Formation and Oxidation of Imidazole in Tropospheric Aqueous-Phase Chemistry: A Computational Study

Wei, Bo; Zhang, Ruifeng; Sit, Patrick H.-L.; He, Maoxia; Chan, Chak K.

doi:10.1021/acsestair.3c00097

ACS EST Air

2024

DOI: 10.1021/acsestair.3c00097

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Formation and Oxidation of Imidazole in Tropospheric Aqueous-Phase Chemistry: A Computational Study

Bo Wei,

Ruifeng Zhang,

Patrick H.-L. Sit

et al.

Abstract: Imidazole produced by the interaction of glyoxal with nitrogen-containing chemicals in atmospheric particles can yield secondary organic aerosol (SOA) due to atmospheric oxidation. However, knowledge about the aqueous phase reaction mechanism of imidazole formation and its oxidation is still very limited. This work investigated the formation mechanism and aqueous-phase oxidative degradation reactions of imidazole with the hydroxyl radical (•OH), nitrate radical (NO3 •), and ozone (O3). Results showed that the … Show more

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Cited by 2 publications

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Theoretical Study on the Synthesis Efficiency and Yield of Imidazole Derivatives Based on the Glyoxal and Diamine

Liu,

Chen,

et al. 2024

Int J of Quantum Chemistry

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Imidazole structures are significant molecular frameworks in pharmaceutical and energetic material research. The synthesis efficiency and yield of their derivatives often vary greatly, making it challenging to establish reaction regularity. In this study, we investigated two types of imidazole derivatives with notably different synthesis efficiencies and yields. Our findings reveal that the catalysis of H2O molecules is crucial for ensuring synthesis efficiency, while side reactions are influenced by the acidity of the solution during the process, thereby affecting the synthesis yield. We observed that the energy barrier for the H2O‐catalyzed ipsilateral H transfer process was reduced to 12.0 from 40.1 kcal/mol, significantly enhancing the reaction efficiency. The synthesis of 34‐dihydroxyimidazolidine‐2‐ketone was found to have a low yield of 19.2% due to competitive side reactions in the reaction system, which have higher energy barriers compared to the desired synthesis pathway. These findings provide a theoretical foundation for future research to optimize the synthesis of imidazole derivatives. Enhancing synthesis conditions could significantly benefit pharmaceutical applications and the development of advanced energetic materials.

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Theoretical Study on the Synthesis Efficiency and Yield of Imidazole Derivatives Based on the Glyoxal and Diamine

Liu,

Chen,

et al. 2024

Int J of Quantum Chemistry

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Theoretical investigation on the oxidation mechanism of methylglyoxal in the aqueous phase

Zhang,

Chan

et al. 2024

Chemosphere

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Formation and Oxidation of Imidazole in Tropospheric Aqueous-Phase Chemistry: A Computational Study

Cited by 2 publications

References 57 publications

Theoretical Study on the Synthesis Efficiency and Yield of Imidazole Derivatives Based on the Glyoxal and Diamine

Theoretical Study on the Synthesis Efficiency and Yield of Imidazole Derivatives Based on the Glyoxal and Diamine

Theoretical investigation on the oxidation mechanism of methylglyoxal in the aqueous phase

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