HD 209458 b

HD 209458 b
Exoplanet List of exoplanets

Size comparison of HD 209458 b with Jupiter
Parent star
Star HD 209458
Constellation Pegasus
Right ascension (α) 22h 03m 10.8s
Declination (δ) +18° 53 04
Apparent magnitude (mV) 7.65
Distance154 ly
(47.1 pc)
Spectral type G0V
Mass (m) 1.13+0.03
0.02 M
Radius (r) 1.14+0.06
0.05 R
Temperature (T) 6000 ± 50 K
Metallicity [Fe/H] 0.00 ± 0.02
Age 4 ± 2 Gyr
Orbital elements
Semi-major axis(a) 0.045 AU
(6.7 Gm)
Periastron (q) 0.044 AU
(6.6 Gm)
Apastron (Q) 0.046 AU
(6.8 Gm)
Eccentricity (e) 0.014±0.009[1]
Orbital period(P) 3.52474541 ± 0.00000025 d
    (84.5938898 h)
Inclination (i) 86.1 ± 0.1°
Argument of
periastron		 (ω) 83°
Time of periastron (T0) 2,452,854.825415
± 0.00000025 JD
Semi-amplitude (K) 84.26 ± 0.81 m/s
Physical characteristics
Mass(m)0.71 MJ
Radius(r)1.35 ± 0.05 RJ
Density(ρ)370 kg m−3
Surface gravity(g)9.4 m/s² (0.96 g)
Temperature (T) 1,130 ± 150
Discovery information
Discovery date November 5, 1999
Discoverer(s) D. Charbonneau
T. Brown
D. Latham
M. Mayor
G.W. Henry
G. Marcy
Kerry O'Connor
R.P. Butler
S.S. Vogt
Discovery method Radial velocity
Other detection methods Transit (both primary and secondary),
Reflection/emission modulations
Discovery site Lowell Observatory
Geneva Observatory
Discovery status Published
Other designations
Osiris
Database references
Extrasolar Planets
Encyclopaedia		data
SIMBADdata
Exoplanet Archivedata
Open Exoplanet Cataloguedata

HD 209458 b (sometimes unofficially called Osiris) is an exoplanet that orbits the solar analog HD 209458 in the constellation Pegasus, some 150 light-years from the Solar System. The radius of the planet's orbit is 7 million kilometres, about 0.047 astronomical units, or one eighth the radius of Mercury's orbit. This small radius results in a year that is 3.5 Earth days long and an estimated surface temperature of about 1,000 °C (about 1,800 °F). Its mass is 220 times that of Earth (0.69 Jupiter masses) and its volume is some 2.5 times greater than that of Jupiter. The high mass and volume of HD 209458 b indicate that it is a gas giant.

HD 209458 b represents a number of milestones in extraplanetary research. It was the first of many categories:

Based on the application of new, theoretical models, as of April 2007, it is alleged to be the first extrasolar planet found to have water vapor in its atmosphere.[3][4][5][6]

In July, 2014, NASA announced finding very dry atmospheres on HD 209458 b and two other exoplanets (HD 189733 b and WASP-12b) orbiting Sun-like stars.[7]

Detection and discovery

Transits

Spectroscopic studies first revealed the presence of a planet around HD 209458 on November 5, 1999. Astronomers had made careful photometric measurements of several stars known to be orbited by planets, in the hope that they might observe a dip in brightness caused by the transit of the planet across the star's face. This would require the planet's orbit to be inclined such that it would pass between the Earth and the star, and previously no transits had been detected.

Soon after the discovery, separate teams, one led by David Charbonneau including Timothy Brown and others, and the other by Gregory W. Henry, were able to detect a transit of the planet across the surface of the star making it the first known transiting extrasolar planet. On September 9 and 16, 1999, Charbonneau's team measured a 1.7% drop in HD 209458's brightness, which was attributed to the passage of the planet across the star. On November 8, Henry's team observed a partial transit, seeing only the ingress.[8] Initially unsure of their results, the Henry group decided to rush their results to publication after overhearing rumors that Charbonneau had successfully seen an entire transit in September. Papers from both teams were published simultaneously in the same issue of the Astrophysical Journal. Each transit lasts about three hours, during which the planet covers about 1.5% of the star's face.

The star had been observed many times by the Hipparcos satellite, which allowed astronomers to calculate the orbital period of HD 209458 b very accurately at 3.524736 days.[9]

Spectroscopic

Spectroscopic analysis had shown that the planet had a mass about 0.69 times that of Jupiter.[10] The occurrence of transits allowed astronomers to calculate the planet's radius, which had not been possible for any previously known exoplanet, and it turned out to have a radius some 35% larger than Jupiter's.

Direct detection

On March 22, 2005, NASA released news that infrared light from the planet had been measured by the Spitzer Space Telescope, the first ever direct detection of light from an extrasolar planet. This was done by subtracting the parent star's constant light and noting the difference as the planet transited in front of the star and was eclipsed behind it, providing a measure of the light from the planet itself. New measurements from this observation determined the planet's temperature as at least 750 °C (1300 °F). The circular orbit of HD 209458 b was also confirmed.

The transit of HD 209458 b.

Spectral observation

On February 21, 2007, NASA and Nature released news that HD 209458 b was one of the first two extrasolar planets to have their spectra directly observed, the other one being HD 189733 b.[11][12] This was long seen as the first mechanism by which extrasolar but non-sentient life forms could be searched for, by way of influence on a planet's atmosphere. A group of investigators led by Jeremy Richardson of NASA's Goddard Space Flight Center 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, for which the investigators did not have an explanation. A separate team led by Mark Swain of the Jet Propulsion Laboratory reanalyzed the Richardson et al. data, and had not yet published their results when the Richardson et al. article came out, but made similar findings.

On 23 June 2010, astronomers announced they have measured a superstorm (with windspeeds of up to 7000 km/h) for the first time in the atmosphere of HD 209458 b.[13] The very high-precision observations done by ESO’s Very Large Telescope and its powerful CRIRES spectrograph of carbon monoxide gas show that it is streaming at enormous speed from the extremely hot day side to the cooler night side of the planet. The observations also allow another exciting "first"—measuring the orbital speed of the exoplanet itself, providing a direct determination of its mass.[2]

Rotation

As of August 2008, the most recent calculation of HD 209458 b's Rossiter–McLaughlin effect and hence spin–orbit angle is −4.4 ± 1.4°.[14][15]

Physical characteristics

It had been previously hypothesized that hot Jupiters particularly close to their parent star should exhibit this kind of inflation due to intense heating of their outer atmosphere. Tidal heating due to its orbit's eccentricity, which may have been more eccentric at formation, may also have played a role over the past billion years.[16]

Stratosphere and upper clouds

The atmosphere is at a pressure of one bar at an altitude of 1.29 Jupiter radii above the planet's center.[17]

Where the pressure is 33±5 millibars, the atmosphere is clear (probably hydrogen) and its Rayleigh effect is detectable. At that pressure the temperature is 2200±260 K.[17]

Observations by the orbiting Microvariability and Oscillations of STars telescope initially limited the planet's albedo (or reflectivity) below 0.3, making it a surprisingly dark object. (The geometric albedo has since been measured to be 0.038 ± 0.045.[18]) In comparison, Jupiter has a much higher albedo of 0.52. This would suggest that HD 209458 b's upper cloud deck is either made of less reflective material than is Jupiter's, or else has no clouds and Rayleigh-scatters incoming radiation like Earth's dark ocean.[19] Models since then have shown that between the top of its atmosphere and the hot, high pressure gas surrounding the mantle, there exists a stratosphere of cooler gas.[20][21] This implies an outer shell of dark, opaque, hot cloud; usually thought to consist of vanadium and titanium oxides like red dwarfs ("pM planets"), but other compounds like tholins cannot be ruled out yet.[21] The Rayleigh-scattering heated hydrogen rests at the top of the stratosphere; the absorptive portion of the cloud deck floats above it at 25 millibars.[22]

Exosphere

Surrounding that level, on November 27, 2001 the Hubble Space Telescope detected sodium, the first planetary atmosphere outside the Solar System to be measured.[23] This detection was predicted by Sara Seager in late 2001.[24] The core of the sodium line runs from pressures of 50 millibar to a microbar.[25] This turns out to be about a third the amount of sodium at HD 189733 b.[26]

In 2003–4, astronomers used the Hubble Space Telescope Imaging Spectrograph to discover an enormous ellipsoidal envelope of hydrogen, carbon and oxygen around the planet that reaches 10,000 K. The hydrogen exosphere extends to a distance RH=3.1 RJ, much larger than the planetary radius of 1.32 RJ.[27] At this temperature and distance, the Maxwell–Boltzmann distribution of particle velocities gives rise to a significant 'tail' of atoms moving at speeds greater than the escape velocity. The planet is estimated to be losing about 100–500 million (1–5×108) kg of hydrogen per second. Analysis of the starlight passing through the envelope shows that the heavier carbon and oxygen atoms are being blown from the planet by the extreme "hydrodynamic drag" created by its evaporating hydrogen atmosphere. The hydrogen tail streaming from the planet is approximately 200,000 kilometres long, which is roughly equivalent to its diameter.

It is thought that this type of atmosphere loss may be common to all planets orbiting Sun-like stars closer than around 0.1 AU. HD 209458 b will not evaporate entirely, although it may have lost up to about 7% of its mass over its estimated lifetime of 5 billion years.[28] It may be possible that the planet's magnetic field may prevent this loss, because the exosphere would become ionized by the star, and the magnetic field would contain the ions from loss.[29]

Presumed atmospheric water vapor

On April 10, 2007, Travis Barman of the Lowell Observatory announced evidence that the atmosphere of HD 209458 b contained water vapor. Using a combination of previously published Hubble Space Telescope measurements and new theoretical models, Barman found strong evidence for water absorption in the planet's atmosphere.[3][30][31] His method modeled light passing directly through the atmosphere from the planet's star as the planet passed in front of it. However, this hypothesis is still being investigated for confirmation.

Barman drew on data and measurements taken by Heather Knutson, a student at Harvard University, from the Hubble Space Telescope, and applied new theoretical models to demonstrate the likelihood of water absorption in the atmosphere of the planet. The planet orbits its parent star every three and a half days, and each time it passes in front of its parent star, the atmospheric contents can be analyzed by examining how the atmosphere absorbs light passing from the star directly through the atmosphere in the direction of Earth.

According to a summary of the research, atmospheric water absorption in such an exoplanet renders it larger in appearance across one part of the infrared spectrum, compared to wavelengths in the visible spectrum. Barman took Knutson's Hubble data on HD 209458 b, applied to his theoretical model, and allegedly identified water absorption in the planet's atmosphere.

On April 24, the astronomer David Charbonneau, who led the team that made the Hubble observations, cautioned that the telescope itself may have introduced variations that caused the theoretical model to suggest the presence of water. He hoped that further observations would clear the matter up in the following months.[32] As of April 2007, further investigation is being conducted.

On October 20, 2009, researchers at JPL announced the discovery of water vapor, carbon dioxide, and methane in the atmosphere.[33][34]

Magnetic field

In 2014, a magnetic field around HD 209458 b was inferred from the way hydrogen was evaporating from the planet. It is the first (indirect) detection of a magnetic field on an exoplanet. The magnetic field is estimated to be about one tenth as strong as Jupiter's.[35][36]

See also

References

  1. Jackson, Brian; Richard Greenberg; Rory Barnes (2008). "Tidal Heating of Extra-Solar Planets". Astrophysical Journal. 681 (2): 1631–1638. arXiv:0803.0026Freely accessible. Bibcode:2008ApJ...681.1631J. doi:10.1086/587641.; Gregory Laughlin; Marcy; Vogt; Fischer; Butler; et al. (2005). "ON THE ECCENTRICITY OF HD 209458b". The Astrophysical Journal. 629 (2): L121–L124. Bibcode:2005ApJ...629L.121L. doi:10.1086/444558.
  2. 1 2 Ignas A. G. Snellen; De Kok; De Mooij; Albrecht; et al. (2010). "The orbital motion, absolute mass and high-altitude winds of exoplanet HD 209458b". Nature. 465 (7301): 1049–1051. arXiv:1006.4364Freely accessible. Bibcode:2010Natur.465.1049S. doi:10.1038/nature09111. PMID 20577209.
  3. 1 2 Water Found in Extrasolar Planet's Atmosphere - Space.com
  4. Signs of water seen on planet outside solar system, by Will Dunham, Reuters, Tue Apr 10, 2007 8:44PM EDT
  5. Staff (December 3, 2013). "Hubble Traces Subtle Signals of Water on Hazy Worlds". NASA. Retrieved December 4, 2013.
  6. Deming, Drake; et al. (September 10, 2013). "Infrared Transmission Spectroscopy of the Exoplanets HD 209458b and XO-1b Using the Wide Field Camera-3 on the Hubble Space Telescope". Astrophysical Journal. 774 (2): 95. arXiv:1302.1141Freely accessible. Bibcode:2013ApJ...774...95D. doi:10.1088/0004-637X/774/2/95. Retrieved December 4, 2013.
  7. Harrington, J.D.; Villard, Ray (July 24, 2014). "RELEASE 14-197 - Hubble Finds Three Surprisingly Dry Exoplanets". NASA. Retrieved July 25, 2014.
  8. Henry et al. IAUC 7307: HD 209458; SAX J1752.3-3138 12 November 1999, reported a transit ingress on Nov. 8. David Charbonneau et al., Detection of Planetary Transits Across a Sun-like Star, November 19, reports full transit observations on September 9 and 16.
  9. Castellano; Jenkins, J.; Trilling, D. E.; Doyle, L.; Koch, D. (March 2000). "Detection of Planetary Transits of the Star HD 209458 in the Hipparcos Data Set". The Astrophysical Journal Letters. University of Chicago Press. 532 (1): L51–L53. Bibcode:2000ApJ...532L..51C. doi:10.1086/312565.
  10. Notes for star HD 209458
  11. NASA's Spitzer First To Crack Open Light of Faraway Worlds
  12. Richardson, L. Jeremy; Deming, D; Horning, K; Seager, S; Harrington, J; et al. (2007). "A spectrum of an extrasolar planet". Nature. 445 (7130): 892–895. arXiv:astro-ph/0702507Freely accessible. Bibcode:2007Natur.445..892R. doi:10.1038/nature05636. PMID 17314975.
  13. Rincon, Paul (23 June 2010). "'Superstorm' rages on exoplanet". BBC News London. Retrieved 2010-06-24.
  14. Winn, Joshua N. (2009). "Measuring accurate transit parameters". Proceedings of the International Astronomical Union. 4: 99. arXiv:0807.4929v2Freely accessible. Bibcode:2009IAUS..253...99W. doi:10.1017/S174392130802629X.
  15. Winn, Joshua N.; et al. (2005). "Measurement of Spin-Orbit Alignment in an Extrasolar Planetary System". The Astrophysical Journal. 631 (2): 1215–1226. arXiv:astro-ph/0504555Freely accessible. Bibcode:2005ApJ...631.1215W. doi:10.1086/432571.
  16. Jackson, Brian; Richard Greenberg; Rory Barnes (2008). "Tidal Heating of Extra-Solar Planets". ApJ. 681 (2): 1631–1638. arXiv:0803.0026Freely accessible. Bibcode:2008ApJ...681.1631J. doi:10.1086/587641.
  17. 1 2 A. Lecavelier des Etangs; A. Vidal-Madjar; J.-M. Désert; D. Sing (2008). "Rayleigh scattering by H in the extrasolar planet HD 209458b". Astronomy & Astrophysics. 485 (3): 865–869. arXiv:0805.0595Freely accessible. Bibcode:2008A&A...485..865L. doi:10.1051/0004-6361:200809704.
  18. Rowe, Jason F.; Matthews, Jaymie M.; Seager, Sara; Sasselov, Dimitar; Kuschnig, Rainer; Guenther, David B.; Moffat, Anthony F. J.; Rucinski, Slavek M.; Walker, Gordon A. H.; Weiss, Werner W. (2009). "Towards the Albedo of an Exoplanet: MOST Satellite Observations of Bright Transiting Exoplanetary Systems". Proceedings of the International Astronomical Union. 4: 121. arXiv:0807.1928v1Freely accessible. Bibcode:2009IAUS..253..121R. doi:10.1017/S1743921308026318.
  19. Matthews J., (2005), MOST SPACE TELESCOPE PLAYS `HIDE & SEEK' WITH AN EXOPLANET; LEARNS ABOUT ATMOSPHERE AND WEATHER OF A DISTANT WORLD
  20. Hubeny, Ivan; Burrows, Adam (2009). "Spectrum and atmosphere models of irradiated transiting giant planets". Proceedings of the International Astronomical Union. 4: 239. arXiv:0807.3588v1Freely accessible. Bibcode:2009IAUS..253..239H. doi:10.1017/S1743921308026458.
  21. 1 2 Dobbs-Dixon, Ian (2009). "Radiative Hydrodynamical Studies of Irradiated Atmospheres". Proceedings of the International Astronomical Union. 4: 273. arXiv:0807.4541v1Freely accessible. Bibcode:2009IAUS..253..273D. doi:10.1017/S1743921308026495.
  22. Sing, David K.; Vidal‐Madjar, A.; Lecavelier Des Etangs, A.; Désert, J.‐M.; Ballester, G.; Ehrenreich, D. (2008). "Determining Atmospheric Conditions at the Terminator of the Hot Jupiter HD 209458b". The Astrophysical Journal. 686: 667–673. arXiv:0803.1054v2Freely accessible. Bibcode:2008ApJ...686..667S. doi:10.1086/590076.
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  24. Seager; Whitney, B. A.; Sasselov, D. D. (2000). "Photometric Light Curves and Polarization of Close‐in Extrasolar Giant Planets". The Astrophysical Journal. 540 (1): 504–520. arXiv:astro-ph/0004001Freely accessible. Bibcode:2000ApJ...540..504S. doi:10.1086/309292.
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  26. Seth Redfield; Michael Endl; William D. Cochran; Lars Koesterke (20 January 2008). "Sodium Absorption from the Exoplanetary Atmosphere of HD 189733b Detected in the Optical Transmission Spectrum". The Astrophysical Journal Letters. 673 (673): L87–L90. arXiv:0712.0761Freely accessible. Bibcode:2008ApJ...673L..87R. doi:10.1086/527475.
  27. Ehrenreich, D.; Lecavelier Des Etangs, A.; Hébrard, G.; Désert, J.-M.; Vidal-Madjar, A.; McConnell, J. C.; Parkinson, C. D.; Ballester, G. E.; Ferlet, R. (2008). "New observations of the extended hydrogen exosphere of the extrasolar planet HD 209458b". Astronomy and Astrophysics. 483 (3): 933–937. arXiv:0803.1831Freely accessible. Bibcode:2008A&A...483..933E. doi:10.1051/0004-6361:200809460.
  28. Hébrard, G.; Lecavelier des Étangs, A.; Vidal-Madjar, A.; Désert, J. -M.; Ferlet, R. (2003). Jean-Philippe Beaulieu, Alain Lecavelier des Étangs and Caroline Terquem, eds. "Evaporation rate of hot Jupiters and formation of Chthonian planets". Extrasolar Planets: Today and Tomorrow. ASP Conference Proceedings. 321: 203–204. arXiv:astro-ph/0312384Freely accessible. Bibcode:2004ASPC..321..203H. ISBN 1-58381-183-4. 30 June - 4 July 2003, Institut d'astrophysique de Paris, France.
  29. Semeniuk, Ivan (September 1, 2009). "Can Magnetism Save a Vaporizing Planet?". Retrieved Oct 30, 2014.
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  31. First sign of water found on an alien world - space - 10 April 2007 - New Scientist Space
  32. J.R. Minkle (April 24, 2007). "All Wet? Astronomers Claim Discovery of Earth-like Planet". Scientific American.
  33. "Astronomers do it Again: Find Organic Molecules Around Gas Planet". October 20, 2009.
  34. "Organic Molecules Detected in Exoplanet Atmosphere". October 20, 2009.
  35. Unlocking the Secrets of an Alien World's Magnetic Field, Space.com, by Charles Q. Choi, November 20, 2014
  36. Kislyakova, K. G.; Holmstrom, M.; Lammer, H.; Odert, P.; Khodachenko, M. L. (2014). "Magnetic moment and plasma environment of HD 209458b as determined from Ly observations". Science. 346 (6212): 981–4. arXiv:1411.6875Freely accessible. Bibcode:2014Sci...346..981K. doi:10.1126/science.1257829. PMID 25414310.

Further reading

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Coordinates: 22h 03m 10.8s, 18° 53′ 04″

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