Abstract
Detections of CO, CS, SO, C2H, HCO+, HCN, HNC, H2CO, and C3H2 are reported from LIRS 36, a star-forming region in the Small Magellanic Cloud. (CO)-O-18, NO, CH3OH, and most notably CN have not been detected, while the rare isotopes (CO)-C-13 and, tentatively, (CS)-S-34 ar,seen. This is so far the most extensive molecular multiline study of an interstellar medium with a heavy element depletion exceeding a factor of four.
The X = N(H-2)/I-CO conversion factor is approximate to 4.8 x 10(21) cm(-2) (K km s(-1))(-1), slightly larger than the local Galactic disk value. The CO (1-0) beam averaged column density then becomes N(H-2) approximate to 3.7 x 10(21) cm(-2) and the density n (H-2) approximate to 100 cm(-3). A comparison with X-values from Rubio et al. (1993a) shows that on small scales (R approximate to 10 pc) X-values are more similar to Galactic disk values than previously anticipated, favoring a neutral interstellar medium of predominantly molecular nature in the cores. The I((CO)-C-13)/I((CO)-O-18) line intensity ratio indicates an underabundance of (CO)-C-12-O-18 relative to (CO)-C-13-O-16 w.r.t. Galactic clouds. I(HCO+)/I(HCN) and I(HCN)/I(HNC) line intensity ratios are > 1 and trace a warm (T-kin > 10 K) molecular gas exposed to a high ionizing flux. Detections of the CS J=2-1, 3-2, and 5-4 lines imply the presence of a high density core with n (H-2) = 10(5) - 10(7) cm(-3). In contrast to star-forming regions in the LMC, the CN 1-0 line is substantially weaker than the corresponding ground rotational transitions of HCN, HNC, and CS. CO, CS, HCO+, and H2CO fractional abundances are a factor approximate to 10 smaller than corresponding values in Galactic disk clouds. Fractional abundances of HCN, HNC, and likely CN are even two orders of magnitude below their 'normal', Galactic disk values. The CN/CS abundance ratio is less than or equal to 1. Based on chemical model calculations, we suggest that this is because of the small metallicity of the SMC, which affects the destruction of CN but not CS, and because of the high molecular core density which also favors CN destruction.