detectable water vapor. Another, unpredicted peak was observed at 9.65 micrometres, which the investigators attributed to clouds of silicate dust, a phenomenon not previously observed. Another unpredicted peak occurred at 7.78 micrometres, which the investigators did not have an explanation for. A separate team led by Mark Swain of the Jet Propulsion Laboratory also separately analyzed the Richardson team's data and indicated that their findings were similar. They had submitted their results to Astrophysical Journal Letters. A team led by Carl Grillmair of NASA's Spitzer Science Center made the observations of HD 189733 b, and their results were pending publication in Astrophysical Journal Letters at the time of the news release. On July 11, 2007, the findings by the Spitzer Science Center were published in the Nature: Spectral imprints of water vapor were found by the Spitzer Space Telescope, thus representing the first solid evidence of water on an extrasolar planet.['Clear Signs of Water' on Distant Planet at Space.com]
;2007, Gliese 581 c: Announced on Space.com on April 24, 2007, at 4:23pm ET, it has been determined that this exoplanet could support liquid water and possibly life.[von Bloh et al. (2007) ] indicate that the planet likely suffers from a runaway greenhouse effect similar to Venus, rendering the presence of liquid water impossible. These studies suggest that the third planet in the system,Gliese 581 d, is more likely to be habitable. Seth Shostak, a senior astronomer with the SETI institute, stated that on two previous occasions, Gliese 581 was looked at as a potential candidate for extraterrestrial intelligence, but both examinations revealed no proof. The confirmation of the exoplanet's position was determined using the HARPS instrument on the European Southern Observatory's 3.6 meter telescope, by applying the radial velocity detection method.
;2007, Gliese 436 b : This planet was one of the first Neptune-mass planets discovered, in August 2004. In May 2007, a transit was found, which revealed it as the least massive transiting planet as of yet (22 times that of Earth) and also the smallest. Its density is consistent with a large core of an exotic form of solid water called "hot ice," which would exist, despite the planet's high temperatures, because the planet's gravity causes water to be extremely dense.
;2007, XO-3b : A 13.24 Jupiter-mass planet is the most massive transiting planet ever found, and most massive extrasolar planet found to date, just above the brown dwarf limit at 13.00 MJ. The planet would have radius of 1.92 times Jupiter, the largest of any known extrasolar planets. The planet takes only 3.19 days to orbit the star. The orbit has an unusually high eccentricity (0.22) for such a short period planet.
;2007, TrES-4 : The largest-diameter and lowest-density exoplanet to date, TrES-4 is 1.7 times Jupiter's diameter but only 0.84 times its mass, giving it a density of just 0.2 grams per cubic centimeter — about the same as balsa wood. It orbits its primary closely and is therefore quite hot, but stellar heating alone does not appear to explain its large size.
;2008, OGLE-2006-BLG-109Lb and OGLE-2006-BLG-109Lc: On February 14 the discovery of the, until now, most similar Jupiter-Saturn planetary system constellation was announced, with the ratios of mass, distance to their star and orbiting time similar to that of Jupiter-Saturn. This can be important for possible life in a solar system as Jupiter and Saturn have a stabilizing effect to the habitable zone by sweeping away large asteroids from the habitable zone.
;2008, HD 189733 b: On March 20 follow up studies to the first spectral analyses of an extrasolar planet were published in the scientific journal Nature, announcing evidence of an organic molecule found on an extrasolar planet for the first time. In 2007 water vapor was already detected in the spectrum of HD 189733 b, but new analyses showed not only water vapor, but also methane existing in the atmosphere of the giant gas planet. Although conditions on HD 189733 b are too harsh to harbor life, it still is the first time a key molecule for organic life was found on an extrasolar planet.
;2008, HD 40307: On June 16, Michel Mayor announced a confirmed planetary system with three super-Earths orbiting this K-type star. Their masses are between 4 to 9 Earth masses and with periods between 4 to 20 days. It is speculated that this may be the first multi-planetary system without any known gas giants. All three terrestrial planets were discovered by the HARPS spectrograph in La Silla, Chile.
Classifications
Appearance of extrasolar planets
Pulsar planet
Super-Earth
Hot Jupiter
Eccentric Jupiter
Gas giant
Terrestrial planet
Chthonian planet
Ocean planet
Desert planet
Systems
Binary star
Hypothetical planet
Interstellar planet
Planetary system
Extrasolar moon
Observatories
Methods of detecting extrasolar planets
Geneva Extrasolar Planet Search
Anglo-Australian Planet Search
California & Carnegie Planet Search
Systemic (amateur extrasolar planet search project)
HATNet Project (HAT)
Trans-Atlantic Exoplanet Survey (TrES)
SuperWASP (WASP)
XO Telescope (XO)
Optical Gravitational Lensing Experiment (OGLE)
Search for Extraterrestrial Intelligence (SETI)
Missions
COROT — current ESA mission to detect extrasolar planets — launched in 2006
Kepler Mission — launch in 2009
PEGASE — launch between 2010-2012
Space Interferometry Mission — launch between 2015-2016
New Worlds Mission — launch in 2013
Terrestrial Planet Finder — no launch date
Darwin (ESA) — launch in 2015
Astronomers
Geoffrey Marcy — co-discoverer with R. Paul Butler of more exoplanets than anyone else
R. Paul Butler — co-discoverer with Geoffrey Marcy of more exoplanets than anyone else
Debra Fischer — co-discoverer with Geoffrey Marcy and R. Paul Butler of more exoplanets than anyone else
Aleksander Wolszczan — co-discoverer of PSR B1257+12B and C, the first ever discovered exoplanets, with Dale Frail
Dale Frail — co-discoverer of PSR B1257+12B and C, the first ever discovered exoplanets, with Aleksander Wolszczan
Michel Mayor — co-discoverer of 51 Pegasi b, the first ever discovered exoplanet orbiting a Sun-like star, with Didier Queloz
Didier Queloz — co-discoverer of 51 Pegasi b, the first ever discovered exoplanet orbiting a Sun-like star, with Michel Mayor
Stephane Udry — co-discoverer of Gliese 581c, the most Earth-like planet
Books
Distant Wanderers
Studies
Exoplanetology
Astrobiology
Lists
List of stars with confirmed extrasolar planets
List of extrasolar planet extremes
List of unconfirmed exoplanets
Habitability
Planetary habitability
Extraterrestrial life
Extraterrestrial liquid water
External links
;Search projects:
University of California Planet Search Project
The Geneva Extrasolar Planet Search Programmes
PlanetQuest distributed computing project
SuperWASP Wide Angle Search for Planets
Custer search involves amateur volunteers.
;Resources:
NASA's PlanetQuest
*PlanetQuest 3D Atlas of extrasolar planets within 400 light years of our Solar System
*Planetquest Flash
Beyond Our Solar System by NASA's Solar System Exploration
German Center for Exo-Planet Research Jena/Tautenburg
Astrophysical Institute & University Observatory Jena (AIU)
The Extrasolar Planets Encyclopaedia
exosolar.net 3D Flash StarMap (2000 Stars and all known Exoplanets)
Table of known planetary systems
Extrasolar Planet XML Database
Andrew Collier Cameron, Extrasolar planets, Physics World (January 2001). (See the online version.)
searchable dynamic database of extrasolar planets and their parent stars
List of important exoplanets
Extrasolar Planets - D. Montes, UCM
Extrasolar Visions
Exoplanets at Paris Observatory
Exoplanet Habitable Zone Candidates
Exoplanet Habitable Zone Residents
;News:
Exoplanets Exhibit at the American Museum of Natural History in New York City
First direct image of an exoplanet from universetoday.com
6–8 Earth-Mass Planet Discovered orbiting Gliese 876
Newfound World Shatters Distance Record from space.com
Oldest Known World from space.com
Earth Sized Planets Confirmed from space.com
Sunshade to Look for Distant Life from news.bbc.co.uk
Planet 3x Earth's size found also from news.bbc.co.uk
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