Depletion and fractionation of nitrogen in collapsing cores

Measurements of the nitrogen isotopic ratio in Solar System comets show a constant value, ≈140, which is three times lower than the protosolar ratio, a highly significant difference that remains unexplained. Observations of static starless cores at early stages of collapse confirm the theoretical ex...

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Bibliographic Details
Published in:Astronomy and astrophysics (Berlin) 2020-11, Vol.643, p.A76
Main Authors: Hily-Blant, P., Pineau des Forêts, G., Faure, A., Flower, D. R.
Format: Article
Language:English
Subjects:
Adsorption
Ammonia
Astrophysics
Charge exchange
Chemical effects
Chemical reactions
Comets
Depletion
Deuteration
Fractionation
Gravitational collapse
Interstellar chemistry
Interstellar matter
Low temperature
Nebulae
Nitrogen
Nitrogen isotopes
Physics
Planet formation
Protoplanetary disks
Vapor phases
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Summary:Measurements of the nitrogen isotopic ratio in Solar System comets show a constant value, ≈140, which is three times lower than the protosolar ratio, a highly significant difference that remains unexplained. Observations of static starless cores at early stages of collapse confirm the theoretical expectation that nitrogen fractionation in interstellar conditions is marginal for most species. Yet, observed isotopic ratios in N 2 H + are at variance with model predictions. These gaps in our understanding of how the isotopic reservoirs of nitrogen evolve, from interstellar clouds to comets, and, more generally, to protosolar nebulae, may have their origin in missing processes or misconceptions in the chemistry of interstellar nitrogen. So far, theoretical studies of nitrogen fractionation in starless cores have addressed the quasi-static phase of their evolution such that the effect of dynamical collapse on the isotopic ratio is not known. In this paper, we investigate the fractionation of 14 N and 15 N during the gravitational collapse of a pre-stellar core through gas-phase and grain adsorption and desorption reactions. The initial chemical conditions, which are obtained in steady state after typically a few Myr, show low degrees of fractionation in the gas phase, in agreement with earlier studies. However, during collapse, the differential rate of adsorption of 14 N- and 15 N-containing species onto grains results in enhanced 15 N: 14 N ratios, in better agreement with the observations. Furthermore, we find differences in the behavior, with increasing density, of the isotopic ratio in different species. We find that the collapse must take place on approximately one free-fall timescale, based on the CO abundance profile in L183. Various chemical effects that bring models into better agreement with observations are considered. Thus, the observed values of 14 N 2 H + :N 15 NH + and 14 N 2 H + : 15 NNH + could be explained by different temperature dependences of the rates of dissociative recombination of these species. We also study the impact of the isotopic sensitivity of the charge-exchange reaction of N 2 with He + on the fractionation of ammonia and its singly deuterated analog and find significant depletion in the 15 N variants. However, these chemical processes require further experimental and theoretical investigations, especially at low temperature. These new findings, such as the depletion-driven fractionation, may also be relevant to the dense, UV-s
ISSN:0004-6361
1432-0746
1432-0756
DOI:10.1051/0004-6361/202038780