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HERSCHEL's "COLD DEBRIS DISKS": BACKGROUND GALAXIES OR QUIESCENT RIMS OF PLANETARY SYSTEMS?

A. V. Krivov ; C. Eiroa ; T. Lohne ; J. P. Marshall ; B. Montesinos ; C. del Burgo ; O. Absil ; D. Ardila ; J. C. Augereau ; A. Bayo ; G. Bryden ; W. Danchi ; S. Ertel ; J. Lebreton ; René Liseau (Institutionen för rymd- och geovetenskap, Radioastronomi och astrofysik) ; A. Mora ; A. J. Mustill ; H. Mutschke ; R. Neuhauser ; G. L. Pilbratt ; A. Roberge ; T. O. B. Schmidt ; K. R. Stapelfeldt ; P. Thebault ; C. Vitense ; G. J. White ; S. Wolf
Astrophysical Journal (0004-637X). Vol. 772 (2013), 1,
[Artikel, refereegranskad vetenskaplig]

Infrared excesses associated with debris disk host stars detected so far peak at wavelengths around similar to 100 mu m or shorter. However, 6 out of 31 excess sources studied in the Herschel Open Time Key Programme, DUNES, have been seen to show significant-and in some cases extended-excess emission at 160 mu m, which is larger than the 100 mu m excess. This excess emission has been attributed to circumstellar dust and has been suggested to stem from debris disks colder than those known previously. Since the excess emission of the cold disk candidates is extremely weak, challenging even the unrivaled sensitivity of Herschel, it is prudent to carefully consider whether some or even all of them may represent unrelated galactic or extragalactic emission, or even instrumental noise. We re-address these issues using several distinct methods and conclude that it is highly unlikely that none of the candidates represents a true circumstellar disk. For true disks, both the dust temperatures inferred from the spectral energy distributions and the disk radii estimated from the images suggest that the dust is nearly as cold as a blackbody. This requires the grains to be larger than similar to 100 mu m, even if they are rich in ices or are composed of any other material with a low absorption in the visible. The dearth of small grains is puzzling, since collisional models of debris disks predict that grains of all sizes down to several times the radiation pressure blowout limit should be present. We explore several conceivable scenarios: transport-dominated disks, disks of low dynamical excitation, and disks of unstirred primordial macroscopic grains. Our qualitative analysis and collisional simulations rule out the first two of these scenarios, but show the feasibility of the third one. We show that such disks can indeed survive for gigayears, largely preserving the primordial size distribution. They should be composed of macroscopic solids larger than millimeters, but smaller than a few kilometers in size. If larger planetesimals were present, then they would stir the disk, triggering a collisional cascade and thus causing production of small debris, which is not seen. Thus, planetesimal formation, at least in the outer regions of the systems, has stopped before "cometary" or "asteroidal" sizes were reached.

Nyckelord: circumstellar matter, galaxies: statistics, planets and satellites: formation, protoplanetary disks, stars: individual (HIP 29271, HIP 49908, HIP 109378, HIP 92043, HIP 171, HIP 73100)



Denna post skapades 2013-08-15.
CPL Pubid: 181482

 

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Institutioner (Chalmers)

Institutionen för rymd- och geovetenskap, Radioastronomi och astrofysik (2010-2017)

Ämnesområden

Astronomi, astrofysik och kosmologi

Chalmers infrastruktur