Shiqi Wei, Qiongqiong Wan, Shibo Zhou, Wenjing Nie, Suming Chen
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引用次数: 0
Abstract
Acetonitrile (CH3CN) is considered a very stable molecule in aqueous solutions, and its deprotonation to produce strongly basic -CH2CN requires harsh conditions. CH3CN is also present in the atmosphere, but its chemical transformation pathway at the air-water interface is unknown. In this study, we discovered and verified the unprecedented spontaneous generation of -CH2CN from the CH3CN-H2O solution at the air-water interface of microdroplets, and revealed the indirect deprotonation mechanism of CH3CN by synergistic redox of •OH and electrons in the microdroplets through the capture of key intermediates and computational chemistry. In addition, the dynamic process of indirect deprotonation-protonation was also observed. The high reactivity of -CH2CN in the droplets was revealed via nucleophilic addition to acetone, benzaldehyde, and the parent CH3CN molecule. Furthermore, the -CH2CN generated in the microdroplets underwent a barrier-free nucleophilic addition reaction with CO2 to produce 2-cyanoacetic acid for CO2 fixation. The synergistic redox reaction process revealed in this study provides new insights into microdroplet chemistry, and the distinctive CH3CN reactions identified may provide new clues to unravel the mystery of the CH3CN transformation in the atmospheric environment.
期刊介绍:
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