Formation of hydroxy, cyano and ethynyl derivatives of C4H4 isomers in the interstellar medium

TL;DR

This study uses high-level quantum calculations to explore the formation and stability of hydroxy, cyano, and ethynyl derivatives of C4H4 isomers in the interstellar medium, suggesting potential targets for astronomical detection.

Contribution

It provides the first detailed theoretical analysis of the formation pathways and stability of these derivatives, highlighting promising candidates for interstellar detection.

Findings

Exothermic formation pathways for CN and CCH derivatives with no activation barriers.

Less favorable formation of OH derivatives.

C-C4H3CN and C-C4H3CCH are promising for detection if C4H4 is present in space.

Abstract

The study of cyclic hydrocarbons is of utmost relevance in current astrochemical research, as they are considered to be among the most significant reservoirs of carbon in the interstellar medium. However, while unsaturated cyclic hydrocarbons with three, five, and six carbon atoms have been widely investigated, the highly strained antiaromatic cyclobutadiene, c-C4H4, still remains uncharted. Here, we employed high-level CCSD(T)-F12/cc-pVTZ-F12//B2PLYPD3/aug-cc-pVTZ theoretical calculations to analyze whether the cyano (CN), ethynyl (CCH), and hydroxy (OH) derivatives of c-C4H4 and its structural isomers butatriene (H2CCCCH2) and vinylacetylene (H2CCHCCH) can readily form via the gas-phase reaction: C4H4 + X -> C4H3X + H (where X = CN, CCH, and OH). For each system, we thoroughly explored the corresponding potential energy surfaces, identifying their critical points to enable a detailed analysis of the thermochemistry. Hence, we found various exothermic pathways for the formation of CN and CCH derivatives of butatriene and vinylacetylene, with no net activation barriers, while the formation of the OH derivatives is in general less favorable. Prior to the mechanistic study, we also analyzed the complete conformational panorama and stability of all the derivatives at the CCSD(T)-F12/cc-pVTZ-F12 level. Overall, c-C4H3CN and c-C4H3CCH emerge as particularly promising candidates for interstellar detection, provided that the parental c-C4H4 is present in the gas phase. These findings highlight the potential for detecting polar derivatives of c-C4H4 as indirect evidence of its presence in the ISM, as it appears to be "invisible" to radioastronomical observations. Also, this study underscores the need for future laboratory and theoretical efforts to characterize the spectroscopic properties of the proposed derivatives, paving the way for their eventual identification in space.