A&A 402, L77-L81 (2003)
L. Pagani 1 - A. O. H. Olofsson2 - P. Bergman2 - P. Bernath3 - J. H. Black2 - R. S. Booth2 - V. Buat4 - J. Crovisier12 - C. L. Curry3 - P. J. Encrenaz1 - E. Falgarone5 - P. A. Feldman6 - M. Fich3 - H. G. Floren7 - U. Frisk8 - M. Gerin5 - E. M. Gregersen9 - J. Harju10 - T. Hasegawa11 - Å. Hjalmarson2 - L. E. B. Johansson2 - S. Kwok11 - B. Larsson7 - A. Lecacheux12 - T. Liljeström13 - M. Lindqvist2 - R. Liseau7 - K. Mattila10 - G. F. Mitchell14 - L. H. Nordh15 - M. Olberg2 - G. Olofsson7 - I. Ristorcelli16 - Aa. Sandqvist7 - F. von Scheele8 - G. Serra16 - N. F. Tothill14 - K. Volk11 - T. Wiklind2 - C. D. Wilson9
1 - LERMA & FRE 2460 du CNRS, Observatoire de Paris, 61 Av. de l'Observatoire, 75140 Paris, France
2 - Onsala Space Observatory, 439 92 Onsala, Sweden
3 - Department of Physics, University of Waterloo, Waterloo, Ontario N2L 3G1, Canada
4 - Laboratoire d'Astronomie Spatiale, BP 8, 13376 Marseille Cedex 12, France
5 - LERMA & FRE 2460 du CNRS, École Normale Supérieure, 24 rue Lhomond, 75005 Paris, France
6 - Herzberg Institute of Astrophysics, NRC of Canada, 5071 W. Saanich Rd, Victoria, BC V9E 2E7, Canada
7 - Stockholm Observatory, SCFAB, Roslagstullsbacken 21, 106 91 Stockholm, Sweden
8 - Swedish Space Corporation, PO Box 4207, 171 04 Solna, Sweden
9 - Department of Physics and Astronomy, McMaster University, Hamilton, Ontario L8S 4M1, Canada
10 - Observatory, PO Box 14, University of Helsinki, 00014 Helsinki, Finland
11 - Department of Physics and Astronomy, University of Calgary, Calgary, Alberta T2N 1N4, Canada
12 - LESIA, Observatoire de Paris, Section de Meudon, 5 place Jules Janssen, 92195 Meudon Cedex, France
13 - Metsähovi Radio Observatory, Helsinki University of Technology, Otakaari 5A, 02150 Espoo, Finland
14 - Department of Astronomy and Physics, Saint Mary's University, Halifax, Nova Scottia B3H 3C3, Canada
15 - Swedish National Space Board, PO Box 4006, 171 04 Solna, Sweden
16 - CESR, 9 avenue du Colonel Roche, BP 4346, 31029 Toulouse, France
Received 2 December 2002 / Accepted 25 January 2003
For the first time, a search has been conducted in our Galaxy for the 119 GHz transition connecting to the ground state of O2, using the Odin satellite. Equipped with a sensitive 3 mm receiver ( K), Odin has reached unprecedented upper limits on the abundance of O2, especially in cold dark clouds where the excited state levels involved in the 487 GHz transition are not expected to be significantly populated. Here we report upper limits for a dozen sources. In cold dark clouds we improve upon the published SWAS upper limits by more than an order of magnitude, reaching N(O2)/N(H in half of the sources. While standard chemical models are definitively ruled out by these new limits, our results are compatible with several recent studies that derive lower O2 abundances. Goldsmith et al. (2002) recently reported a SWAS tentative detection of the 487 GHz transition of O2 in an outflow wing towards Oph A in a combination of 7 beams covering approximately . In a brief (1.3 hour integration time) and partial covering of the SWAS region (65% if we exclude their central position), we did not detect the corresponding 119 GHz line. Our 3 sigma upper limit on the O2 column density is cm-2. We presently cannot exclude the possibility that the SWAS signal lies mostly outside of the 9 Odin beam and has escaped our sensitive detector.
Key words: radio lines: ISM - ISM: molecules - Galaxy: abundances
|Figure 1: Receiver stability. Over a period of 24 hours of integration, the noise keeps decreasing steadily.|
Oxygen, the third most abundant cosmic element, is a key species in the chemistry of the interstellar medium (ISM). Our knowledge of its prevalence and distribution depends on the ability to measure the abundance of the main oxygen-bearing species: O, CO, CO2, OH, H2O, CH3OH and O2. The task is difficult due to telluric blocking of CO2, H2O and O2, in addition to important transitions of OH and O. Standard chemical models predicted that the abundance of O2 should be comparable to that of CO inside well-shielded cloud cores (e.g., Herbst & Klamperer 1973; Graedel et al. 1982; Maréchal et al. 1997). Consequently, O2 was considered an important cooling species for clouds (Goldsmith & Langer 1978). It has been actively searched for from the ground (redshifted 119 GHz transition, e.g. Liszt 1985, 1992, Combes et al. 1996; 16O18O rare isotope transition at 1.3 mm, e.g. Goldsmith et al. 1985, Maréchal et al. 1997), from high above the troposphere by balloon (Olofsson et al. 1998), and most recently by satellite (SWAS, Goldsmith et al. 2000). None of these efforts has produced a convincing detection of O2. SWAS reported the lowest upper limits yet: N(O2)/N(C18O) 1.5 (3) and N(O2)/N(H (3) in sources with star-forming activity and N(O2)/N(H (3) in cold dark clouds (TMC-1 and L183/L134N). More recently, the SWAS team reported a possible detection of the 487 GHz O2 line in the Oph A outflow (Goldsmith et al. 2002) with N(O2)/N(H . Despite its diminished importance as a cloud coolant, O2 still attracts interest because it provides strong constraints on chemical models.
Odin, a 1.1 m spaceborne millimeter and submillimeter telescope (Frisk et al. 2003; Olberg et al. 2003), is equipped with two receivers having O2 search capabilities: a cryogenically cooled 3 mm HEMT preamplifier (fixed-) tuned to the 118.750343 GHz transition of O2 for which the beam diameter is 9; and a submm receiver tunable to the 487 GHz O2 line with a beamsize of 2.4. Since the 119 GHz line is easy to thermalize, stronger than any of the submm transitions at temperatures below 100 K (Maréchal et al. 1997), and has an upper level only 5.7 K above the ground state, it is probably the best line to search for, especially in cold dark clouds. At 10 K, the 119 GHz line is 20 times stronger than the 487 GHz line. With a 119 GHz system temperature ( K) 8 times lower than that of SWAS, we gain 2 orders of magnitude in sensitivity in extended cold clouds and gain a factor of 40 even if the source is smaller than the SWAS beam.
In this paper, we present the observations in Sect. 2, the data reduction in Sect. 3, and discuss briefly the intriguing results in Sect. 4.
|Figure 2: O2 spectra with unscaled C18O spectra. The noise peaks at source velocity are 1.5 (L134N) and 2.5 (Orion A). The horizontal axis is LSR velocity in km s-1, the vertical axis, in K (uncorrected for beam efficiency).|
The first useful Odin observations were obtained towards Orion on 2001-08-19 and all reported sources but TMC-1 were subsequently observed until 2001-10-04. At that time, the phase-lock system became unstable and was lost after 2001-10-14. The phase-lock was recovered no later than 2002-03-09. Data taken towards TMC-1 (2002-03-23 to 2002-03-25) were correctly phase-locked. The absolute pointing uncertainty is within 30 , which is negligible for our beam size of 9. In some sources, we allowed offsets up to 2 to be included in the average, which still represents less than 25% error in pointing. The autocorrelator spectral sampling was 0.125 MHz ( km s-1) in a 100 MHz bandwidth for all sources except G0.26-0.01, for which we used 1 MHz ( km s-1) sampling (in a bandwidth of 800 MHz). The autocorrelator resolution is twice as wide as its sampling. In this Letter, we adopt , as measured at 557 GHz towards Jupiter. Details of the calibration are presented by Olberg et al. (2003).
Our first concern was to establish the exact center frequency of the O2 receiver band at all times and heck its stability. The Local Oscillator phase-lock reference signal is not thermally controlled and is thus allowed to drift somewhat around its standard frequency. The receiver tuning is checked by measuring the telluric O2 line position in the backend during the 40% of each orbit Odin spends pointing at Earth's atmosphere. The tuning was extremely stable from mid-August to the 4th of October 2001, with high and low resolution data requiring corrections of MHz and -0.3 to -0.1 MHz, respectively. In March 2002, the high resolution data correction was 0.12 MHz.
The observing mode ("Dicke'' switching against blank sky with a 4.4 FWHM reference beam, off-axis by 20) gives reasonably good baselines at high resolution but rather bad ones for large bandwidth. For the large-bandwidth G0.26-0.01 observation, the baselines were improved by subtracting a Dicke-switched off-source observation (+30 in declination, with no C18O emission). After long integrations in high resolution mode, a sinusoidal ripple of low amplitude (a few mK) could sometimes be seen and was removed with a sinusoidal baseline fit.
The stability of the receiver is clearly demonstrated in the decrease of the rms noise versus time shown in Fig. 1. Some of our observational results are displayed in Fig. 2.
(a) Core only:
(b) No extended C18O measurements available;
(c) Line of sight towards G0.26-0.01, containing many clouds|
over a large velocity range; (d) From 13CO, N(H2) 1023 cm-3; (e) C18O core only.
Refs.: (1) Onishi et al. (1996), (2) Dutrey et al. (1996), (3) Aoyama et al. (2001), (4) Pagani et al. (2001), (5) Tachihara et al. (2000),
(6) Kraemer & Jackson (1999), (7) Schwartz et al. (1989), (8) Dickel et al. (1977), (9) Dahmen et al. (1997), (10) Dahmen et al. (1998),
(11) Ando et al. (2002), (12) McMullin et al. (2000), (13) Churchwell et al. (1992), (14) Matthews et al. (1987), (15) Little et al. (1994),
(16) Kim et al. (2001).
|Figure 3: The SWAS and Odin beams towards Oph A. The dashed circle represents the SWAS central beam, not taken into account in their detection (Goldsmith et al. 2002).|
|Figure 4: Smoothed Oph A O2 spectrum, with the signal expected at 119 GHz from the SWAS O2 column density estimate superimposed. Axes are the same as in Fig. 2.|
In a recent paper (Goldsmith et al. 2002), the SWAS team reported a possible detection of 487 GHz O2 in the red wing of the Oph A outflow. Their tentative detection was made by adding 7 different SWAS positions surrounding, but excluding, the source itself (cf. our Fig. 3). Our larger beam, with a slightly different target position ( Oph A-VLA) covers about 65% of the SWAS-mapped region, not including their central beam. With the same assumptions as in Goldsmith et al. (2002), we find a 3 upper limit of N(O cm-2, corresponding to X(O , a factor of 3 below their estimate (N(O cm-2, X(O ). Using their estimated O2 column density, we have computed the expected Gaussian line at 119 GHz and overlaid it on our spectrum in Fig. 4 (the Gaussian line has been combined with our own noise spectrum to simulate real observing conditions). A clear signal should have been detected if O2 is evenly distributed among the SWAS mapped region. Because the Odin beam does not completely cover that region, we cannot exclude the possibility that most of the emission lies outside our beam and thus escaped detection at 119 GHz. Further Odin observations are underway to settle this point.
We thank E. Herbst and P. Goldsmith for sending us their manuscripts prior to publication. We also thank the NANTEN group, G. Dahmen, J. McMullin and J. Bally for kindly providing us with their C18O data. Generous financial support from the Research Councils and Space Agencies in Canada, Finland, France and Sweden is gratefully acknowledged.