The 2024 KIDA network for interstellar chemistry

TL;DR

The paper introduces an updated astrochemical network, kida.uva.2024, incorporating recent reaction data and ice chemistry, to improve modeling of interstellar medium compositions and compare predictions with observations.

Contribution

It presents the new kida.uva.2024 network, integrating gas-phase and ice surface chemistry, with updated reactions and code for modeling interstellar medium chemistry.

Findings

Model predictions differ significantly for some species.

The new network aligns similarly with observations as previous versions.

Revised reactions improve the accuracy of astrochemical models.

Abstract

The study of the chemical composition of the interstellar medium (ISM) requires a strong synergy between laboratory astrophysics, modeling, and observations. In particular, astrochemical models have been developed for decades now and include an increasing number of processes studied in the laboratory or theoretically. These models follow the chemistry both in the gas phase and at the surface of interstellar grains. Since 2012, we have provided complete gas-phase chemical networks for astrochemical codes that can be used to model various environments of the ISM. Our aim is to introduce the new up-to-date astrochemical network kida.uva.2024 together with the ice chemical network and the fortran code to compute time dependent compositions of the gas, the ice surface, and the ice mantles under physical conditions relevant for the ISM. The gas-phase chemical reactions, as well as associated rate coefficients, included in kida.uva.2024 were carefully selected from the KIDA online database and represent the most recent values. The model predictions for cold core conditions and for when considering only gas-phase processes were computed as a function of time and compared to the predictions obtained with the previous version, kida.uva.2014. In addition, key chemical reactions were identified. The model predictions, including both gas and surface processes, were compared to the molecular abundances as observed in the cold core TMC1-CP. Many gas-phase reactions were revised or added to produce kida.uva.2024. The new model predictions are different by several orders of magnitude for some species. The agreement of this new model with observations in TMC-1 (CP) is, however, similar to the one obtained with the previous network.