Grupo de Sistemas Estelares

Kong, S.; Lada, C. J.; Lada, E. A.; Román-Zúñiga, C.; Bieging, J. H.; Lombardi, M.; Forbrich, J.; Alves, J. F.
The Astrophysical Journal, Volume 805, Issue 1, article id. 58, 19 pp. (2015).
05/2015

ABSTRACT

We present results of an extinction-CO line survey of the southeastern part of the California molecular cloud (CMC). Deep, wide-field, near-infrared images were used to construct a sensitive, relatively high resolution (˜0.5 arcmin) (NICEST) extinction map of the region. The same region was also surveyed in the ¹²CO(2-1), ¹³CO(2-1), and C¹⁸O(2-1) emission lines at the same angular resolution. These data were used to investigate the relation between the molecular gas, traced by CO emission lines, and the dust column density, traced by extinction, on spatial scales of 0.04 pc across the cloud. We found strong spatial variations in the abundances of ¹³CO and C¹⁸O that were correlated with variations in gas temperature, consistent with temperature-dependent CO depletion/desorption on dust grains. The ¹³CO-to-C¹⁸O abundance ratio was found to increase with decreasing extinction, suggesting selective photodissociation of C¹⁸O by the ambient UV radiation field. The effect is particularly pronounced in the vicinity of an embedded cluster where the UV radiation appears to have penetrated deeply (i.e., {{A}_V} ≲ 15 mag) into the cloud. We derived the cloud-averaged X-factor to be < X_CO > = 2.53 × 10²⁰ c{{m}^-2}{{≤ft( K km {{s}^-1} \right)}^-1}, a value somewhat higher than the Milky Way average. On sub-parsec scales we find there is no single empirical value of the ¹²CO X-factor that can characterize the molecular gas in cold (T_k ≲ 15 K) cloud regions, with X_CO ∝ A_V^0.74 for {{A}_V} ≳ 3 mag. However, in regions containing relatively hot (T_ex ≳ 25 K) molecular gas we find a clear correlation between W(¹²CO) and {{A}_V} over a large (3 ≲ {{A}_V} ≲ 25 mag) range of extinction. This results in a constant X_CO = 1.5 × 10²⁰ c{{m}^-2} {{≤ft( K km {{s}^-1} \right)}^-1} for the hot gas, a lower value than either the average for the CMC or the Milky Way. Overall we find an (inverse) correlation between X_CO and T_ex in the cloud with X_CO ∝ T_ex ^-0.7. This correlation suggests that the global X-factor of a giant molecular cloud may depend on the relative amounts of hot gas contained within the cloud.