A team of scientists led by Carnegie's Jacqueline Faherty has discovered the first evidence of water ice clouds on an object outside of our own Solar System. Water ice clouds exist on our own gas giant planets -- Jupiter, Saturn¹, Uranus², and Neptune³ -- but have not been seen outside of the planets orbiting our Sun until now. Their findings are published today by The Astrophysical Journal Letters.

 

At the Las Campanas Observatory⁴ in Chile, Faherty, along with a team including Carnegie's Andrew Monson, used the FourStar near infrared⁵ camera to detect the coldest brown dwarf⁶ ever characterized. Their findings are the result of 151 images taken over three nights and combined. The object, named WISE J085510.83-071442.5, or W0855, was first seen by NASA's Wide-Field Infrared Explorer mission and published earlier this year. But it was not known if it could be detected by Earth-based facilities.

 

"This was a battle at the telescope to get the detection," said Faherty.

 

Chris Tinney, an Astronomer⁷ at the Australian Centre for Astrobiology, UNSW Australia and co-author on the result stated: "This is a great result. This object is so faint and it's exciting to be the first people to detect it with a telescope on the ground."

 

Brown dwarfs⁸ aren't quite very small stars, but they aren't quite giant planets either. They are too small to sustain the hydrogen fusion⁹ process that fuels stars. Their temperatures can range from nearly as hot as a star to as cool as a planet, and their masses also range between star-like and giant planet-like. They are of particular interest to scientists because they offer clues to star-formation processes. They also overlap¹⁰ with the temperatures of planets, but are much easier to study since they are commonly found in isolation¹¹.

 

W0855 is the fourth-closest system to our own Sun, practically a next-door neighbor in astronomical¹² distances. A comparison of the team's near-infrared images of W0855 with models for predicting the atmospheric¹³ content of brown dwarfs showed evidence of frozen clouds of sulfide and water.

 

"Ice clouds are predicted to be very important in the atmospheres of planets beyond our Solar System, but they've never been observed outside of it before now," Faherty said.

 

The paper's other co-author is Andrew Skemer of the University of Arizona.

 

This work was supported by the Australian Research Council. It made use of data from the NASA WISE mission, which was a joint¹⁴ project of the University of California Los Angeles and the Jet Propulsion Laboratory and Caltech, funded by NASA. It also made use of the NASA/IPAC Infrared Science Archive, which is operated by the Jet Propulsion Laboratory and Caltech, under contract with NASA.

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