Rapid Atmospheric Reactions between Criegee Intermediates and Hypochlorous Acid

Zhang, Yu-Qiong; Francisco, Joseph S.; Long, Bo

doi:10.1021/acs.jpca.3c06144

J. Phys. Chem. A

2024

DOI: 10.1021/acs.jpca.3c06144

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Rapid Atmospheric Reactions between Criegee Intermediates and Hypochlorous Acid

Yu-Qiong Zhang,

Joseph S. Francisco,

Bo Long

Abstract: Hypochlorous acid (HOCl) is a paramount compound in the atmosphere due to its significant contribution to both tropospheric oxidation capacity and ozone depletion. The main removal routes for HOCl are photolysis and the reaction with OH during the daytime, while these processes are unimportant during the nighttime. Here, we report the rapid reactions of Criegee intermediates (CH 2 OO and anti/syn-CH 3 CHOO) with HOCl by using high-level quantum chemical methods as the benchmark; their accuracy is close to coup… Show more

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Cited by 3 publications

References 77 publications

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Reactions of sulfur trioxide with hypochlorous acid catalyzed by water in gas phase and at the air-water nanodroplet interface in the atmosphere: An important sink for hypochlorous acid

Gao,

Dong,

Long

2024

Atmospheric Environment

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Reactions of sulfur trioxide with hypochlorous acid catalyzed by water in gas phase and at the air-water nanodroplet interface in the atmosphere: An important sink for hypochlorous acid

Gao,

Dong,

Long

2024

Atmospheric Environment

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Promoting Cl₂O Generation from the HOCl + HOCl Reaction on Aqueous/Frozen Air–Water Interfaces

Zhang,

Zheng,

Han

et al. 2024

J. Am. Chem. Soc.

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Hypochlorous acid (HOCl) is considered a temporary reservoir of dichlorine monoxide (Cl 2 O). Previous studies have suggested that Cl 2 O is difficult to generate from the reaction of HOCl + HOCl in the gas phase. Here, we demonstrate that Cl 2 O can be generated from the HOCl + HOCl reaction at aqueous/frozen air−water interfaces, which is confirmed by ab initio molecular dynamic calculations. Distinct from the one-step reaction in the gas phase, our results show that Cl 2 O generation from HOCl + HOCl on aqueous/frozen interfaces involves two elementary steps, namely, one HOCl deprotonation and one Cl-abstraction from the other HOCl. Specifically, the mechanisms of neutral/acidic catalysis from interfacial water/nitric acid and base catalysis from ammonia, methylamine and dimethylamine have been examined. For the former, HOCl deprotonation is the rate-limiting step, and the total k of Cl 2 O generation increases to 9.23 × 10 −9 −9.10 × 10 −1 M −1 s −1 at the aqueous interface and 3.20 × 10 −7 −4.10 × 10 −3 M −1 s −1 at the frozen interface, which is at least 23 and 25 orders of magnitude greater than that of gaseous k (3.31 × 10 −32 M −1 s −1 ). For the latter, the rate-limiting step is changed to Cl-abstraction, whose total k dramatically increases to 1.40−8.97 × 10 7 M −1 s −1 at the aqueous interface and 7.12−9.99 × 10 6 M −1 s −1 at the frozen interface. Interestingly, the Cl 2 O production rates ranked in the order of dimethylamine < methylamine < ammonia and decreased with increasing catalytic alkalinity. These findings provide new insights for understanding other Cl 2 O sources beyond the ClONO 2 + HOCl reaction.

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Dual-level strategy for quantitative kinetics for the reaction between ethylene and hydroxyl radical

Li,

Long

2024

The Journal of Chemical Physics

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The atmospheric reactions are mainly initiated by hydroxyl radical (OH). Here, we choose the C2H4 + OH reaction as a model reaction for other reactions of OH with alkenes. We use the GMM(P).L//CCSD(T)-F12a/cc-pVTZ-F12 theoretical method as the benchmark results close to the approximation of CCSDTQ(P)/CBS accuracy to investigate the C2H4 + OH reaction. The rate constants for the C2H4 + OH reaction at high-pressure limit were calculated by using the dual-level strategy. It integrates the transition state theory rate constant calculated by GMM(P).L//CCSD(T)-F12a/cc-pVTZ-F12 with the canonical variational transition state theory containing small-curvature tunneling (CVT/SCT) calculated by using the M11-L functional method with the MG3S basis set. The rate constants of C2H4 + OH at different pressures were obtained by using both the system-specific quantum Rice–Ramsperger–Kassel (SS-QRRK) theory and master equation method. The calculated results uncover that both the calculated rate constants at different pressures and temperatures are quantitatively consistent with the values obtained by the experimental measurements in the C2H4 + OH reaction. We find that the post-CCSD(T) contributions to the barrier height for the C2H4 + OH reaction are significant with the calculated value of −0.38 kcal/mol. We also find that the rate determining step is only dominated by the tight transition state under atmospheric conditions, whereas previous investigations indicated that the rate constants were controlled by both the loose and tight transition states in the C2H4 + OH reaction. The present findings unravel that it is an important factor for the effect of torsional anharmonicity on quantitative kinetics.

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Rapid Atmospheric Reactions between Criegee Intermediates and Hypochlorous Acid

Cited by 3 publications

References 77 publications

Reactions of sulfur trioxide with hypochlorous acid catalyzed by water in gas phase and at the air-water nanodroplet interface in the atmosphere: An important sink for hypochlorous acid

Reactions of sulfur trioxide with hypochlorous acid catalyzed by water in gas phase and at the air-water nanodroplet interface in the atmosphere: An important sink for hypochlorous acid

Promoting Cl₂O Generation from the HOCl + HOCl Reaction on Aqueous/Frozen Air–Water Interfaces

Dual-level strategy for quantitative kinetics for the reaction between ethylene and hydroxyl radical

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Rapid Atmospheric Reactions between Criegee Intermediates and Hypochlorous Acid

Cited by 3 publications

References 77 publications

Reactions of sulfur trioxide with hypochlorous acid catalyzed by water in gas phase and at the air-water nanodroplet interface in the atmosphere: An important sink for hypochlorous acid

Reactions of sulfur trioxide with hypochlorous acid catalyzed by water in gas phase and at the air-water nanodroplet interface in the atmosphere: An important sink for hypochlorous acid

Promoting Cl2O Generation from the HOCl + HOCl Reaction on Aqueous/Frozen Air–Water Interfaces

Dual-level strategy for quantitative kinetics for the reaction between ethylene and hydroxyl radical

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Product

Resources

About

Promoting Cl₂O Generation from the HOCl + HOCl Reaction on Aqueous/Frozen Air–Water Interfaces