Theoretical Insights into a Novel Ion–Ion Reaction of Methane in the Initial Stages of Hydrocarbon Growth in Space

In this article, we examine the reactions between methane molecules as a starting point for hydrocarbon growth in space and assess the effectiveness of the ion–ion reaction between CH4 + and CH4 + using quantum mechanical and molecular dynamics methods. We modeled the reaction starting from the dica...

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Bibliographic Details
Published in:ACS earth and space chemistry 2024-12, Vol.8 (12), p.2557-2573
Main Author: Matsubara, Toshiaki
Format: Article
Language:English
Online Access:Get full text
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Summary:In this article, we examine the reactions between methane molecules as a starting point for hydrocarbon growth in space and assess the effectiveness of the ion–ion reaction between CH4 + and CH4 + using quantum mechanical and molecular dynamics methods. We modeled the reaction starting from the dicationically ionized [CH4···CH4]2+ cluster. Initially, attractive interactions occur between the facing C–H bonds of the tetrahedral structures, which are electron-deficient. As the structure transitions to a trigonal pyramid, a bond begins to form between two carbon atoms with unpaired electrons, resulting in a metastable configuration due to the balance between Coulombic repulsion and attractive forces. The stabilization energy for C–C bond formation was 176.8 kcal/mol, with a bond formation efficiency of 32.6%, and the corresponding rate coefficient was 1.394 × 10–2 fs–1. This stabilization by C–C bond formation generates kinetic energy, and if sufficient energy is redistributed to the vibrational mode of the reaction, the reaction can proceed. Reactions involving C–C bond formation produced precursors of ethane, ethylene, and acetylene, such as C2H6 2+, C2H5 +, C2H4 +, and C2H3 +, as well as CH3 +, a key species in ion–molecule reactions in space. Even without C–C bond formation, a significant amount of CH3 + was produced. Our findings underscore the importance of exploring novel ion–ion reactions to deepen our understanding of molecular growth in space.
ISSN:2472-3452
2472-3452
DOI:10.1021/acsearthspacechem.4c00242