Multi-line detection of O2 toward rho Oph A

R. Liseau (1); P.F. Goldsmith (2); B. Larsson (3); L. Pagani (4); P.; Bergman (5); J. Le Bourlot (6); T.A. Bell (7); A.O. Benz (8); E.A. Bergin; (9); P. Bjerkeli (1); J.H. Black (1); S. Bruderer (8; 21); P. Caselli; (10); E. Caux (11); J.-H. Chen (2); M. de Luca (6); P. Encrenaz (4); E.; Falgarone (12); M. Gerin (12); J.R. Goicoechea (7); {\AA}. Hjalmarson (1),; D.J. Hollenbach (13); K. Justtanont (1); M.J. Kaufman (14); F. Le Petit (6),; D. Li (15; 16); D.C. Lis (16); G.J. Melnick (17); Z. Nagy (18); A.O.H.; Olofsson (5); G. Olofsson (3); E. Roueff (6); Aa. Sandqvist (3); R.L. Snell; (19); F.F.S. van der Tak (18); E.F. van Dishoeck (20; 21); C. Vastel (11),; S. Viti (22); and U.A. Y{\i}ld{\i}z (20) ((1) Chalmers University of; Technology; Sweden; (2) Jet Propulsion Laboratory; USA; (3) Department of; Astronomy; Stockholm University; Sweden; (4) LERMA & UMR8112 du CNRS; France,; (5) Onsala Space Observatory; Sweden; (6) Observatoire de Paris; France; (7); Centro de Astrobiolog\'ia; Madrid; Spain; (8) Institute of Astronomy; Zurich,; Switzerland; (9) Department of Astronomy; University of Michigan; USA; (10); School of Physics; Astronomy; University of Leeds; Leeds; UK; (11); Universit\'e de Toulouse; France (12) LRA/LERMA; CNRS; Observatoire de Paris,; France; (13) SETI Institute; (14) Department of Physics; Astronomy; San; Jos\'e State University; USA; (15) National Astronomical Observatories,; Beijing; China; (16) California Institute of Technology; (17); Harvard-Smithsonian Center for Astrophysics; (18) SRON Netherlands Institute; for Space Research; The Netherlands; (19) Department of Astronomy; University; of Massachusetts; USA; (20) Leiden Observatory; The Netherlands; (21); Max-Planck-Institut fur Extraterrestrische Physik; Garching; Germany; (22); Department of Physics; Astronomy; University College)

arXiv:1202.5637·astro-ph.GA·August 14, 2016

Multi-line detection of O2 toward rho Oph A

R. Liseau (1), P.F. Goldsmith (2), B. Larsson (3), L. Pagani (4), P., Bergman (5), J. Le Bourlot (6), T.A. Bell (7), A.O. Benz (8), E.A. Bergin, (9), P. Bjerkeli (1), J.H. Black (1), S. Bruderer (8, 21), P. Caselli, (10), E. Caux (11), J.-H. Chen (2), M. de Luca (6)

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TL;DR

This study uses Herschel's high-resolution spectra to detect and analyze molecular oxygen in rho Oph A, revealing spatial and temperature variations that challenge existing chemical models of molecular clouds.

Contribution

First high-resolution Herschel observations of O2 in rho Oph A, providing detailed spatial and temperature information to refine chemical models.

Findings

01

Detected O2 at 487.2 GHz in all observed positions.

02

Map revealed O2 line in only half the area, indicating spatial variation.

03

O2 column densities range from 3 to >6 x 10^15/cm^2.

Abstract

Models of pure gas-phase chemistry in well-shielded regions of molecular clouds predict relatively high levels of molecular oxygen, O2, and water, H2O. Contrary to expectation, the space missions SWAS and Odin found only very small amounts of water vapour and essentially no O2 in the dense star-forming interstellar medium. Only toward rho Oph A did Odin detect a weak line of O2 at 119 GHz in a beam size of 10 arcmin. A larger telescope aperture such as that of the Herschel Space Observatory is required to resolve the O2 emission and to pinpoint its origin. We use the Heterodyne Instrument for the Far Infrared aboard Herschel to obtain high resolution O2 spectra toward selected positions in rho Oph A. These data are analysed using standard techniques for O2 excitation and compared to recent PDR-like chemical cloud models. The 487.2GHz line was clearly detected toward all three observed…

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