The role of aldehydes on sulfur based-new particle formation: a theoretical study

• Published in: RSC advances Vol. 14; no. 19; pp. 13321 - 13335
• Main Authors: Zhang, Guohua, Liu, Min, Han, Yaning, Wang, Zhongteng, Liu, Wei, Zhang, Ying, Xu, Jing
• Format: Journal Article
• Language: English
• Published: England Royal Society of Chemistry 22.04.2024; The Royal Society of Chemistry
• Subjects: Acids; Alcohols; Aldehydes; Atmospheric chemistry; Chemical bonds; Chemistry; Clusters; Hydrogen bonds; Ion pairs; Molecular dynamics; Nucleation; Protons; Quantum chemistry; Stability; Sulfur; Synergistic effect; Ternary systems
• ISSN: 2046-2069; 2046-2069
• DOI: 10.1039/d4ra00952e

Aldehydes play a crucial role in the formation of atmospheric particles, attracting significant attention due to their environmental impact. However, the microscopic mechanisms underlying the formation of aldehyde-involved particles remain uncertain. In this study, through quantum chemical calculations and molecular dynamics (MD) simulations, we investigate the microscopic formation mechanisms of binary and ternary systems composed of three representative aldehydes, two sulfur-based acids, water, and two bases. Our research findings reveal that the most stable structures of acid-aldehyde clusters involve the connection of acids and aldehyde compounds through hydrogen bonds without involving proton transfer reactions, indicating relatively poor cluster stability. However, with the introduction of a third component, the stability of 18 clusters significantly increase. Among these, in ten systems, acids act as catalysts, facilitating reactions between aldehyde compounds and water or alkaline substances to generate glycols and amino alcohols. However, according to MD simulations conducted at 300 K, these acids readily dissociate from the resulting products. In the remaining eight systems, the most stable structural feature involves ion pairs formed by proton transfer reactions between acids and aldehyde compounds. These clusters exhibit remarkable thermodynamic stability. Furthermore, the acidity of the acid, the nature of nucleophilic agents, and the type of aldehyde all play significant roles in cluster stability and reactivity, and they have synergistic effects on the nucleation process. This study offers microscopic insights into the processes of new particle formation involving aldehydes, contributing to a deeper understanding of atmospheric chemistry at the molecular level. The acidity of the acid, the nature of nucleophilic agents, the type of aldehyde, proton transferall play significant roles in the nucleation process of aldehyde-sulfur-based particles.