Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature

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Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature. / Jenkin, Michael E.; Hayman, Garry D.; Wellington, Timothy J.; Hurley, Michael D.; Ball, James C.; Nielsen, Ole John; Ellermann, Thomas.

I: Journal of Physical Chemistry, Bind 97, Nr. 45, 01.12.1993, s. 11712-11723.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Jenkin, ME, Hayman, GD, Wellington, TJ, Hurley, MD, Ball, JC, Nielsen, OJ & Ellermann, T 1993, 'Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature', Journal of Physical Chemistry, bind 97, nr. 45, s. 11712-11723.

APA

Jenkin, M. E., Hayman, G. D., Wellington, T. J., Hurley, M. D., Ball, J. C., Nielsen, O. J., & Ellermann, T. (1993). Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature. Journal of Physical Chemistry, 97(45), 11712-11723.

Vancouver

Jenkin ME, Hayman GD, Wellington TJ, Hurley MD, Ball JC, Nielsen OJ o.a. Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature. Journal of Physical Chemistry. 1993 dec. 1;97(45):11712-11723.

Author

Jenkin, Michael E. ; Hayman, Garry D. ; Wellington, Timothy J. ; Hurley, Michael D. ; Ball, James C. ; Nielsen, Ole John ; Ellermann, Thomas. / Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature. I: Journal of Physical Chemistry. 1993 ; Bind 97, Nr. 45. s. 11712-11723.

Bibtex

@article{c03893002651480caf16792c4cede8d4,
title = "Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature",
abstract = "The UV absorption spectrum and kinetics of the self reaction of CH3OCH2O2 at 298 K have been studied using both the modulated photolysis of Cl2/CH3OCH3/O2/N2 mixtures and the pulse radiolysis of SF6/CH3OCH3/ O2 mixtures. The spectrum, characterized in the range 200-290 nm, is in good agreement with the single published determination.8 The observed second-order removal kinetics of CH3OCH2O2, k5obs, were found to be sensitive to both the variation of total pressure (17-760 Torr) and the composition of the reaction mixtures: 2CH3OCH2O2 → 2CH3OCH2O + O2 (5a); → CH3OCHO + CH3OCH2OH + O2 (5b). The kinetic studies and a detailed product investigation using long path length FTIR spectroscopy (T = 295 K; Cl2/CH3OCH3/ O2/N2 system) provide evidence to support a mechanism involving the rapid thermal decomposition of CH3-OCH2O by H atom ejection occurring in competition with the reaction with O2: CH3OCH2O (+M) → CH3OCHO + H (+M) (6); CH3OCH2O + O2 → CH3OCHO + HO2 (4). The complications in the measured values of k5obs in the present studies, and those reported previously, 8 are believed to occur as a direct result of formation of H atoms from reaction 6. Accordingly, a pressure-independent value of k5 = (2.1 ± 0.3) × 10-12 cm3 molecule-1 s-1 is derived for the elementary rate coefficient at 298 K, with identical values of the branching ratio α = k5a/k5 = 0.7 ± 0.1 determined independently from the FTIR product studies and the modulated photolysis experiments. As part of this work, the rate coefficient for the reaction of Cl atoms with CH3OCH2Cl was found to be (2.9 ± 0.2) × 10-11 cm3 molecule-1 s-1.",
author = "Jenkin, {Michael E.} and Hayman, {Garry D.} and Wellington, {Timothy J.} and Hurley, {Michael D.} and Ball, {James C.} and Nielsen, {Ole John} and Thomas Ellermann",
year = "1993",
month = dec,
day = "1",
language = "English",
volume = "97",
pages = "11712--11723",
journal = "Journal of Physical Chemistry",
issn = "0022-3654",
publisher = "American Chemical Society",
number = "45",

}

RIS

TY - JOUR

T1 - Kinetic and mechanistic study of the self reaction of CH3OCH2O2 radicals at room temperature

AU - Jenkin, Michael E.

AU - Hayman, Garry D.

AU - Wellington, Timothy J.

AU - Hurley, Michael D.

AU - Ball, James C.

AU - Nielsen, Ole John

AU - Ellermann, Thomas

PY - 1993/12/1

Y1 - 1993/12/1

N2 - The UV absorption spectrum and kinetics of the self reaction of CH3OCH2O2 at 298 K have been studied using both the modulated photolysis of Cl2/CH3OCH3/O2/N2 mixtures and the pulse radiolysis of SF6/CH3OCH3/ O2 mixtures. The spectrum, characterized in the range 200-290 nm, is in good agreement with the single published determination.8 The observed second-order removal kinetics of CH3OCH2O2, k5obs, were found to be sensitive to both the variation of total pressure (17-760 Torr) and the composition of the reaction mixtures: 2CH3OCH2O2 → 2CH3OCH2O + O2 (5a); → CH3OCHO + CH3OCH2OH + O2 (5b). The kinetic studies and a detailed product investigation using long path length FTIR spectroscopy (T = 295 K; Cl2/CH3OCH3/ O2/N2 system) provide evidence to support a mechanism involving the rapid thermal decomposition of CH3-OCH2O by H atom ejection occurring in competition with the reaction with O2: CH3OCH2O (+M) → CH3OCHO + H (+M) (6); CH3OCH2O + O2 → CH3OCHO + HO2 (4). The complications in the measured values of k5obs in the present studies, and those reported previously, 8 are believed to occur as a direct result of formation of H atoms from reaction 6. Accordingly, a pressure-independent value of k5 = (2.1 ± 0.3) × 10-12 cm3 molecule-1 s-1 is derived for the elementary rate coefficient at 298 K, with identical values of the branching ratio α = k5a/k5 = 0.7 ± 0.1 determined independently from the FTIR product studies and the modulated photolysis experiments. As part of this work, the rate coefficient for the reaction of Cl atoms with CH3OCH2Cl was found to be (2.9 ± 0.2) × 10-11 cm3 molecule-1 s-1.

AB - The UV absorption spectrum and kinetics of the self reaction of CH3OCH2O2 at 298 K have been studied using both the modulated photolysis of Cl2/CH3OCH3/O2/N2 mixtures and the pulse radiolysis of SF6/CH3OCH3/ O2 mixtures. The spectrum, characterized in the range 200-290 nm, is in good agreement with the single published determination.8 The observed second-order removal kinetics of CH3OCH2O2, k5obs, were found to be sensitive to both the variation of total pressure (17-760 Torr) and the composition of the reaction mixtures: 2CH3OCH2O2 → 2CH3OCH2O + O2 (5a); → CH3OCHO + CH3OCH2OH + O2 (5b). The kinetic studies and a detailed product investigation using long path length FTIR spectroscopy (T = 295 K; Cl2/CH3OCH3/ O2/N2 system) provide evidence to support a mechanism involving the rapid thermal decomposition of CH3-OCH2O by H atom ejection occurring in competition with the reaction with O2: CH3OCH2O (+M) → CH3OCHO + H (+M) (6); CH3OCH2O + O2 → CH3OCHO + HO2 (4). The complications in the measured values of k5obs in the present studies, and those reported previously, 8 are believed to occur as a direct result of formation of H atoms from reaction 6. Accordingly, a pressure-independent value of k5 = (2.1 ± 0.3) × 10-12 cm3 molecule-1 s-1 is derived for the elementary rate coefficient at 298 K, with identical values of the branching ratio α = k5a/k5 = 0.7 ± 0.1 determined independently from the FTIR product studies and the modulated photolysis experiments. As part of this work, the rate coefficient for the reaction of Cl atoms with CH3OCH2Cl was found to be (2.9 ± 0.2) × 10-11 cm3 molecule-1 s-1.

UR - http://www.scopus.com/inward/record.url?scp=33751386750&partnerID=8YFLogxK

M3 - Journal article

AN - SCOPUS:33751386750

VL - 97

SP - 11712

EP - 11723

JO - Journal of Physical Chemistry

JF - Journal of Physical Chemistry

SN - 0022-3654

IS - 45

ER -

ID: 228195053