Vibrational state specificity and selectivity in the reactions N+OH→NO(v)+H and N+NO(v)→N2+O

Ian Smith; Richard P. Tuckett; Christopher J. Whitham

doi:10.1063/1.464821

Vibrational state specificity and selectivity in the reactions N+OH→NO(v)+H and N+NO(v)→N2+O

Ian Smith, Richard P. Tuckett, Christopher J. Whitham

Chemistry

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Abstract

The vibrational state distribution of NO formed in the radical–radical reaction N+OH→NO(v’≤9)+H; ΔH00=−204.0 kJ mol−1 has been determined using a pulse‐and‐probe technique. OH radicals were generated by pulsed laser photolysis of H2O2 at 266 nm in a flow of N2 which had been passed through a microwave discharge to produce N atoms. The vibrational distribution of NO, measured by laser‐induced fluorescence (LIF) spectroscopy, is similar to that predicted by phase‐space theory and corresponds to an average yield of ca. 31% of the energy available to the reaction products. Experiments in which LIF signals were observed as the pulse–probe time delay was varied showed that populations within different vibrational levels (v=0–8) displayed similar kinetics, consistent with rapid removal of NO(v) by reaction with N atoms, N+NO(v)→N2+O, at rates which exhibit a mild dependence on v.

Original language	English
Pages (from-to)	6267-6275
Journal	Journal of Chemical Physics
Volume	98
Issue number	8
DOIs	https://doi.org/10.1063/1.464821
Publication status	Published - 15 Apr 1993

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Smith_et_al_Vibrational_state_specificity_Journal_of_Chemical_Physics_1993
Vibrational state specificity and selectivity in the reactions N+OH→NO(v)+H and N+NO(v)→N2+O. Ian W. M. Smith, Richard P. Tuckett, and Christopher J. Whitham. The Journal of Chemical Physics 1993 98:8, 6267-6275
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http://aip.scitation.org/doi/10.1063/1.464821Licence: None: All rights reserved

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title = "Vibrational state specificity and selectivity in the reactions N+OH→NO(v)+H and N+NO(v)→N2+O",

abstract = "The vibrational state distribution of NO formed in the radical–radical reaction N+OH→NO(v{\textquoteright}≤9)+H; ΔH00=−204.0 kJ mol−1 has been determined using a pulse‐and‐probe technique. OH radicals were generated by pulsed laser photolysis of H2O2 at 266 nm in a flow of N2 which had been passed through a microwave discharge to produce N atoms. The vibrational distribution of NO, measured by laser‐induced fluorescence (LIF) spectroscopy, is similar to that predicted by phase‐space theory and corresponds to an average yield of ca. 31% of the energy available to the reaction products. Experiments in which LIF signals were observed as the pulse–probe time delay was varied showed that populations within different vibrational levels (v=0–8) displayed similar kinetics, consistent with rapid removal of NO(v) by reaction with N atoms, N+NO(v)→N2+O, at rates which exhibit a mild dependence on v.",

author = "Ian Smith and Tuckett, {Richard P.} and Whitham, {Christopher J.}",

year = "1993",

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T1 - Vibrational state specificity and selectivity in the reactions N+OH→NO(v)+H and N+NO(v)→N2+O

AU - Smith, Ian

AU - Tuckett, Richard P.

AU - Whitham, Christopher J.

PY - 1993/4/15

Y1 - 1993/4/15

N2 - The vibrational state distribution of NO formed in the radical–radical reaction N+OH→NO(v’≤9)+H; ΔH00=−204.0 kJ mol−1 has been determined using a pulse‐and‐probe technique. OH radicals were generated by pulsed laser photolysis of H2O2 at 266 nm in a flow of N2 which had been passed through a microwave discharge to produce N atoms. The vibrational distribution of NO, measured by laser‐induced fluorescence (LIF) spectroscopy, is similar to that predicted by phase‐space theory and corresponds to an average yield of ca. 31% of the energy available to the reaction products. Experiments in which LIF signals were observed as the pulse–probe time delay was varied showed that populations within different vibrational levels (v=0–8) displayed similar kinetics, consistent with rapid removal of NO(v) by reaction with N atoms, N+NO(v)→N2+O, at rates which exhibit a mild dependence on v.

AB - The vibrational state distribution of NO formed in the radical–radical reaction N+OH→NO(v’≤9)+H; ΔH00=−204.0 kJ mol−1 has been determined using a pulse‐and‐probe technique. OH radicals were generated by pulsed laser photolysis of H2O2 at 266 nm in a flow of N2 which had been passed through a microwave discharge to produce N atoms. The vibrational distribution of NO, measured by laser‐induced fluorescence (LIF) spectroscopy, is similar to that predicted by phase‐space theory and corresponds to an average yield of ca. 31% of the energy available to the reaction products. Experiments in which LIF signals were observed as the pulse–probe time delay was varied showed that populations within different vibrational levels (v=0–8) displayed similar kinetics, consistent with rapid removal of NO(v) by reaction with N atoms, N+NO(v)→N2+O, at rates which exhibit a mild dependence on v.

U2 - 10.1063/1.464821

DO - 10.1063/1.464821

M3 - Article

SN - 0021-9606

VL - 98

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EP - 6275

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

IS - 8

ER -

Vibrational state specificity and selectivity in the reactions N+OH→NO(v)+H and N+NO(v)→N2+O

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