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News Release 09-241

Waterworld Discovered Transiting a Nearby Star

Charbonneau team realizes major advance in discovering habitable planets

Artist's conception of a super-Earth orbiting GJ1214, a nearby star, 40 light years away.

Artist's conception of a super-Earth orbiting GJ1214, a nearby star, 40 light years away.


December 16, 2009

View a Webcast with astronomer David Charbonneau.

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Astronomers announced today that they have discovered a "super-Earth" orbiting a red dwarf star only 40 light-years from Earth. They found this nearby planet with a small fleet of ground-based telescopes no larger than those many amateur astronomers have in their backyards. Although the super-Earth is too hot to sustain life, the discovery shows that current, ground-based technologies are capable of finding almost-Earth-sized planets in warm, life-friendly orbits.

The discovery is being published in the December 17 issue of the journal Nature.

A super-Earth is defined as a planet between one and ten times the mass of the Earth. The new-found world, GJ1214b, is about 6.5 times as massive as the Earth. Its host star, GJ1214, is a small, red type M star about one-fifth the size of the Sun. It has a surface temperature of only about 4,900 degrees F and a luminosity only three-thousandths as bright as the Sun.

GJ1214b orbits its star once every 38 hours at a distance of only 1.3 million miles. Astronomers estimate the planet's temperature to be about 400 degrees Fahrenheit. Although warm as an oven, it is still cooler than any other known transiting planet because it orbits a very dim star that emits only about three-thousandths as much energy per second as does the Sun.

Since GJ1214b crosses in front of its star, astronomers were able to measure its radius, which is about 2.7 times that of Earth. This makes GJ1214b one of the two smallest transiting worlds astronomers have discovered, the other being CoRoT-7-b. The resulting density suggests that GJ1214b is composed of about three-fourths water and other ices, and one-fourth rock. There are also tantalizing hints that the planet has a gaseous atmosphere.

"Despite its hot temperature, this appears to be a waterworld," said Zachory Berta, a graduate student at the Harvard-Smithsonian Center for Astrophysics (CfA) who first spotted the hint of the planet among the data. "It is much smaller, cooler, and more Earthlike than any other known exoplanet."

Berta added that some of the planet's water should be in the form of exotic materials like Ice VII (seven)--a crystalline form of water that exists at pressures greater than 20,000 times Earth's sea-level atmosphere.

Astronomers found the new planet using the MEarth (pronounced "mirth") Project--an array of eight identical 16-inch-diameter RC Optical Systems telescopes that monitor a pre-selected list of 2,000 red dwarf stars. Each telescope perches on a highly accurate Software Bisque Paramount and funnels light to an Apogee U42 charge-coupled device (CCD) chip, which many amateurs also use.

"Since we found the super-earth using a small ground-based telescope, this means that anyone else with a similar telescope and a good CCD camera can detect it too. Students around the world can now study this super-earth!" said David Charbonneau of CfA, lead author and head of the MEarth project.

MEarth looks for stars that periodically decrease in brightness because planets cross in front of, or transits, their stars. During such a mini-eclipse, the planet blocks a small portion of the star's light, making it dimmer. Using innovative data processing techniques, astronomers can tease out the telltale signal of a transiting planet and distinguish it from "false positives" such as eclipsing double stars.

NASA's Kepler mission also uses transits to look for Earth-sized planets orbiting Sun-like stars. However, such systems dim by only one part in ten thousand. The higher precision required to detect these transits means that such worlds can only be found from space.

In contrast, a super-Earth transiting a small, red dwarf star yields a more pronounced decrease in brightness that can be detected from the ground. Astronomers then use instruments like the HARPS (High Accuracy Radial Velocity Planet Searcher) spectrograph at the European Southern Observatory to measure the companion's mass and confirm it is a planet, as they did with this discovery.

When astronomers compared the measured radius of GJ1214b to theoretical models, they found that the observed radius exceeds the model's prediction, even assuming a pure water planet. Something more than the planet's solid surface may be blocking the star's light--specifically, a surrounding atmosphere.

The team also notes that, if it has an atmosphere, those gases are almost certainly not primordial. The star's heat is gradually boiling off the atmosphere. Over the planet's lifetime, several billion years, much of the original atmosphere may have been lost.

The next step for astronomers is to try to directly detect and characterize the atmosphere, which will require a space-based instrument like NASA's Hubble Space Telescope. GJ1214b is only 40 light-years from Earth, within the reach of current observatories.

"Since this planet is so close to Earth, Hubble should be able to detect the atmosphere and determine what it's made of," said Charbonneau. "That will make it the first super-Earth with a confirmed atmosphere--even though that atmosphere probably won't be hospitable to life as we know it."

"The future for further discovery is bright," said Donald Terndrup, program manager in NSF's Division of Astronomical Sciences, "Because this discovery was made early in the MEarth project, there may be many super-Earths around cool stars.  Dr. Charbonneau's team may also discover strange or unexpected worlds, and this will show us how common or rare earth-like planets truly are, further expanding the frontiers of astronomical science."

-NSF-

Media Contacts
Lisa-Joy Zgorski, NSF, (703) 292-8311, email: lisajoy@nsf.gov
Christine Pulliam, Harvard-Smithsonian Center for Astrophysics, (617) 495-7463, email: cpulliam@cfa.harvard.edu

Program Contacts
Donald Terndrup, NSF, (703) 292-4901, email: dterndru@nsf.gov

Principal Investigators
David Charbonneau, Harvard-Smithsonian Center for Astrophysics, (617) 496-6515, email: dcharbon@cfa.harvard.edu

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