Hydro-chemical study of the evolution of interstellar pre-biotic molecules during the collapse of molecular clouds

TL;DR

This study uses quantum chemical theory within a hydro-chemical model to investigate the formation and evolution of interstellar pre-biotic molecules during molecular cloud collapse, highlighting the importance of reaction rates and grain effects.

Contribution

It introduces quantum chemically derived rate coefficients into a hydro-chemical model to more accurately simulate pre-biotic molecule formation during star formation.

Findings

Significant pre-biotic molecules can form during proto-star collapse.

Formation pathways depend on reactive species and rate coefficients.

Grains influence gas-phase molecule abundances.

Abstract

One of the stumbling blocks for studying the evolution of interstellar molecules is the lack of adequate knowledge of the rate co-efficients of various reactions which take place in the Interstellar medium and molecular clouds. Some of the theoretical models of rate coefficients do exist in the literature for computing abundances of the complex pre-biotic molecules. So far these have been used to study the abundances of these molecules in space. However, in order to obtain more accurate final compositions in these media, we find out the rate coefficients for the formation of some of the most important interstellar pre-biotic molecules by using quantum chemical theory. We use these rates inside our hydro-chemical model to find out the chemical evolution and the final abundances of the pre-biotic species during the collapsing phase of a proto-star. We find that a significant amount of various pre-biotic molecules could be produced during the collapsing phase of a proto-star. We study extensively the formation these molecules via successive neutral-neutral and radical-radical/radical-molecular reactions. We present the time evolution of the chemical species with an emphasis on how the production of these molecules varies with the depth of a cloud. We compare the formation of adenine in the interstellar space using our rate-coefficients and using those obtained from the existing theoretical models. Formation routes of the pre-biotic molecules are found to be highly dependent on the abundances of the reactive species and the rate coefficients involved in the reactions. Presence of grains strongly affect the abundances of the gas phase species. We also carry out a comparative study between different pathways available for the synthesis of adenine, alanine, glycine and other molecules considered in our network.