# Reactivity of the Ethenium Cation (C2H5+) with Ethyne (C2H2): A Combined Experimental and Theoretical Study

**Authors:** Vincent Richardson, Miroslav Polášek, Claire Romanzin, Paolo Tosi, Roland Thissen, Christian Alcaraz, Ján Žabka, Daniela Ascenzi

PMC · DOI: 10.3390/molecules29040810 · Molecules · 2024-02-09

## TL;DR

This study investigates the gas-phase reaction between ethyl cation and ethyne, revealing key reaction pathways and their relevance to interstellar and plasma chemistry.

## Contribution

The paper provides new insights into the reaction mechanisms and energy-dependent reactivity of ethyl cation with ethyne through combined experimental and theoretical approaches.

## Key findings

- Two main product channels were identified with branching ratios of 0.76±0.05 and 0.22±0.02 at low collision energy.
- A third reaction channel emerges at high internal excitation and collision energies.
- Theoretical calculations reveal a common intermediate leading to different product isomers via barrierless pathways.

## Abstract

The gas-phase reaction between the ethyl cation (C2H5+) and ethyne (C2H2) is re-investigated by measuring absolute reactive cross sections (CSs) and branching ratios (BRs) as a function of collision energy, in the thermal and hyperthermal energy range, via tandem-guided ion beam mass spectrometry under single collision conditions. Dissociative photoionization of C2H5Br using tuneable VUV radiation in the range 10.5–14.0 eV is employed to generate C2H5+, which has also allowed us to explore the impact of increasing (vibrational) excitation on the reactivity. Reactivity experiments are complemented by theoretical calculations, at the G4 level of theory, of the relative energies and structures of the most relevant stationary points on the reactive potential energy hypersurface (PES) and by mass-analyzed ion kinetic energy (MIKE) spectrometry experiments to probe the metastable decomposition from the [C4H7]+ PES and elucidate the underlying reaction mechanisms. Two main product channels have been identified at a centre-of-mass collision energy of ∼0.1 eV: (a) C3H3++CH4, with BR = 0.76±0.05 and (b) C4H5++H2, with BR = 0.22±0.02. A third channel giving C2H3+ in association with C2H4 is shown to emerge at both high internal excitation of C2H5+ and high collision energies. From CS measurements, energy-dependent total rate constants in the range 4.3×10−11−5.2×10−10 cm3·molecule−1·s−1 have been obtained. Theoretical calculations indicate that both channels stem from a common covalently bound intermediate, CH3CH2CHCH+, from which barrierless and exothermic pathways exist for the production of both cyclic c−C3H3+ and linear H2CCCH+ isomers of the main product channel. For the minor C4H5+ product, two isomers are energetically accessible: the three-member cyclic isomer c−C3H2(CH3)+ and the higher energy linear structure CH2CHCCH2+, but their formation requires multiple isomerization steps and passages via transition states lying only 0.11 eV below the reagents’ energy, thus explaining the smaller BR. Results have implications for the modeling of hydrocarbon chemistry in the interstellar medium and the atmospheres of planets and satellites as well as in laboratory plasmas (e.g., plasma-enhanced chemical vapor deposition of carbon nanotubes and diamond-like carbon films).

## Linked entities

- **Chemicals:** C2H5+ (PubChem CID 123138), C2H2 (PubChem CID 6326), CH4 (PubChem CID 297), H2 (PubChem CID 783), C2H3+ (PubChem CID 123166), C2H4 (PubChem CID 6325)

## Full-text entities

- **Chemicals:** C2H2 (-), diamond (MESH:D018130), carbon nanotubes (MESH:D037742), Ethyne (MESH:D000114), hydrocarbon (MESH:D006838), C2H4 (MESH:C036216), CH4 (MESH:D008697), carbon (MESH:D002244), C2H5Br (MESH:C037311)

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC10892252/full.md

## References

98 references — full list in the complete paper: https://tomesphere.com/paper/PMC10892252/full.md

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Source: https://tomesphere.com/paper/PMC10892252