Catching the Birth of a Dark Molecular Cloud for the First Time

Abstract

The majority of hydrogen in the interstellar medium (ISM) is in atomic form. The transition from atoms to molecules and, in particular, the formation of the H2 molecule, is a key step in cosmic structure formation en route to stars. Quantifying H2 formation in space is difficult, due to the confusion in the emission of atomic hydrogen (HI) and the lack of a H2 signal from the cold ISM. Here we present the discovery of a rare, isolated dark cloud currently undergoing H2 formation, as evidenced by a prominent "ring" of HI self-absorption. Through a combined analysis of HI narrow self-absorption, CO emission, dust emission, and extinction, we directly measured, for the first time, the [HI]/[H2] abundance varying from 2% to 0.2%, within one region. These measured HI abundances are orders of magnitude higher than usually assumed initial conditions for protoplanetary disk models. None of the fast cloud formation model could produce such low atomic hydrogen abundance. We derived a cloud formation timescale of 6×106 years, consistent with the global Galactic star formation rate, and favoring the classical star formation picture over fast star formation models. Our measurements also help constrain the H2 formation rate, under various ISM conditions.