Johnson Measures Precise Size of Exoplanet
When the planet WASP-10b crosses the disk of its star, WASP-10, the brightness of the star decreases, allowing scientists to measure the precise size of the planet.
Postdoctoral fellow and planet hunter John Johnson has measured the precise size of a planet around a distant star. He and his team employed a new technique and a camera so sensitive that it could detect the passage of a moth in front of a lit window from a distance of 1,000 miles.
The camera, mounted on the UH 2.2-meter (88-inch) telescope on Mauna Kea, measured the small decrease in brightness that occurs when a planet passes in front of its star along the line-of-sight from Earth. These "planet transits" allow researchers to measure the diameters of worlds outside our solar system.
"While we know of more than 330 planets orbiting other stars in our Milky Way galaxy, we can measure the physical sizes of only the few that line up just right to transit," explained Johnson. The team studied a planet called WASP-10b, which was thought to have an unusually large diameter. They were able to measure its diameter with much higher precision than before, leading to the finding that it is one of the densest planets known, rather than one of the most bloated. The planet orbits the star WASP-10, which is about 300 light-years from Earth.
IfA astronomer John Tonry designed the camera, known as OPTIC (Orthogonal Parallel Transfer Imaging Camera), and it was built at the IfA. It uses a new type of detector, an orthogonal transfer array, the same type used in the Pan-STARRS 1.4 Gigapixel Camera, the largest digital camera in the world. These detectors are similar to the CCDs (charge-coupled devices) commonly used in scientific and consumer digital cameras, but they are more stable and can collect more light, which leads to higher precision.
"This new detector design is really going to change the way we study planets. It's the killer app for planet transits," said team member Joshua Winn, an assistant professor of physics at MIT. The precision of the camera is high enough to detect transits of much smaller planets than previously possible. It measures light to a precision of one part in 2,000. For the first time, scientists are approaching the precision needed to measure transits of Earth-size planets.
Bigger planets block more of the star's surface and cause a deeper brightness dip. The diameter of WASP-10b is only 6 percent larger than that of Jupiter, even though WASP-10b is three times more massive. Correspondingly, its density is about three times higher than Jupiter's. Because of the nature of their interiors, Jupiter-like planets have a nearly constant radius across a wide range of masses.
The photometric precision is three to four times higher than that of typical CCDs and two to three times higher than the best CCDs, and comparable to the most recent results from the Hubble Space Telescope for stars of the same brightness.
Johnson is a National Science Foundation astronomy and astrophysics postdoctoral fellow working at the IfA. Working with Johnson and Winn are MIT graduate student Joshua Carter and Nicole Cabrera, a student at the Georgia Institute of Technology who spent the summer working with Johnson as a participant in IfA's Research Experiences for Undergraduates program.
The scientific paper presenting this discovery will be published in the Astrophysical Journal Letters. A preprint is available on the Web at http://arxiv.org/abs/0812.0029.
Built in 1970, the UH 2.2-meter telescope continues to produce cutting-edge scientific results.