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A CS J=5-4 Mapping Survey Towards High-mass Star Forming Cores Associated with Water Masers

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 Added by Yancy L. Shirley
 Publication date 2003
  fields Physics
and research's language is English




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We have mapped 63 regions forming high-mass stars in CS J=5-4 using the CSO. The CS peak position was observed in C34S J=5-4 towards 57 cores and in 13CS J=5-4 towards the 9 brightest cores. The sample is a subset of a sample originally selected toward water masers; the selection on maser sources should favor sources in an early stage of evolution. The integrated intensity of CS J=5-4 correlates very well with the dust continuum emission at 350 microns. The distributions of size, virial mass, surface density, and luminosity are all peaked with a few cores skewed towards much larger values than the mean. We find a weak correlation between C34S linewidth and size, consistent with Dv ~ R^{0.3}. The linewidths are much higher than would be predicted by the usual relations between linewidth and size determined from regions of lower mass. These regions are very turbulent. The derived virial mass agrees within a factor of 2 to 3 with mass estimates from dust emission at 350 microns after corrections for the density structure are accounted for. The resulting cumulative mass spectrum of cores above 1000 solar masses can be approximated by a power law with a slope of about -0.9, steeper than that of clouds measured with tracers of lower density gas and close to that for the total masses of stars in OB associations. The median turbulent pressures are comparable to those in UCHII regions, and the pressures at small radii are similar to those in hypercompact-HII regions (P/k ~ 10^{10} K cm^{-3}). The filling factors for dense gas are substantial, and the median abundance of CS is about 10^{-9}. The ratio of bolometric luminosity to virial mass is much higher than the value found for molecular clouds as a whole, and the correlation of luminosity with mass is tighter. (Abridged).



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