Nitrogen chemistry and depletion in starless cores

TL;DR

This study examines nitrogen-bearing molecules in starless cores, revealing their persistence in dense regions and highlighting the complexity of nitrogen chemistry and depletion processes in early star formation stages.

Contribution

It provides new observational data on nitrogen species in starless cores and compares these with collapse models, advancing understanding of nitrogen chemistry in dense interstellar environments.

Findings

CN, HCN, and HNC remain in the gas phase at high densities.

Abundance ratios of CN:HCN and HNC:HCN are consistently greater than one.

Nitrogen may be predominantly locked in ices, affecting chemical models.

Abstract

We investigated the chemistry of nitrogen--containing species, principally isotopomers of CN, HCN, and HNC, in a sample of pre-protostellar cores. We used the IRAM 30 m telescope to measure the emission in rotational and hyperfine transitions of CN, HCN, 13CN, H13CN, HN13C, and HC15N, in L 1544, L 183, Oph D, L 1517B, L 310. The observations were made along axial cuts through the dust emission peak, at a number of regularly--spaced offset positions. The observations were reduced and analyzed to obtain the column densities, using the measurements of the less abundant isotopic variants in order to minimize the consequences of finite optical depths in the lines. The observations were compared with the predictions of a free--fall gravitational collapse model, which incorporates a non-equilibrium treatment of the relevant chemistry. We found that CN, HCN, and HNC remain present in the gas phase at densities well above that at which CO depletes on to grains. The CN:HCN and the HNC:HCN abundance ratios are larger than unity in all the objects of our sample. Furthermore, there is no observational evidence for large variations of these ratios with increasing offset from the dust emission peak and hence with density. Whilst the differential freeze--out of CN and CO can be understood in terms of the current chemistry, the behaviour of the CN:HCN ratio is more difficult to explain. Models suggest that most nitrogen is not in the gas phase but may be locked in ices. Unambiguous conclusions require measurements of the rate coefficients of the key neutral--neutral reactions at low temperatures.