Dense Clumps in Giant Molecular Clouds in the Large Magellanic Cloud: Density and Temperature Derived from 13CO(J=3-2) Observations

Abstract

In order to precisely determine temperature and density of molecular gas in the Large Magellanic Cloud, we made observations of optically thin 13CO(J=3-2) transition by using the ASTE 10m telescope toward 9 peaks where 12CO(J=3-2) clumps were previously detected with the same telescope. The molecular clumps include those in giant molecular cloud (GMC) Types I (with no signs of massive star formation), II (with HII regions only), and III (with HII regions and young star clusters). We detected 13CO(J=3-2) emission toward all the peaks and found that their intensities are 3 -- 12 times lower than those of 12CO(J=3-2). We determined the intensity ratios of 12CO(J=3-2) to 13CO(J=3-2), R12/133-2, and 13CO(J=3-2) to 13CO(J=1-0), R133-2/1-0, at 45 resolution. These ratios were used for radiative transfer calculations in order to estimate temperature and density of the clumps. The parameters of these clumps range kinetic temperature Tkin = 15 -- 200 K, and molecular hydrogen gas density n(H2) = 8× 102 -- 7× 103 cm-3. We confirmed that the higher density clumps show higher kinetic temperature and that the lower density clumps lower kinetic temperature at a better accuracy than in the previous work. The kinetic temperature and density increase generally from a Type I GMC to a Type III GMC. We interpret that this difference reflects an evolutionary trend of star formation in molecular clumps. The R133-2/1-0 and kinetic temperature of the clumps are well correlated with Hα flux, suggesting that the heating of molecular gas n(H2) = 103 -- 104 cm-3 can be explained by stellar FUV photons.