Infrared-driven unimolecular reaction of CH3CHOO Criegee intermediates to OH radical products

Fang Liu; Joseph M. Beames; Andrew S. Petit; Anne B. McCoy; Marsha I. Lester

doi:10.1126/science.1257158

Infrared-driven unimolecular reaction of CH3CHOO Criegee intermediates to OH radical products

Fang Liu
, Joseph M. Beames
, Andrew S. Petit
, Anne B. McCoy
, Marsha I. Lester^*

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

Ozonolysis of alkenes, an important nonphotolytic source of hydroxyl (OH) radicals in the troposphere, proceeds through energized Criegee intermediates that undergo unimolecular decay to produce OH radicals. Here, we used infrared (IR) activation of cold CH₃CHOO Criegee intermediates to drive hydrogen transfer from the methyl group to the terminal oxygen, followed by dissociation to OH radicals. State-selective excitation of CH₃CHOO in the CH stretch overtone region combined with sensitive OH detection revealed the IR spectrum of CH₃CHOO, effective barrier height for the critical hydrogen transfer step, and rapid decay dynamics to OH products. Complementary theory provides insights on the IR overtone spectrum, as well as vibrational excitations, structural changes, and energy required to move from the minimum-energy configuration of CH3CHOO to the transition state for the hydrogen transfer reaction.

Original language	English
Pages (from-to)	1596-1598
Number of pages	3
Journal	Science
Volume	345
Issue number	6204
DOIs	https://doi.org/10.1126/science.1257158
Publication status	Published - 26 Sept 2014

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title = "Infrared-driven unimolecular reaction of CH3CHOO Criegee intermediates to OH radical products",

abstract = "Ozonolysis of alkenes, an important nonphotolytic source of hydroxyl (OH) radicals in the troposphere, proceeds through energized Criegee intermediates that undergo unimolecular decay to produce OH radicals. Here, we used infrared (IR) activation of cold CH3CHOO Criegee intermediates to drive hydrogen transfer from the methyl group to the terminal oxygen, followed by dissociation to OH radicals. State-selective excitation of CH3CHOO in the CH stretch overtone region combined with sensitive OH detection revealed the IR spectrum of CH3CHOO, effective barrier height for the critical hydrogen transfer step, and rapid decay dynamics to OH products. Complementary theory provides insights on the IR overtone spectrum, as well as vibrational excitations, structural changes, and energy required to move from the minimum-energy configuration of CH3CHOO to the transition state for the hydrogen transfer reaction.",

author = "Fang Liu and Beames, \{Joseph M.\} and Petit, \{Andrew S.\} and McCoy, \{Anne B.\} and Lester, \{Marsha I.\}",

year = "2014",

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doi = "10.1126/science.1257158",

language = "English",

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TY - JOUR

T1 - Infrared-driven unimolecular reaction of CH3CHOO Criegee intermediates to OH radical products

AU - Liu, Fang

AU - Beames, Joseph M.

AU - Petit, Andrew S.

AU - McCoy, Anne B.

AU - Lester, Marsha I.

PY - 2014/9/26

Y1 - 2014/9/26

N2 - Ozonolysis of alkenes, an important nonphotolytic source of hydroxyl (OH) radicals in the troposphere, proceeds through energized Criegee intermediates that undergo unimolecular decay to produce OH radicals. Here, we used infrared (IR) activation of cold CH3CHOO Criegee intermediates to drive hydrogen transfer from the methyl group to the terminal oxygen, followed by dissociation to OH radicals. State-selective excitation of CH3CHOO in the CH stretch overtone region combined with sensitive OH detection revealed the IR spectrum of CH3CHOO, effective barrier height for the critical hydrogen transfer step, and rapid decay dynamics to OH products. Complementary theory provides insights on the IR overtone spectrum, as well as vibrational excitations, structural changes, and energy required to move from the minimum-energy configuration of CH3CHOO to the transition state for the hydrogen transfer reaction.

AB - Ozonolysis of alkenes, an important nonphotolytic source of hydroxyl (OH) radicals in the troposphere, proceeds through energized Criegee intermediates that undergo unimolecular decay to produce OH radicals. Here, we used infrared (IR) activation of cold CH3CHOO Criegee intermediates to drive hydrogen transfer from the methyl group to the terminal oxygen, followed by dissociation to OH radicals. State-selective excitation of CH3CHOO in the CH stretch overtone region combined with sensitive OH detection revealed the IR spectrum of CH3CHOO, effective barrier height for the critical hydrogen transfer step, and rapid decay dynamics to OH products. Complementary theory provides insights on the IR overtone spectrum, as well as vibrational excitations, structural changes, and energy required to move from the minimum-energy configuration of CH3CHOO to the transition state for the hydrogen transfer reaction.

UR - https://www.scopus.com/pages/publications/84907447142

U2 - 10.1126/science.1257158

DO - 10.1126/science.1257158

M3 - Article

AN - SCOPUS:84907447142

SN - 0036-8075

VL - 345

SP - 1596

EP - 1598

JO - Science

JF - Science

IS - 6204

ER -

Infrared-driven unimolecular reaction of CH3CHOO Criegee intermediates to OH radical products

Abstract

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