Formation of complex organics by covalent and non-covalent interactions of the sequential reactions of 1-4 acrylonitrile molecules with the benzonitrile radical cation

Benzonitrile molecules are present in ionizing environments including interstellar clouds and solar nebulae, where their ions can form adducts with neutral molecules such as acrylonitrile leading to the formation of a variety of nitrogen-containing complex organics. Herein, we report on the formation of complex organics by the sequential reactions of 1-4 acrylonitrile (C 3 NH 3 ) molecules with the benzonitrile radical cation (C 7 NH 5 + &z.rad;). The results reveal the formation of the covalently bonded N -acrylonitrile-benzonitrile radical cation (C 10 N 2 H 8 + &z.rad;) with a rate coefficient of 2.2 (±0.4) × 10 −11 cm 3 s −1 at 423 K and a calculated collision cross-section of 73.8 Å 2 in good agreement with the measured cross-section of 70.7 Å 2 of the C 10 N 2 H 8 + &z.rad; adduct. Subsequent reversible association of 1-3 acrylonitrile molecules with the N -acrylonitrile-benzonitrile radical cation (C 10 N 2 H 8 + &z.rad;) at lower temperatures (250-200 K) results in the formation of the N-rich clusters (C 10 N 2 H 8 + &z.rad;)(C 3 NH 3 ) 1-3 which can be enhanced in the very cold cores of the interstellar medium (ISM) and could offer unique potential candidates for the substantial amount of nitrogen carriers detected in the emission spectra of the ISM. The observed N -acrylonitrile-benzonitrile covalent adduct and its associated acrylonitrile clusters could have significant implications in the formation of different types of complex organics in different regions of outer space. It is anticipated that the current results would have direct implications in the search for nitrogen-containing complex organics in space. N -acrylonitrile-benzonitrile radical cation (C 10 N 2 H 8 +* ) can act as a core ion for the clustering of multiple acrylonitrile molecules thus generating nitrogen-rich complex organics in the cold environments of space.