| |
| Discovery | |
|---|---|
| Discovered by | Vanessa Bailey, et al.[1] |
| Discovery site | Magellan Telescopes at the Las Campanas ObservatoryinChile[1] |
| Discovery date | December 4, 2013 (published)[2] |
| Direct imaging[3] | |
| Orbital characteristics | |
Mean orbit radius | 738 AU (110 billion km)[4] |
| 8,910.501 years[5] | |
| Star | HD 106906 |
| Physical characteristics | |
Mean radius | 149,589.06 km |
| Mass | 11±2 MJup[2] |
| Temperature | ≈1,800 K (1,500 °C; 2,800 °F)[2] |
HD 106906 b is a directly imaged planetary-mass companion[2] and candidate exoplanet orbiting the star HD 106906, in the constellation Crux at about 336 ± 13light-years (103 ± 4 pc) from Earth.[5] It is estimated to be about eleven times the massofJupiter and is located about 738 AU away from its host star.[4] HD 106906 b is an oddity; while its mass estimate is nominally consistent with identifying it as an exoplanet, it appears at a much wider separation from its parent star than thought possible for in-situ formation from a protoplanetary disk.[6]
HD 106906 b is the only known companion orbiting HD 106906, a spectroscopic binary star composed of two F5V main-sequence stars with a combined mass of 2.71 M☉.[5] Based on the star's luminosity and temperature, the system is estimated to be about 13±2 million years old. The system is a likely member of the Scorpius–Centaurus association. The star is surrounded by a debris disk oriented 21 degrees away from HD 106906 b;[7][8] this disk is about 65 AU (10 billion km; 6 billion mi) from the binary on its interior and ranges asymmetrically from approximately 120 to 550 AU (18 to 82 billion km; 11 to 51 billion mi) from the binary at its outer edge.[5] Based on its near-infrared spectral-energy distribution, its age, and relevant evolutionary models, HD 106906 b is estimated to be 11±2 MJup, with a surface temperature of 1,800 K (1,500 °C; 2,800 °F).[2] The high surface temperature, a relic of its recent formation, gives it a luminosity of about 0.02% of the Sun's.[2] While its mass and temperature are similar to other planetary-mass companions/exoplanets like beta Pictorisbor1RXS J160929.1−210524b, its projected separation from the star is much larger, about 738 AU (110 billion km; 69 billion mi),[2][a] giving it one of the widest orbits of any currently known planetary-mass companions.[2]
The measurements obtained thus far are not adequate to evaluate its orbital properties. If its eccentricity is large enough, it might approach the outer edge of the primary's debris disk closely enough to interact with it at periastron. In such a case, the outer extent of the debris disk would be truncated at the inner edge of HD 106906 b's Hill sphere at periastron.[2]
The discovery team evaluated the possibility that HD 106906 b is not gravitationally bound to HD 106906, but is seen close to it along our line of sight and moving in the same direction by chance. The odds of such a coincidence were found to be less than 0.01%.[2]
Observation of star HD 106906 began in 2005, utilizing the Magellan Telescopes at the Las Campanas Observatory in the Atacama DesertofChile, some eight years before the companion was discovered. The initial interest in HD 106906 A was directed largely to the debris disk surrounding the star, a pre-main-sequence member of Lower Centaurus–Crux. On December 4, 2013, University of Arizona graduate student Vanessa Bailey, leader of an international team of astronomers, detailed the discovery of HD 106906 b with a paper first published as a preprint on the arXiv and later as a refereed article in The Astrophysical Journal Letters.[2]
The discovery team and astronomers worldwide were puzzled by HD 106906 b's extreme separation from its host star, because it is not considered possible that a star's protoplanetary disk could be extensive enough to permit formation of gas giants at such a distance. To account for the separation, it is theorized that the companion formed independently from its star as part of a binary system. This proposal is somewhat problematic in that the mass ratio of ~140:1 is not in the range expected from this process; binary stars typically do not exceed a ratio of 10:1.[6][9] This is still considered preferable, however, to the alternate theory that the companion formed closer to its primary and then was scattered to its present distance by gravitational interaction with another orbital object. This second companion would need to have a mass greater than that of HD 106906 b, and the discovery team found no such object beyond 35 AU from the primary. Additionally, the scattering process would have likely disrupted the protoplanetary disk.[2]
Subsequently, astronomer Paul Kalas and colleagues discovered that Hubble Space Telescope images show a highly asymmetric shape to the debris disk beyond a radius of 200 AU, supporting the hypothesis of a dynamical upheaval that involved the planet and another perturber, such as a second planet in the system or a close encounter with a passing star.[7] One theory modeled the planet as originating in a disk close to the central binary, migrating inward to an unstable resonance with the binary, and then evolving rapidly to a highly eccentric orbit.[5] The planet would be ejected unless its periastron distance was increased away from the binary, such as by a gravitational encounter with a passing star during apastron. An analysis of the motions of 461 nearby stars using Gaia observations revealed two (HIP 59716 and HIP 59721, a possible loosely bound binary system) that passed within 1 pc (3.3 ly) of HD 106906 between 2 and 3 million years ago.[4]
A petition had been launched asking the International Astronomical Union (IAU) to name the companion Gallifrey, after the homeworldofThe Doctor on the British science fiction series Doctor Who. The petition gathered over 139,000 signatures. In January 2014, however, it was agreed by the IAU not to accept the petition's goal to name it Gallifrey, as the petition did not follow the public policy of the IAU that a discussion between the public and IAU should be started before naming any spatial entity, and that this policy was not respected.[10][11]
In 2009, IAU stated that it had no plans to assign names to extrasolar planets, considering it impractical.[12] However, in August 2013 the IAU changed its stance, inviting members of the public to suggest names for exoplanets.[13]
Recent observations made by the Hubble Space Telescope "pinned" down that the planet had a somewhat unusual orbit that perturbed it from its host star's debris disk. With NASA and several news outlets comparing it to the so-called hypothetical Planet Nine.[14][15]
|
2013 in space
| ||||||
|---|---|---|---|---|---|---|
2014 » | ||||||
Space probe launches  |
|
| ||||
| Impact events |
| |||||
| Selected NEOs |
| |||||
| Exoplanets |
| |||||
| Discoveries |
| |||||
| Novae |
| |||||
| Comets |
| |||||
| Space exploration |
| |||||
| ||||||
|
| |||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| |||||||||||
| Stars |
| ||||||||||
| |||||||||||
| |||||||||||
| |||||||||||
