Kinematics of HI Envelopes Associated with Molecular Clouds

Abstract

We investigate the evolution of molecular clouds through the kinematics of their atomic hydrogen (HI) envelopes, using 12CO and 21-cm emission to trace the molecular and atomic gas, respectively. We measure the large-scale gradients, , in the velocity fields of 22 molecular clouds and their HI envelopes, then calculate their specific angular momenta, j R2. The molecular clouds have a median velocity gradient of 9.6× 10-2\ km\ s-1\ pc-1, and a typical specific angular momentum of 2.7 × 1024\ cm2\ s-1. The HI envelopes have smaller velocity gradients than their respective molecular clouds, with an average of HI = 0.03\ km\ s-1\ pc-1, and a median angular momentum of jHI ≈ 5.7 × 1024\ cm2\ s-1. For a majority of the systems, jHI > jH2, with an average of jHI/jH2 = 4. Their velocity gradient directions tend to be misaligned, indicating that angular momentum is not conserved during molecular cloud formation. Both populations exhibit a j-R scaling consistent with that expected of supersonic turbulence: jH2 R1.67 0.22, and jHI R1.71 0.27. Combining our measurements with previous observations, we demonstrate a scaling of j R1.50 0.02 in star-forming regions spanning 5 dex in size, R∈ (10-3,\ 102) \ pc. We construct a model of angular momentum transport during molecular cloud formation, and derive the angular momenta of the progenitors to the present-day systems. We calculate a typical angular momentum redistribution timescale of 13 Myr, comparable to the HI envelope free-fall times.