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Need Water? Just Add UV Starlight

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The European Space Agency’s Herschel infrared space observatory has discovered that ultraviolet starlight is the key ingredient for making water in space. It is the only explanation for why a dying star is surrounded by a gigantic cloud of hot water vapor.


The European Space Agency’s Herschel infrared space observatory has shown that the dying star IRC+10216 is surrounded by a large volume of high-temperature water vapor. This color-coded image shows the star, surrounded by a clumpy envelope of dust, at three IR wavelengths, taken by Herschel’s PACS and SPIRE instruments. Blue represents a 160-μm image acquired by the PACS; green is a 250-μm image acquired by the SPIRE; red is a 350-μm image, also from SPIRE. (Image: ESA/PACS/SPIRE/MESS Consortia)

Every recipe needs a secret ingredient. When astronomers discovered an unexpected cloud of water vapor around the old star IRC+10216 in 2001, they immediately began searching for the source. Celestial bodies such as IRC+10216 are known as carbon stars and are thought not to make much water. Initially, the scientists suspected that the star’s heat must be evaporating comets or even dwarf planets to produce the water.

Now, Herschel’s PACS and SPIRE instruments have revealed that the secret ingredient is UV light, because the water is too hot to have come from the destruction of icy celestial bodies.

“This is a good example of how better instruments can change our picture completely,” said Leen Decin, Katholieke Universiteit Leuven in Belgium, the lead author of the paper about this work. The superb sensitivity of Herschel’s instruments has revealed that the water around IRC+10216 varies in temperature from about –200 °C to 800 °C, which indicates that it is being formed much closer to the star than comets can stably exist.


The Herschel observatory has an unprecedented view of the cold universe, using IR radiation to penetrate the gas and dust clouds that hide objects from optical telescopes. Cooler objects, such as tiny stars and molecular clouds, even galaxies enshrouded in dust, barely emitting optical light, are visible in the IR. (Image: Herschel, European Space Agency/AOES Medialab); background, Hubble Space Telescope, NASA/ ESA/ STScI)

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IRC+10216 is a red giant star, hundreds of times the Sun’s size, although only a few times its mass. If it replaced the Sun in our solar system, it would extend beyond the orbit of Mars.

It is 500 light years away, and although it is barely detectable at visible wavelengths, even in the largest telescopes, it is the brightest star in the sky at some infrared wavelengths. This is because it is surrounded by a huge envelope of dust that absorbs almost all its visible radiation and re-emits it as IR light. It is in the envelope that the water vapor has been found. But how did the water get there?

The vital clue was found by Herschel. Observations had already revealed the clumpy structure in the dusty envelope around IRC+10216. The Herschel water detection made the astronomers realize that UV light from surrounding stars can reach deep into the envelope between the clumps and break up molecules such as carbon monoxide and silicon monoxide, releasing oxygen atoms. The oxygen atoms then attach themselves to hydrogen molecules, forming water.

“This is the only mechanism that explains the full range of the water’s temperature,” Decin said. The closer to the star the water is formed, the hotter it will be.

Decin and her colleagues now plan to extend the observations to other carbon stars. “We are very hopeful that Herschel will find the same situations around those stars too,” she said.

On Earth, carbon compounds and water are the key ingredients for life. Now, thanks to Herschel, we know that both can be made around IRC+10216, and that the secret ingredient for water is ultraviolet light from surrounding stars.

For more information, visit:  www.esa.int 



Published: September 2010
Glossary
infrared
Infrared (IR) refers to the region of the electromagnetic spectrum with wavelengths longer than those of visible light, but shorter than those of microwaves. The infrared spectrum spans wavelengths roughly between 700 nanometers (nm) and 1 millimeter (mm). It is divided into three main subcategories: Near-infrared (NIR): Wavelengths from approximately 700 nm to 1.4 micrometers (µm). Near-infrared light is often used in telecommunications, as well as in various imaging and sensing...
ultraviolet
That invisible region of the spectrum just beyond the violet end of the visible region. Wavelengths range from 1 to 400 nm.
Belgiumcarbon starsenergyESAEuropeEuropean Space AgencyHerschel Space ObservatoryImaginginfraredIRIRC+10216Katholieke Universiteit LeuvenLeen DecinPACSred giant starsResearch & TechnologySPIREstarlightultravioletUVwater vapor

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