Tracing high energy radiation with molecular lines near deeply embedded protostars
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Tracing high energy radiation with molecular lines near deeply embedded protostars. / Stäuber, P.; Benz, A. O.; Jørgensen, J. K.; Van Dishoeck, E. F.; Doty, S. D.; Van Der Tak, F. F.S.
I: Astronomy and Astrophysics, Bind 466, Nr. 3, 01.05.2007, s. 977-988.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt
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TY - JOUR
T1 - Tracing high energy radiation with molecular lines near deeply embedded protostars
AU - Stäuber, P.
AU - Benz, A. O.
AU - Jørgensen, J. K.
AU - Van Dishoeck, E. F.
AU - Doty, S. D.
AU - Van Der Tak, F. F.S.
PY - 2007/5/1
Y1 - 2007/5/1
N2 - Aims. The aim is to probe high energy radiation emitted by deeply embedded protostars. Methods. Submillimeter lines of CN, NO, CO+ and SO +, and upper limits on SH+ and N2O are observed with the James Clerk Maxwell Telescope in two high-mass and up to nine low-mass young stellar objects and compared with chemical models. Results. Constant fractional abundances derived from radiative transfer modeling of the line strengths are x(CN) ≈ a few × 10-11 -10-8, x(NO) ≈ 10-9-10-8 and x(CO+) ≈ 10 -12-10-10. SO+ has abundances of a few × 10-11 in the high-mass objects and upper limits of ≈10 -12-10-11 in the low-mass sources. All abundances are up to 1-2 orders of magnitude higher if the molecular emission is assumed to originate mainly from the inner region (≲1000 AU) of the envelope. For high-mass sources, the CN, SO+ and CO+ abundances and abundance ratios are best explained by an enhanced far-ultraviolet (FUV) field impacting gas at temperatures of a few hundred K. The observed column densities require that this region of enhanced FUV has scales comparable to the observing beam, such as in a geometry in which the enhanced FUV irradiates outflow walls. For low-mass sources, the required temperatures within the FUV models of T ≳ 300 K are much higher than found in models, so that an X-ray enhanced region close to the protostar (r ≲ 500 AU) is more plausible. Gas-phase chemical models produce more NO than observed, suggesting an additional reduction mechanism not included in current models. Conclusions. The observed CN, CO+ and SO+ abundances can be explained with either enhanced X-rays or FUV fields from the central source. High-mass sources likely have low opacity regions that allow the FUV photons to reach large distances from the central source. X-rays are suggested to be more effective than FUV fields in the low-mass sources. The observed abundances imply X-ray fluxes for the Class 0 objects of LX ≈ 1029-1031 ergs-1, comparable to those observed from low-mass Class I protostars. Spatially resolved data are needed to clearly distinguish the effects of FUV and X-rays for individual species.
AB - Aims. The aim is to probe high energy radiation emitted by deeply embedded protostars. Methods. Submillimeter lines of CN, NO, CO+ and SO +, and upper limits on SH+ and N2O are observed with the James Clerk Maxwell Telescope in two high-mass and up to nine low-mass young stellar objects and compared with chemical models. Results. Constant fractional abundances derived from radiative transfer modeling of the line strengths are x(CN) ≈ a few × 10-11 -10-8, x(NO) ≈ 10-9-10-8 and x(CO+) ≈ 10 -12-10-10. SO+ has abundances of a few × 10-11 in the high-mass objects and upper limits of ≈10 -12-10-11 in the low-mass sources. All abundances are up to 1-2 orders of magnitude higher if the molecular emission is assumed to originate mainly from the inner region (≲1000 AU) of the envelope. For high-mass sources, the CN, SO+ and CO+ abundances and abundance ratios are best explained by an enhanced far-ultraviolet (FUV) field impacting gas at temperatures of a few hundred K. The observed column densities require that this region of enhanced FUV has scales comparable to the observing beam, such as in a geometry in which the enhanced FUV irradiates outflow walls. For low-mass sources, the required temperatures within the FUV models of T ≳ 300 K are much higher than found in models, so that an X-ray enhanced region close to the protostar (r ≲ 500 AU) is more plausible. Gas-phase chemical models produce more NO than observed, suggesting an additional reduction mechanism not included in current models. Conclusions. The observed CN, CO+ and SO+ abundances can be explained with either enhanced X-rays or FUV fields from the central source. High-mass sources likely have low opacity regions that allow the FUV photons to reach large distances from the central source. X-rays are suggested to be more effective than FUV fields in the low-mass sources. The observed abundances imply X-ray fluxes for the Class 0 objects of LX ≈ 1029-1031 ergs-1, comparable to those observed from low-mass Class I protostars. Spatially resolved data are needed to clearly distinguish the effects of FUV and X-rays for individual species.
KW - ISM: molecules
KW - Stars: formation
KW - Stars: low-mass, brown dwarfs
KW - X-rays: ISM
UR - http://www.scopus.com/inward/record.url?scp=34248598502&partnerID=8YFLogxK
U2 - 10.1051/0004-6361:20065762
DO - 10.1051/0004-6361:20065762
M3 - Journal article
AN - SCOPUS:34248598502
VL - 466
SP - 977
EP - 988
JO - Astronomy & Astrophysics
JF - Astronomy & Astrophysics
SN - 0004-6361
IS - 3
ER -
ID: 234018574