Nitrogen and hydrogen fractionation in high-mass star forming cores from observations of HCN and HNC

Abstract

The ratio between the two stable isotopes of nitrogen, 14N and 15N, is well measured in the terrestrial atmosphere ( 272), and in the pre-Solar nebula ( 441). Interestingly, some pristine Solar System materials show enrichments in 15N with respect to the pre-Solar nebula value. However, it is not yet clear if, and how, these enrichments are linked to the past chemical history, due to the limited number of measurements in dense star-forming regions. In this respect, dense cores believed to be precursors of clusters containing also intermediate- and high-mass stars are important targets, as the Solar System was probably born within a rich stellar cluster. In this work, we show the results of IRAM-30m observations of the J=1-0 rotational transition of the molecules HCN and HNC, and their 15N-bearing counterparts, towards 27 intermediate/high-mass dense cores divided in three evolutionary categories: high-mass starless cores, high-mass protostellar objects, and ultra-compact HII regions. We have also observed the DNC(2-1) rotational transition, in order to search for a relation between the isotopic ratios D/H and 14N/15N. We derive average 14N/15N ratios of 35916 in HCN and of 43821 in HNC, with a dispersion of about 150-200. We find no trend of the 14N/15N ratio with the evolutionary stage. This result agrees with what found from N2H+ and its isotopologues in the same sources, although the 14N/15N ratios from N2H+ show a dispersion larger than that in HCN/HNC. Moreover, we have found no correlation between D/H and 14N/15N in HNC. These findings indicate that: (1) the chemical evolution does not seem to play a role in the fractionation of nitrogen; (2) the fractionation of hydrogen and nitrogen in these objects are not related.