<HashMap><database>biostudies-literature</database><scores/><additional><submitter>Trac HP</submitter><funding>Ministry of Science and Technology, Taiwan</funding><pagination>5548-5555</pagination><full_dataset_link>https://www.ebi.ac.uk/biostudies/studies/S-EPMC11264261</full_dataset_link><repository>biostudies-literature</repository><omics_type>Unknown</omics_type><volume>128(28)</volume><pubmed_abstract>Next to CH&lt;sub>4&lt;/sub>, CH&lt;sub>3&lt;/sub>OH is the most abundant C&lt;sub>1&lt;/sub> organics in the troposphere. The redox reaction of CH&lt;sub>3&lt;/sub>OH with N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub> had been shown experimentally to produce CH&lt;sub>3&lt;/sub>ONO, instead of CH&lt;sub>3&lt;/sub>ONO&lt;sub>2&lt;/sub>. The mechanism for the reaction remains unknown to date. We have investigated the reaction by ab initio MO calculations at the UCCSD(T)/6-311+G(3df,2p)//UB3LYP/6-311+G(3df,2p) level. The result indicates that the reaction takes place primarily by the isomerization of N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub> to ONONO&lt;sub>2&lt;/sub> through a very loose transition state within the N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>-CH&lt;sub>3&lt;/sub>OH collision complex with a 14.3 kcal/mol barrier, followed by the rapid attack of ONONO&lt;sub>2&lt;/sub> at CH&lt;sub>3&lt;/sub>OH producing CH&lt;sub>3&lt;/sub>ONO and HNO&lt;sub>3&lt;/sub>. The predicted mechanism for the redox reaction compares closely with the hydrolysis of N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>. The computed rate constant, &lt;i>k&lt;/i>&lt;sub>1&lt;/sub> = 1.43 × 10&lt;sup>-8&lt;/sup> T&lt;sup>1.96&lt;/sup> exp (-9092/T) (200-2000 K) cm&lt;sup>3&lt;/sup>molecule&lt;sup>-1&lt;/sup>s&lt;sup>-1&lt;/sup>, for the formation of CH&lt;sub>3&lt;/sub>ONO and HNO&lt;sub>3&lt;/sub> agrees reasonably with available low-temperature kinetic data and is found to be similar to that of the isoelectronic N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub> + CH&lt;sub>3&lt;/sub>NH&lt;sub>2&lt;/sub> reaction. We have also estimated the kinetics for the termolecular reaction, 2 NO&lt;sub>2&lt;/sub> + CH&lt;sub>3&lt;/sub>OH, and compared it with the direct bimolecular process; the latter was found to be 4.4 × 10&lt;sup>5&lt;/sup> times faster under the troposphere condition. On the basis of the known pollution levels of NO&lt;sub>2&lt;/sub>, N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>, and CH&lt;sub>3&lt;/sub>OH, both processes were estimated to be of negligible importance to tropospheric chemistry, however.</pubmed_abstract><journal>The journal of physical chemistry. A</journal><pubmed_title>Ab Initio Chemical Kinetics for Oxidation of CH&lt;sub>3&lt;/sub>OH by N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>: Elucidation of the Mechanism for Major Product Formation and Its Relevancy to Tropospheric Chemistry.</pubmed_title><pmcid>PMC11264261</pmcid><funding_grant_id>MOST 107-3017-F009-003</funding_grant_id><pubmed_authors>Trac HP</pubmed_authors><pubmed_authors>Lin MC</pubmed_authors></additional><is_claimable>false</is_claimable><name>Ab Initio Chemical Kinetics for Oxidation of CH&lt;sub>3&lt;/sub>OH by N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>: Elucidation of the Mechanism for Major Product Formation and Its Relevancy to Tropospheric Chemistry.</name><description>Next to CH&lt;sub>4&lt;/sub>, CH&lt;sub>3&lt;/sub>OH is the most abundant C&lt;sub>1&lt;/sub> organics in the troposphere. The redox reaction of CH&lt;sub>3&lt;/sub>OH with N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub> had been shown experimentally to produce CH&lt;sub>3&lt;/sub>ONO, instead of CH&lt;sub>3&lt;/sub>ONO&lt;sub>2&lt;/sub>. The mechanism for the reaction remains unknown to date. We have investigated the reaction by ab initio MO calculations at the UCCSD(T)/6-311+G(3df,2p)//UB3LYP/6-311+G(3df,2p) level. The result indicates that the reaction takes place primarily by the isomerization of N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub> to ONONO&lt;sub>2&lt;/sub> through a very loose transition state within the N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>-CH&lt;sub>3&lt;/sub>OH collision complex with a 14.3 kcal/mol barrier, followed by the rapid attack of ONONO&lt;sub>2&lt;/sub> at CH&lt;sub>3&lt;/sub>OH producing CH&lt;sub>3&lt;/sub>ONO and HNO&lt;sub>3&lt;/sub>. The predicted mechanism for the redox reaction compares closely with the hydrolysis of N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>. The computed rate constant, &lt;i>k&lt;/i>&lt;sub>1&lt;/sub> = 1.43 × 10&lt;sup>-8&lt;/sup> T&lt;sup>1.96&lt;/sup> exp (-9092/T) (200-2000 K) cm&lt;sup>3&lt;/sup>molecule&lt;sup>-1&lt;/sup>s&lt;sup>-1&lt;/sup>, for the formation of CH&lt;sub>3&lt;/sub>ONO and HNO&lt;sub>3&lt;/sub> agrees reasonably with available low-temperature kinetic data and is found to be similar to that of the isoelectronic N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub> + CH&lt;sub>3&lt;/sub>NH&lt;sub>2&lt;/sub> reaction. We have also estimated the kinetics for the termolecular reaction, 2 NO&lt;sub>2&lt;/sub> + CH&lt;sub>3&lt;/sub>OH, and compared it with the direct bimolecular process; the latter was found to be 4.4 × 10&lt;sup>5&lt;/sup> times faster under the troposphere condition. On the basis of the known pollution levels of NO&lt;sub>2&lt;/sub>, N&lt;sub>2&lt;/sub>O&lt;sub>4&lt;/sub>, and CH&lt;sub>3&lt;/sub>OH, both processes were estimated to be of negligible importance to tropospheric chemistry, however.</description><dates><release>2024-01-01T00:00:00Z</release><publication>2024 Jul</publication><modification>2025-05-18T13:26:24.043Z</modification><creation>2025-05-18T13:26:24.043Z</creation></dates><accession>S-EPMC11264261</accession><cross_references><pubmed>38973582</pubmed><doi>10.1021/acs.jpca.4c02433</doi></cross_references></HashMap>