Computational study of the dissociation reactions of secondary ozonide

M.H. Almatarneh; S.F. Alrebei; M. Altarawneh; Y. Zhao; A.Al-A. Abu-Saleh

doi:10.3390/atmos11010100

Back

Computational study of the dissociation reactions of secondary ozonide

Journal article

Open access

Peer reviewed

Computational study of the dissociation reactions of secondary ozonide

M.H. Almatarneh, S.F. Alrebei, M. Altarawneh, Y. Zhao and A.Al-A. Abu-Saleh

Atmosphere, Vol.11(1), Article 100

2020

DOI: https://doi.org/10.3390/atmos11010100

Files and links (2)

pdf

Computational study of the dissociation reactions of secondary ozonide.pdfDownload View

Published (Version of Record) Open Access

url

Free to Read *No subscription requiredView

Abstract

This contribution presents a comprehensive computational study on the reactions of secondary ozonide (SOZ) with ammonia and water molecules. The mechanisms were studied in both a vacuum and the aqueous medium. All the molecular geometries were optimized using the B3LYP functional in conjunction with several basis sets. M06-2X, APFD, and ωB97XD functionals with the full basis set were also used. In addition, single-point energy calculations were performed with the G4MP2 and G3MP2 methods. Five different mechanistic pathways were studied for the reaction of SOZ with ammonia and water molecules. The most plausible mechanism for the reaction of SOZ with ammonia yields HC(O)OH, NH3, and HCHO as products, with ammonia herein acting as a mediator. This pathway is exothermic and exergonic, with an overall barrier height of only 157 kJ mol−1 using the G3MP2 method. All the reaction pathways between SOZ and water molecules are endothermic and endergonic reactions. The most likely reaction pathway for the reaction of SOZ with water involves a water dimer, in which the second water molecule acts as a mediator, with an overall barrier height of only 135 kJ mol−1 using the G3MP2 method. Solvent effects were found to incur a significant reduction in activation energies. When the second H2O molecule acts as a mediator in the reaction of SOZ with water, the barrier height of the rate-determining step state decreases significantly.

Details

Title: Computational study of the dissociation reactions of secondary ozonide
Authors/Creators: M.H. Almatarneh (Author/Creator)
S.F. Alrebei (Author/Creator)
M. Altarawneh (Author/Creator)
Y. Zhao (Author/Creator)
A.Al-A. Abu-Saleh (Author/Creator)
Publication Details: Atmosphere, Vol.11(1), Article 100
Publisher: MDPI
Identifiers: 991005541784807891
Copyright: © 2020 by the authors. Licensee MDPI, Basel, Switzerland.
Murdoch Affiliation: Murdoch University
Language: English
Resource Type: Journal article

UN Sustainable Development Goals (SDGs)

This output has contributed to the advancement of the following goals:

Source: InCites

Metrics

33 File views/ downloads

101 Record Views

5 Times Cited - Web of Science

InCites Highlights

These are selected metrics from InCites Benchmarking & Analytics tool, related to this output

Collaboration types: Domestic collaboration; International collaboration
Citation topics: 8 Earth Sciences; 8.124 Environmental Sciences; 8.124.10 Atmospheric Aerosols
Web Of Science research areas: Environmental Sciences; Meteorology & Atmospheric Sciences
ESI research areas: Geosciences