Forming planet observed for first time

Published: Thursday, November 19, 2015 - 06:30 in Astronomy & Space

Related images
(click to enlarge)

This is a composite image of LkCa 15 in which blue shows the MagAO data taken at H-alpha, and green and red show the LBT data taken at Ks and L' bands. The greyscale is a previously published millimeter image of the disk. NOTE: pixilation is because of the way the image was formed.
Credit University of Arizona.
This is an artist's conception of planets forming in a transition disk like LkCa 15. The planets within the disk clearing sweep up material that would have otherwise fallen onto the star.
Attribution: Credit: NASA/JPL-Caltech
This is University of Sydney's Professor Peter Tuthill, co-author of the <i>Nature</i> paper.
University of Sydney

An international team of scientists in Australia and the United States has captured the first-ever images of a planet in the making. The accumulation of dust and gas particles onto a new planet - the process by which the planet continues to form and grow - has been directly observed for the first time. None of the nearly 1,900 planets previously discovered and confirmed outside our Solar System (called exoplanets) are in the process of formation.

The findings of the scientists, led by University of Arizona graduates Steph Sallum and Kate Follette and including the University of Sydney's Professor Peter Tuthill, are published today in Nature.

The YouTube video can be shared after the embargo lifts at https://www.youtube.com/watch?v=vp37oQgTmX4.

A star known as LkCa 15, located 450 light years from Earth, has been observed exhibiting all the trappings of an expectant parent: it is surrounded by a vast disc of dust and gas, making an ideal environment for planets to grow from; the dust shows distinct signs of disturbance - something within has eaten away part of the disc.

Co-author of the paper, Professor Tuthill, said the images provided unambiguous evidence. "This is the first time we've imaged a planet that is definitely still in the process of forming."

The photo provided the proof: "The difficulty had been that when you have indirect evidence, there are always alternate explanations that might fit the data," Professor Tuthill said.

Researchers are just now being able to image objects that were close to and much fainter than a nearby star, thanks to specialised instruments. These include the Large Binocular Telescope - the world's largest telescope, located on Arizona's Mount Graham - and the University of Arizona's Magellan Telescope and its Adaptive Optics System, MagAO, located in Chile.

Capturing sharp images of distant objects was challenging, in large part because of atmospheric turbulence, said Professor Laird Close, Dr Follette's graduate adviser.

"When you look through the Earth's atmosphere, what you're seeing is cold and hot air mixing in a turbulent way that makes stars shimmer," Professor Close said. "To a big telescope, it's a fairly dramatic thing; you see a horrible looking image." The breakthrough was possible because the Large Binocular Telescope was purpose-built, incorporating a novel imaging technique to sharpen the images.

Meanwhile, Professor Close and Dr Follette used Magellan's adaptive optics system MagAO independently to corroborate the discovery. Using MagAO's unique ability to work in visible wavelengths, they captured the planet's 'hydrogen alpha' spectral fingerprint, the specific wavelength of light that LkCa 15 and its planets emit as they grow.

When cosmic objects are forming, they get extremely hot, and because they are forming from hydrogen, those objects all glow a deep red, which astronomers refer to as H-alpha, a particular wavelength of light.

That single shade of red light was emitted by both the planet and the star as they underwent the same growing process, Dr Follette said.

"We were able to separate the light of the faint planet from the light of the much brighter star and to see that they were both growing and glowing in this very distinct shade of red," she said.

Professor Tuthill said the results were only made possible because of the application of a lot of very advanced new technology to the business of imaging the stars.

"It's fantastic to see these cutting-edge instruments now enabling us to make such exciting discoveries," Professor Tuthill said.

The paper, 'Accreting Protoplanets in the LkCa 15 Transition Disc', was published in Nature at 5am on 19 November Australian Eastern Daylight Time. [The paper can be viewed before the embargo upon request.]

Paper will be available at http://www.nature.com/articles/doi:10.1038/nature15761

Source: University of Sydney

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