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Far infrared spectroscopy of low G_o PDRs in low-mass star forming clouds

René Liseau ¹, Glenn White ², & Bengt Larsson ¹

¹ Stockholm Observatory, SE-133 36, Saltsjöbaden, Sweden

² Queen Mary & Westfield College, Dept. of Physics, University of London, Mile End Road, GB-London E1-4NS, UK

Spatial maps and strip scans of low-mass star forming clouds in the solar neighbourhood have been obtained. These observations have been performed with the ISO- LWS (beam size $\sim$ 80 $^{\prime\prime}$ ) and cover the spectral range of $\sim$ 45 to 200 $\mu$ m at the resolution of a few hundred. The data are absolutely calibrated to an accuracy of 30% and thus reasonably well suited for comparison with predictions from theoretical model calculations.

In this paper, we address primarily the spatial distribution of the emission in [C II] 158 $\mu$ m $^{2}{\rm P}_{3/2}$ - $^{2}{\rm P}_{1/2}$ ([C II]158 $\mu$ m), O⁰ $^{3}{\rm P}_{1}$ - $^{3}{\rm P}_{2}$ ([O I]63 $\mu$ m) and O⁰ $^{3}{\rm P}_{0}$ - $^{3}{\rm P}_{1}$ ([O I]145 $\mu$ m). The [C II] 158 $\mu$ m line emission originates in the outer, externally illuminated layers of the cloud ( PDR) and its spatial distribution holds information about the cloud surface geometry and about the efficiency at which the cloud material converts far UV radiation into [C II]158 $\mu$ m line photons. This model provides also estimates of the strength of the incident UV field, commonly expressed in units of G₀ (the Habing Field).

Combining this informtion with the observed distribution of the [O I]63 $\mu$ m emission leads to estimates of the PDR density distribution from detailed model calculations. These standard PDR models fit the LWS observations of the [C II]158 $\mu$ m and [O I]63 $\mu$ m very well and predict, e.g., [C I]609 $\mu$ m line intensities which are in good agreement with independent observations, but leave the observed excess flux in the [O I]145 $\mu$ m line unexplained. These PDR models include recent updates of physical processes and their rates (low temperature collisions; self-shielding of C⁰, H₂ and CO; chemistry; grain and PAH populations). The theory of line excitation and transfer is examined and possible reasons for the mismatch between observed and calculated [O I]145 $\mu$ m strengths are discussed.

Next: Morphology and excitation of Up: Poster session C Interstellar Previous: A superbubble surrounding the

"The Universe as seen by ISO", 20 - 23 October 1998, Paris: Abstract Book

Far infrared spectroscopy of low Go PDRs in low-mass star forming clouds

Far infrared spectroscopy of low G_o PDRs in low-mass star forming clouds