An 850 μm survey for dust around solar-mass stars

We present the results of an 850 mu m JCMT/SCUBA survey for dust around 13 nearby solar-mass stars. The dust mass sensitivity ranged from 5 x 10(-3) to 0.16 M-circle plus. Three sources were detected in the survey, one of which (HD 107146) has been previously reported. One of the other two submillimeter sources, HD 104860, was not detected by IRAS and is surrounded by a cold, massive dust disk with a dust temperature and mass of T-dust 33 K and M-dust 0.16M(circle plus), respectively. The third source, HD 8907, was detected by IRAS and ISO at 60-87 mu m and has a dust temperature and mass of Tdust 48 K and M-dust 0.036M(circle plus), respectively. We find that the deduced masses and radii of the dust disks in our sample are roughly consistent with models for the collisional evolution of planetesimal disks with embedded planets. We also searched for residual gas in two of the three systems with detected submillimeter excesses and place limits on the mass of gas residing in these systems. When the properties measured for the detected excess sources are combined with the larger population of submillimeter excess sources from the literature, we find strong evidence that the mass in small grains declines significantly on a similar to 200 Myr timescale, approximately inversely with age. However, we also find that the characteristic dust radii of the population, obtained from the dust temperature of the excess and assuming blackbody grains, is uncorrelated with age. This is in contrast to self-stirred collisional models for debris disk evolution, which predict a trend of radius increasing with age t(age) proportional to R-d.(3) The lack of agreement suggests that processes beyond self-stirring, such as giant planet formation, play a role in the evolutionary histories of planetesimal disks.