AMI radio continuum observations of young stellar objects with known outflows

We present 16 GHz (1.9 cm) deep radio continuum observations made with the Arcminute Microkelvin Imager (AMI) of a sample of low-mass young stars driving jets. We combine these new data with archival information from an extensive literature search to examine spectral energy distributions (SEDs) for...

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Published inMonthly notices of the Royal Astronomical Society Vol. 423; no. 2; pp. 1089 - 1108
Main Authors Ainsworth, Rachael E., Scaife, Anna M. M., Ray, Tom P., Buckle, Jane V., Davies, Matthew, Franzen, Thomas M. O., Grainge, Keith J. B., Hobson, Michael P., Hurley-Walker, Natasha, Lasenby, Anthony N., Olamaie, Malak, Perrott, Yvette C., Pooley, Guy G., Richer, John S., Rodríguez-Gonzálvez, Carmen, Saunders, Richard D. E., Schammel, Michel P., Scott, Paul F., Shimwell, Timothy, Titterington, David, Waldram, Elizabeth
Format Journal Article
LanguageEnglish
Published Oxford, UK Blackwell Publishing Ltd 01.06.2012
Oxford University Press
Subjects
ISM: clouds
ISM: general
radiation mechanisms: general
Radio astronomy
Stars & galaxies
stars: formation
stars: formation
ISM: clouds
ISM: general
radiation mechanisms: general
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Summary:We present 16 GHz (1.9 cm) deep radio continuum observations made with the Arcminute Microkelvin Imager (AMI) of a sample of low-mass young stars driving jets. We combine these new data with archival information from an extensive literature search to examine spectral energy distributions (SEDs) for each source and calculate both the radio and sub-mm spectral indices in two different scenarios: (1) fixing the dust temperature (T d) according to evolutionary class; and (2) allowing T d to vary. We use the results of this analysis to place constraints on the physical mechanisms responsible for the radio emission. From AMI data alone, as well as from model fitting to the full SED in both scenarios, we find that 80 per cent of the objects in this sample have spectral indices consistent with free-free emission. We find an average spectral index in both T d scenarios, consistent with free-free emission. We examine correlations of the radio luminosity with bolometric luminosity, envelope mass and outflow force, and find that these data are consistent with the strong correlation with envelope mass seen in lower luminosity samples. We examine the errors associated with determining the radio luminosity and find that the dominant source of error is the uncertainty on the opacity index, β. We examine the SEDs for variability in these young objects, and find evidence for possible radio flare events in the histories of L1551 IRS 5 and Serpens SMM 1.
Bibliography:We request that any reference to this paper cites ‘AMI Consortium: Ainsworth et al. 2012’.
ISSN:0035-8711
1365-2966
DOI:10.1111/j.1365-2966.2012.20935.x