Herschel Probes Dusty Past Of A Giant Star
About 5 thousand million years from now, our Sun will expand into a red giant, swelling to such a size that it may swallow the Earth. It will then begin to shed huge amounts of dust, surrounding itself with an expanding circumstellar envelope (CSE) that ultimately will become a planetary nebula. New insights into this process have been revealed by ESA’s Herschel Space Observatory, which is providing unprecedented images of the complex, outer structure of a nearby CSE.
As part of a long term program to study aging stars, known as the Mass loss of Evolved StarS (MESS) survey, Herschel’s Photodetector Array Camera and Spectrometer (PACS) instrument has been used to observe a nearby, carbon-rich star known as IRC+10216, or CW Leonis.
Classified as an Asymptotic Giant Branch (AGB) star, IRC+10216 has evolved into a red giant, several thousand times bigger than the Sun, and is now nearing the final stages of its life.
Nuclear reactions in its core have transformed most of its hydrogen into helium, and the star is now characterized by an inert carbon-oxygen core, surrounded by two separate layers where nuclear fusion is taking place – an inner layer of helium and an outer layer of hydrogen. These layers are surrounded by a strongly convective outer envelope of hydrogen.
As the star evolves through the AGB phase, burning its nuclear fuel faster and faster, it is cooling and expanding, allowing dust to condense in its outer envelope. At the same time, IRC+10216 has begun to pulsate, causing a stellar wind of dust and gas to be expelled from its surface into the surrounding space. Measurements show that the dust is expanding outwards at a velocity of 14.5 km/s.
The presence of this dusty cocoon has been known for many years, but, until now, no instruments have been able to observe the structure of its cold outer regions, where the temperature plummets to —248 °C. Now, PACS infrared images taken at wavelengths of 70, 100 and 160 microns have revealed multiple dust shells in the circumstellar envelope of IRC+10216. The results are published this week in the journal Astronomy & Astrophysics.
The extremely sensitive PACS instrument has unveiled at least a dozen dust shells (or arcs) that have never been seen before. While arcs which had been ejected within the last 4000 years were previously observed up to 80 arc seconds from the star, the new images show material which was ejected some 16 000 years ago and is now visible at a distance of 320 arc seconds.
Arcs which were shed much earlier than this are no longer visible. Although the mass-loss process started some 220 000 years ago, the earliest arcs have been destroyed by the violent interaction of the stellar wind with the interstellar medium at the bow shock interface, about one light year (almost 9.5 million million kilometers) from IRC+10216.
Surprisingly, the almost spherical shells are non-concentric, of variable thickness, and unevenly spaced. The arcs contain some 50 per cent more dust mass than the smooth envelope and local density variations are also visible within one of the arcs.
The complex internal structure of the nebula is a record of how the star has been losing mass during the recent past. A number of possible explanations for the asymmetric structure of the dust shells have been examined by the authors of the new paper.
“The shell separation distances indicate that they were ejected some 500 to 1700 years apart,” said Leen Decin from the Instituut voor Sterrenkunde, Katholieke Universiteit Leuven, Belgium, lead author of the paper.
“The irregular spacing between the arcs suggests that the structure is not caused by the regular gravitational perturbations associated with an unseen binary companion in orbit around the star.
“A second hypothesis favors enhanced dust formation from magnetic cool spots on the star, rather like the coronal mass ejections which are associated with sunspots. However, the large size of the arcs suggests that there would have to be several sizeable starspots existing in close proximity at the same time. Furthermore, the spacing of the shells shows no evidence of the periodicity that would be expected if the star was experiencing a cycle of rising and falling magnetic activity, like our Sun.
“It seems more likely that the arcs are caused by slight variations in ejection velocity or in the time the ejection took place as the star pulsates and loses mass. Variations in the clumpiness of the dust, associated with temperature variations in the nebula, may also play a part.”
Located some 500 light years from Earth, IRC+10216 is one of the best-known examples of the 150 or so evolved stars which are being studied in the MESS survey, one of the guaranteed time, key observational programs being undertaken with the PACS and SPIRE instruments on board Herschel.
“The angular resolution of these instruments provides accurate maps of the far infrared emission of different types of evolved stars,” said Groenewegen from the Observatory of Belgium in Brussels, Investigator of the MESS program. “This helps us to infer detailed information on the mass, size and structure of the dust shells, and possible grain size/temperature gradients, significantly improving our knowledge of the mass-loss history of these giant stars.”
IRC+10216 was also the subject of a recent paper, published in the journal Nature, in which Leen Decin described the detection of warm water vapor in the sooty envelope of the carbon star. One way to create water in this carbon-rich environment is by means of photochemistry, induced by the penetration of highly energetic interstellar photons of ultraviolet light into a non-homogeneous envelope.
The new PACS detection of arcs in the outer envelope confirms that the nebula surrounding IRC+10216 is variable in structure, and that photochemistry is an important process in creating warm water vapor.
“By virtue of its large telescope enabling us to see these structures in such fine detail, Herschel is adding to our understanding of this iconic star,” commented GÃ¶ran Pilbratt, ESA’s Herschel Project Scientist.
L. Decin, et al., “Discovery of multiple dust shells beyond 1 arcmin in the circumstellar envelope of IRC+10216 using Herschel/PACS”. Published online in Astronomy & Astrophysics on 20 September 2011.
Image 1: New images of IRC+10216, obtained with the PACS instrument on the Herschel Space Observatory, have revealed never before seen dust shells extending out to a distance of 320 arc seconds from the central star. This image was obtained at 100 micron and shows a field of view of 16 arc minutes Ã— 11 arc minutes. The 6 radial spikes are due to the support structure of the secondary mirror. Credit: ESA/PACS/MESS Consortia
Image 2: New images of IRC+10216, obtained with the PACS instrument on the Herschel Space Observatory, have revealed never before seen dust shells extending out to a distance of 320 arc seconds from the central star. Some new features in the circumstellar envelope of IRC+10216 (CW Leonis)are indicated in this annotated image. (A) The arc indicates the location of a bow shock, situated about 1 light year from the star; dust shells, corresponding to the ejection of material from the star at (B) 16 000 years, (C) 12 750 years, (D) 2500 years and (E) 1175 years ago are also indicated. This image was obtained at 100 micron and shows a field of view of 16 arc minutes Ã— 11 arc minutes. The 6 radial spikes are due to the support structure of the secondary mirror. Credit: ESA/PACS/MESS Consortia
Image 3: This color-composite image of CW Leonis, also known as IRC +10216, was obtained with the SPIRE and PACS instruments on the Herschel Space Observatory. It combines observations at wavelengths of 160 µm (blue; PACS), 250 µm (green; SPIRE) and 350 µm (red; SPIRE). A bow shock, created by the interaction of the stellar wind emitted by the star and the interstellar medium, can be seen to the left of the star. The image is 15×15 arcminutes. Credit: ESA/PACS/SPIRE/MESS Consortia
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