Carbon in low Metallicity PDRs

1. Carbon in low Metallicity PDRs Markus Röllig1 V. Ossenkopf1,3, J. Stutzki1, A. Sternberg4, C. Kramer1, M.Cubick1, H. Jakob1, B. Mookerjea2, R. Simon1, F. Bensch5, 1KOSMA, Universität zu Köln 2University of Maryland, USA 3SRON, Groningen, Netherlands 4Tel Aviv University, Israel 5Radioastronomisches Institut der Universität Bonn Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

2. Introduction • PDR – a working definition:PhotoDissociationRegion • This implies the existence of atomic and molecular gas PLUS the dissociating photons • Also used: Photon Dominated Region • But much broader classification (HII regions, PNe, …) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

3. Introduction • PDRs occur where far-ultraviolet (FUV) radiation (6-13.6 eV) dominates the physics (e.g. heating and cooling) and determines the chemical composition of the gas. Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

4. CO C0 C+ FUV Introduction typical stratification: C+/C/CO, H/H2, S+,S,SO,… center of the cloud edge of the cloud Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

5. FUV Introduction Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

6. The KOSMA- Code 0 1 r/Rtot Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

7. 0 1 r/Rtot The KOSMA- Code Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

8. The KOSMA- Code DR21 in Cygnus X: CO 7-6 & [CI] 3P2-3P1 Figure: 3m-KOSMA maps of [CI] 2-1 (color) and CO 7-6 (contours) at 42'' HPBW (0.35 pc) (Jakob et al. 2005 in prep.) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

9. Introduction Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

10. The KOSMA- Code Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

11. The KOSMA- Code • spherical symmetry • isotropic FUV field • density profile (4 parameter) • D/G, Z as free parameter • 20 heating/cooling processes • modular, steady-state, gas-phase chemistry (UMIST95/99/…) • pre-shielding possible • external multi-shell RT code computes emergent line intensities (CO,13CO,CI,CII,OI,…) • clump-mass & mass-size relations applicable Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

12. The KOSMA- Code • The KOSMA- Code is designed to supply a large parameter grid of pre-calculated model clouds. • results available per web-interface • Standard parameters: D/G, n0, M, , standard chemistry • Extra: , Rcore, pre-shielding, D, CR, ΔvD, Xi, chemical composition Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

13. The KOSMA- Code Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

14. The KOSMA- Code Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

15. The KOSMA- Code Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

16. Solve chemical network destruction formation Solve energy balance heat cooling The KOSMA- Code Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

17. The KOSMA- Code Radiative Transfer Calculations multi-shell ray-tracing ONION, SimLine, etc. calculates emergent intensities per beam and averaged over the whole clump Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

18. Low Z-PDRs Theory and observations suggest that metallicity Z significantly changes the structure of PDR’s : • altered Z  altered gas-phase chemistry • altered Z  less dust • altered grain surface chemistry (e.g. formation of H2) • weaker extinction  deeper FUV penetration  stronger photo-reactions • altered Z  altered heating/cooling rates  altered Tequil. • dissociation/formation of H2 and CO change differently with Z  standard XCO factors yield incorrect results  molecular gas in low-Z systems not well traced by CO. temperature structure and chemical stratification depend on metallicity Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

19. Low Z PDRs Temperature determined by balancing heating and cooling At the Surface: 4 primary h/c processes: • PE heating • H2 vib. de-excitation • [CII] 158µm fine-structure cooling • [OI] 63µm fine-structure cooling Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

20. Low Z PDRs n [OI] [CII]  PE H2*  PE~Z  H2*~Z/(1+2 Z) T~1 /(1+2 Z) • [OI]  [CII] •  PE H2*  PE~Z2 • H2*~Z T~Z  [OI] [CII]  PE H2*  PE~Z…Z1.5  H2*~Z T~Z0.5…Z [OI] [CII]  PE H2*  PE~Z  H2*~Z T~const. Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

21. Low Z PDRs Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

22. Low Z PDRs Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

23. Low Z PDRs Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

24. C +   C+ + e- C++ H2 CH2++  Low Z PDRs Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

25. [CII]/CO(1-0) LMC [CII] Nakagawa et al. 2005 Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

26. [CII]/CO(1-0) line integrated, clump averaged surface brightness of [CII]158µm Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

27. [CII]/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

28. [CII]/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

29. [CII]/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

30. [CII]/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

31. [CI]610µm/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

32. Galactic values [CI]610µm/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

33. [CI]610µm/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

34. [CI]610µm/CO(1-0) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

35. Modeling the MW COBE-FIRAS:far-infrared survey of the spectral line emission from the Galaxy with a 7° beam (Fixsen et al. 1999) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

36. Modeling the MW • a single, spherical clump scenario is a very special case • usually molecular clouds have a highly irregular, clumpy structure, far from simple plane-parallel or spherical model clouds • furthermore, molecular clouds are embedded in atomic gas, also contributing to the total emission Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

37. Modeling the MW • observations show an almost universal clump-mass distribution with dN/dMM-1.6…1.8 and a mass-size relation of MR2.3 (Kramer et al. 1998) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

38. Modeling the MW Credit: NASA/JPL-Caltech/R. Hurt (SSC) • MW as disk with Rtot=18kpc and h=59pc • n, , and Z as function of galactocentric radius (Wolfire et al. 2003) • n(R)=104cm-3, (R)=3 • molecular gas distributed according to C-M and M-S relation • COBE beam (1°5°) • area- and volume filling per concentric ring  (Fixsen et al. 1999) Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

39. Modeling the MW Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

40. Modeling the MW Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

41. Modeling the MW Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

42. Modeling the MW =100 =3 Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

43. Summary • KOSMA- model, a spherical PDR code featuring isotropic FUV illumination and a highly modular chemistry • Z-dependence of the gas temperature in PDR • Z-dependence of the C+-layer • Influence of geometrical beam filling on the total surface brightness • Observational trend in Galactic and extragalactic [CII]/CO(1-0) with metallicity observations can be explained with spherical PDR model results Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

44. Summary • The connection between [CI]/CO(1-0) and Z is more complicated, but again the observational trend can be reproduced • By applying C-M spectra and M-S relations to the KOSMA- database it is possible to analyze large surveys, i.e. observations with large beam filling → application to a simple MW-model in order to explain COBE results as PDR emission ([CII] can only be explained partly) • Clump-ensemble approach suitable for any single position observation, face-on galaxy scan, etc. with considerable beam filling. Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

45. Thank you for your attention! Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

46. http://www.ph1.uni-koeln.de/workgroups/theo_astronomy/pdr/ Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

47. Modeling the MW Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective

48. C+ C CO Z=1 Z=0.5 Z=0.1 Workshop in Extragalactic and Galactic ISM - Modelling in an ALMA Perspective