Gemini Planet Imager

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The Gemini Planet Imager (GPI) is a high contrast imaging instrument being built for the Gemini South Telescope in Chile. The instrument will achieve high contrast at small angular separations, allowing for the direct imaging and integral field spectroscopy of extrasolar planets around nearby stars.[1] The collaboration involved in planning and building the Gemini Planet imager includes the American Museum of Natural History (AMNH), Dunlap Institute, Gemini Observatory, Herzberg Institute of Astrophysics (HIA), Jet Propulsion Laboratory, Lawrence Livermore National Lab (LLNL), Lowell Observatory, SETI Institute, The Space Telescope Science Institute (STSCI), the University of Montreal, University of California, Berkeley, University of California, Los Angeles (UCLA), University of California, Santa Cruz (UCSC), University of Georgia.[2]

Specifications

The Gemini Planet Imager will be used at the Gemini South Telescope, located in Cerro Pachon, Chile. It saw the first light in November 2013, and be available for limited community use in April 2014.[2] It is designed to directly detect young gas giants via their thermal emission. It will operate at near-infrared wavelengths (Y - K bands), where planets will be reasonably bright, but thermal emission from the Earth's atmosphere is not too strong.[3]

The system consist of multiple components, including a high-order adaptive optics system, a coronagraph, a calibration interferometer, and an integral field spectrograph. The adaptive optics system, being built at LLNL, uses a MEMS deformable mirror from Boston Micromachines Corporation to correct wavefront errors induced by motion of air in the atmosphere and the optics in the telescope. The coronagraph, being built at AMNH, blocks out the light from the star being observed, which is necessary in order to see a much dimmer companion. The spectrograph, developed by UCLA and Montreal, images and takes spectra of any detected companion to the star, with a spectral resolving power of 34 - 83, depending on wavelength. The expected instrument performance will allow for detection of companions one ten millionth as bright as their hosts at angular separations of roughly 0.2-1 arcseconds, down to an H band magnitude of 23.[4]

Scientific goals

Present day searches for exoplanets are insensitive to exoplanets located at the distances from their host star comparable to the semi-major axes of the gas giants in the Solar System, greater than about 5 AU. Surveys using the radial velocity method require observing a star over at least one period of revolution, which is roughly 30 years for a planet at the distance of Saturn. Existing adaptive optics instruments become ineffective at small angular separations, limiting them to semi-major axes larger than about 30 astronomical units. The high contrast of the Gemini Planet Imager at small angular separations will allow it to detect gas giants with semi-major axes of 5-30 astronomical units.[5]

The Gemini Planet Imager will be most effective at detecting young gas giants, 1 Myr to 1 Gyr in age. The reason for this is that young planets retain heat from their formation, and only gradually cool. While a planet is still hot, it remains bright, and is thus more easily detected. This limits GPI to younger targets, but means that it will yield information about how gas giants form. In particular, the spectrograph will allow determination of the temperature and surface gravity, which yield information about the atmospheres and thermal evolution of gas giants.[5]

In addition to its main goal of imaging exoplanets, GPI will be capable of studying protoplanetary disks, transition disks, and debris disks around young stars. This may provide clues about planet formation. The technique used to image disks with this instrument is called polarization differential imaging. Another science case is to study solar system objects at high spatial resolution and high strehl ratio. Asteroids, the moons of Jupiter and Saturn, Uranus, and Neptune are all good targets for GPI. The final ancillary science case is to study the mass loss from evolved stars via their outflow.

Gallery

  • GPI Image of star hy4796a showing protoplanetary disk.
    GPI Image of star hy4796a showing protoplanetary disk.

References

  1. ^ Macintosh et al. (2006), p. 1.
  2. ^ a b "GPI: Gemini Planet Imager". Retrieved 2010-03-07.
  3. ^ Graham et al. (2007), p 2.
  4. ^ Macintosh et al. (2006), p. 3.
  5. ^ a b Macintosh et al. (2006), p. 2.

Bibliography

  • Graham, James R.; Macintosh, Bruce; Doyon, Rene; Gavel, Don; Larkin, James; Levine, Marty; Oppenheimer, Ben; Palmer, David; Saddlemyer, Les; Sivaramakrishnan, Anand; Veran, Jean-Pierre; Wallace, Kent (2007). "Ground-Based Direct Detection of Exoplanets with the Gemini Planet Imager (GPI)". Eprint arXiv:0704.1454. arXiv:0704.1454. Bibcode:2007arXiv0704.1454G.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  • Macintosh, Bruce (June 2006). "The Gemini Planet Imager". Proceedings of SPIE. Astronomical Telescopes. 6272: 62720L-62720L-12. doi:10.1117/12.672430. Retrieved 18 April 2012. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
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