Reaction of Criegee Intermediates with SO₂─A Possible Route for Sulfurous Acid Formation in the Atmosphere

Abstract: The reaction of a Criegee intermediate (CI) with SO 2 is of significant interest due to its negative impact on the environment and ecosystem. In the present work, the formation of H 2 SO 3 through the reaction of the CIs CH 2 OO, syn-CH 3 CHOO, and (CH 3 ) 2 COO with SO 2 is studied by using high-level electronic structure calculations. The reaction of CIs with SO 2 is a stepwise process; in the first step an O atom from a CI is transferred to the S atom of SO 2 , which results in the formation of SO 3 through… Show more

“…However, the possible impacts of pressure were not fully discussed, and the reaction of anti -CH 3 CHOO + SO 2 was not considered. The calculations predicted a positive temperature dependence for reactions of CH 2 OO, syn -CH 3 CHOO, and (CH 3 ) 2 COO with SO 2 , despite the reactions being barrierless, and this is in contrast to the experimental results for syn -CH 3 CHOO + SO 2 obtained in this work, our previous experiments for CH 2 OO + SO 2 , and experimental results for (CH 3 ) 2 COO + SO 2 (see the Supporting Information for further details). Where potential impacts of pressure have been considered in detail in theoretical studies of SCI + SO 2 reactions, there is an agreement with the lack of observed pressure dependence in the kinetics for CH 2 OO + SO 2 under atmospheric conditions, ,,, but there are differences in the predicted pressure dependence of the reaction between (CH 3 ) 2 COO and SO 2 . , Vereecken et al suggested that >80% of the SOZ formed by (CH 3 ) 2 COO + SO 2 undergoes prompt decomposition to acetone (CH 3 C­(O)­CH 3 ) and SO 3 at 298 K and a pressure of 4 Torr, while >97% of the SOZ collisionally stabilizes at 298 K and 760 Torr, with the difference compared to CH 2 OO + SO 2 attributed to the greater number of degrees of freedom in the SOZ formed via (CH 3 ) 2 COO + SO 2 , which would also be relevant to the comparison between the SOZ formed via CH 2 OO + SO 2 and those from reactions of CH 3 CHOO conformers with SO 2 .…”

“…The reaction between syn -CH 3 CHOO and SO 2 has been investigated using theoretical approaches, which indicate a barrierless reaction with a 98% yield of acetaldehyde (CH 3 CHO) + SO 3 at 298 K and 200 Torr of He and a rate coefficient for CH 3 CHO + SO 3 production of 4.49 × 10 –11 cm 3 s –1 at 298 K . However, the possible impacts of pressure were not fully discussed, and the reaction of anti -CH 3 CHOO + SO 2 was not considered.…”

“…The reaction between syn -CH 3 CHOO and SO 2 has been investigated using theoretical approaches, which indicate a barrierless reaction with a 98% yield of acetaldehyde (CH 3 CHO) + SO 3 at 298 K and 200 Torr of He and a rate coefficient for CH 3 CHO + SO 3 production of 4.49 × 10 –11 cm 3 s –1 at 298 K. 13 However, the possible impacts of pressure were not fully discussed, and the reaction of anti -CH 3 CHOO + SO 2 was not considered. The calculations 13 predicted a positive temperature dependence for reactions of CH 2 OO, syn -CH 3 CHOO, and (CH 3 ) 2 COO with SO 2 , despite the reactions being barrierless, and this is in contrast to the experimental results for syn -CH 3 CHOO + SO 2 obtained in this work, our previous experiments for CH 2 OO + SO 2 , 6 and experimental results for (CH 3 ) 2 COO + SO 2 40 (see the Supporting Information for further details). Where potential impacts of pressure have been considered in detail in theoretical studies of SCI + SO 2 reactions, there is an agreement with the lack of observed pressure dependence in the kinetics for CH 2 OO + SO 2 under atmospheric conditions, 3 , 4 , 11 , 12 but there are differences in the predicted pressure dependence of the reaction between (CH 3 ) 2 COO and SO 2 .…”

“…For the reaction of the simplest SCI, CH 2 OO, with SO 2 , there is now general consensus regarding the kinetics at room temperature, with a current IUPAC recommendation of (3.7 –0.40 +0.45 ) × 10 –11 cm 3 s –1 at 298 K . The kinetics of CH 2 OO + SO 2 have been demonstrated to be independent of pressure under typical atmospheric conditions, , with a negative temperature dependence and reaction products dominated by formaldehyde (HCHO) , and sulfur trioxide (SO 3 ). , Theory indicates that the reaction of an SCI with SO 2 proceeds via the barrierless formation of a cyclic secondary ozonide (SOZ), followed by collisional stabilization of the SOZ or further rearrangement via one or more submerged barriers to form products including SO 3 . − In the case of CH 2 OO + SO 2 , there is negligible stabilization of the SOZ under atmospheric conditions, , and contributions from two stereochemical pathways lead to the production of HCHO + SO 3 via submerged barriers . For reactions of other SCIs with SO 2 , there is greater potential for stabilization of the SOZ, leading to the potential for pressure-dependent kinetics and product yields …”

Kinetics of the Gas-Phase Reactions of syn- and anti-CH₃CHOO Criegee Intermediate Conformers with SO₂ as a Function of Temperature and Pressure

“…However, the possible impacts of pressure were not fully discussed, and the reaction of anti -CH 3 CHOO + SO 2 was not considered. The calculations predicted a positive temperature dependence for reactions of CH 2 OO, syn -CH 3 CHOO, and (CH 3 ) 2 COO with SO 2 , despite the reactions being barrierless, and this is in contrast to the experimental results for syn -CH 3 CHOO + SO 2 obtained in this work, our previous experiments for CH 2 OO + SO 2 , and experimental results for (CH 3 ) 2 COO + SO 2 (see the Supporting Information for further details). Where potential impacts of pressure have been considered in detail in theoretical studies of SCI + SO 2 reactions, there is an agreement with the lack of observed pressure dependence in the kinetics for CH 2 OO + SO 2 under atmospheric conditions, ,,, but there are differences in the predicted pressure dependence of the reaction between (CH 3 ) 2 COO and SO 2 . , Vereecken et al suggested that >80% of the SOZ formed by (CH 3 ) 2 COO + SO 2 undergoes prompt decomposition to acetone (CH 3 C­(O)­CH 3 ) and SO 3 at 298 K and a pressure of 4 Torr, while >97% of the SOZ collisionally stabilizes at 298 K and 760 Torr, with the difference compared to CH 2 OO + SO 2 attributed to the greater number of degrees of freedom in the SOZ formed via (CH 3 ) 2 COO + SO 2 , which would also be relevant to the comparison between the SOZ formed via CH 2 OO + SO 2 and those from reactions of CH 3 CHOO conformers with SO 2 .…”

“…The reaction between syn -CH 3 CHOO and SO 2 has been investigated using theoretical approaches, which indicate a barrierless reaction with a 98% yield of acetaldehyde (CH 3 CHO) + SO 3 at 298 K and 200 Torr of He and a rate coefficient for CH 3 CHO + SO 3 production of 4.49 × 10 –11 cm 3 s –1 at 298 K . However, the possible impacts of pressure were not fully discussed, and the reaction of anti -CH 3 CHOO + SO 2 was not considered.…”

“…The reaction between syn -CH 3 CHOO and SO 2 has been investigated using theoretical approaches, which indicate a barrierless reaction with a 98% yield of acetaldehyde (CH 3 CHO) + SO 3 at 298 K and 200 Torr of He and a rate coefficient for CH 3 CHO + SO 3 production of 4.49 × 10 –11 cm 3 s –1 at 298 K. 13 However, the possible impacts of pressure were not fully discussed, and the reaction of anti -CH 3 CHOO + SO 2 was not considered. The calculations 13 predicted a positive temperature dependence for reactions of CH 2 OO, syn -CH 3 CHOO, and (CH 3 ) 2 COO with SO 2 , despite the reactions being barrierless, and this is in contrast to the experimental results for syn -CH 3 CHOO + SO 2 obtained in this work, our previous experiments for CH 2 OO + SO 2 , 6 and experimental results for (CH 3 ) 2 COO + SO 2 40 (see the Supporting Information for further details). Where potential impacts of pressure have been considered in detail in theoretical studies of SCI + SO 2 reactions, there is an agreement with the lack of observed pressure dependence in the kinetics for CH 2 OO + SO 2 under atmospheric conditions, 3 , 4 , 11 , 12 but there are differences in the predicted pressure dependence of the reaction between (CH 3 ) 2 COO and SO 2 .…”

“…For the reaction of the simplest SCI, CH 2 OO, with SO 2 , there is now general consensus regarding the kinetics at room temperature, with a current IUPAC recommendation of (3.7 –0.40 +0.45 ) × 10 –11 cm 3 s –1 at 298 K . The kinetics of CH 2 OO + SO 2 have been demonstrated to be independent of pressure under typical atmospheric conditions, , with a negative temperature dependence and reaction products dominated by formaldehyde (HCHO) , and sulfur trioxide (SO 3 ). , Theory indicates that the reaction of an SCI with SO 2 proceeds via the barrierless formation of a cyclic secondary ozonide (SOZ), followed by collisional stabilization of the SOZ or further rearrangement via one or more submerged barriers to form products including SO 3 . − In the case of CH 2 OO + SO 2 , there is negligible stabilization of the SOZ under atmospheric conditions, , and contributions from two stereochemical pathways lead to the production of HCHO + SO 3 via submerged barriers . For reactions of other SCIs with SO 2 , there is greater potential for stabilization of the SOZ, leading to the potential for pressure-dependent kinetics and product yields …”

Kinetics of the Gas-Phase Reactions of syn- and anti-CH₃CHOO Criegee Intermediate Conformers with SO₂ as a Function of Temperature and Pressure

“…However, their reaction with TFA is as high as that of CH 2 O + O − with SO 2 , HCl, and (CF 3 ) 2 CO, as well as the self-reaction, which is about 1 × 10 −11 cm 3 s −1 . 68–71 This interesting finding suggests that the 1,4-CC addition reaction of C3–C4 unsaturated SC -CH 2 R z CR y CO + O − + TFA will be a significant loss for larger unsaturated CIs with acids.…”

New insights into the mechanism and kinetics of the addition reaction of unsaturated Criegee intermediates to CF₃COOH and tropospheric implications

Revealing new pathways for the reaction of Criegee intermediate CH2OO with SO2