Cold molecular gas in the hot nuclear wind of the Milky Way

TL;DR

This study investigates the presence and properties of cold molecular gas in the Milky Way's nuclear wind, providing upper limits on molecular mass and insights into the stability and dynamics of gas clouds within the Fermi Bubble.

Contribution

First detection of molecular line emission in specific atomic clouds associated with the Milky Way's Fermi Bubble, with derived physical conditions and mass estimates.

Findings

No 12CO or 13CO emission from one cloud; detection of 12CO in another.

Upper limit on molecular mass in the detected cloud is 132 solar masses.

Clumps are likely pressure-confined or disrupted by shear and expansion.

Abstract

Using the Large Millimeter Telescope and the SEQUOIA 3~mm focal plane array, we have searched for molecular line emission from two atomic clouds associated with the Fermi Bubble of the Milky Way. Neither 12CO nor 13CO J=1-0 emission is detected from the HI cloud, MW-C20. 12CO J=1-0 emission is detected from MW-C21 that is distributed within 11 clumps with most of the CO luminosity coming from a single clump. However, we find no 13CO emission to a 3sigma brightness temperature limit of 0.3 K. Using this limit and RADEX non local thermodynamic equilibrium (non-LTE) excitation models, we derive H2 column density upper limits of (0.4-3)x10^{21} cm-2 for a set of physical conditions and a H2 to 12CO abundance ratio of 10^4. Model CO-to-H2 conversion factors are derived for each set of physical conditions. We find the maximum value is 1.6x10^{20} cm-2/(K km/s). Increasing [H2/12CO] to 10^5 to account for photodissociation and cosmic ray ionization increases the column density and XCO upper limits by a factor of 10. Applying these XCO limits to the CO luminosities, the upper limit to the total molecular mass in MW-C21 is 132+/-2~Msun, corresponding to less than 27% of the neutral gas mass. For the three clumps that are fully resolved, lower limits to the virial ratios are 288+/-32, 68+/-28, and 157+/-39, which suggest that these structures are bound by external pressure to remain dynamically stable over the entrainment time of 2x10^6 years or are being disrupted by shear and expansion over the clump crossing times of (3-8)x10^5 years. The observations presented in this study add to the growing census of cold gas entrained within the Galactic Center wind.