Photochemical modeling of hydroxyl and its relationship to other species during the Tropospheric OH Photochemistry Experiment

McKeen, S. A.; Mount, G. H.; Eisele, F. L.; Williams, E. J.; Harder, J. W.; Goldan, P. D.; Kuster, W. C.; Liu, S. C.; Baumann, Karsten; Tanner, David J.; Fried, Alan; Sewell, Scott; Cantrell, C. A.; Shetter, R. E.

doi:10.1029/96jd03322

Cited by 141 publications

(120 citation statements)

References 55 publications

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“…(1) Recent tropospheric field measurements have shown that there is still a significant disagreement between measured OH concentrations and the predictions from regional scale models [Crosley, 1997;McKeen et al, 1997]. Isoprene can be a major OH sink under certain conditions accounting for up to 30% of the OH removal rate [Biesenthal and Bottenheim, 1998 …”

Section: Oh + Csi-ia --• Productsmentioning

confidence: 99%

Kinetics of the OH‐initiated oxidation of isoprene

Campuzano‐Jost

Williams

O'Ottone

et al. 2000

Geophysical Research Letters

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Abstract. Absolute rate coefficients have been determined for the reaction OH + CsI-Is (1) and two of its isotopomeric variants. Reaction (1) was studied as a function of temperature and pressure in N2, N2/02 and He buffer gases. At room temperature, a rate coefficient, k•, of (8.564-0.26)'104• cm 3 s 4 independent of pressure and buffer gas identity was obtained. An Arrhenius fit to data over the temperature range 250 -340 K gave a negative activation energy of-6664-150 cal/mol. HO2 production was inferred from observations of radical regeneration in the presence of NO. The absence of a kinetic isotope effect, together with the specificity of radical regeneration, indicates that reaction proceeds via an addition channel with no significant abstraction component. Our rate coefficient for reaction (1) is 15% lower than the value currently recommenced for atmospheric modeling.

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Section: Oh + Csi-ia --• Productsmentioning

confidence: 99%

Kinetics of the OH‐initiated oxidation of isoprene

Campuzano‐Jost

Williams

O'Ottone

et al. 2000

Geophysical Research Letters

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“…Hence it is an ideal target species to test the accuracy of tropospheric chemical mechanisms via comparison of measured [OH] with predictions of zero-dimensional models constrained by supporting measurements of the longerlived OH co-reactant trace gas concentrations, and photolysis rates, that define its rate of production and loss. Tropospheric measurements of OH concentrations have been made in various environments for about two decades , and references therein) together with supporting measurements, and, whilst the measured/modelled agreement has in general improved, there remain discrepancies Carslaw et al, 1999;McKeen et al, 1997;Bell et al, 2003). A commonly suggested hypothesis for model over-prediction of [OH] is an incomplete suite of supporting measurements of trace gas compounds that act as OH sinks .…”

Section: Introductionmentioning

confidence: 99%

A flow-tube based laser-induced fluorescence instrument to measure OH reactivity in the troposphere

et al. 2009

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Abstract.A field instrument utilising the artificial generation of OH radicals in a sliding injector flow-tube reactor with detection by laser-induced fluorescence spectroscopy has been developed to measure the rate of decay of OH by reaction with its atmospheric sinks. The OH reactivity instrument has been calibrated using known concentrations of CO, NO 2 and single hydrocarbons in a flow of zero air, and the impact of recycling of OH via the reaction HO 2 +NO→OH+NO 2 on the measured OH reactivity has been quantified. As well as a detailed description of the apparatus, the capabilities of the new instrument are illustrated using representative results from deployment in the semi-polluted marine boundary layer at the Weybourne Atmospheric Observatory, UK, and in a tropical rainforest at the Bukit Atur Global Atmospheric Watch station, Danum Valley, Borneo.

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“…Many of these compounds have important implications for modeling the chemistry in the atmosphere. For example light carbonyls such as formaldehyde and acetone can influence the HOx budget in the upper troposphere (Mckeen et al, 1997). Acetone and acetaldehyde can also be converted to acetyl peroxy radicals by atmospheric oxidation and lead to formation of PAN (peroxyacetic nitric anhydride) type compounds, which act as relatively long-lived reservoirs for nitrogen oxides (NOx) (Roberts et al, 1998).…”

Section: Introductionmentioning

confidence: 99%

The Tropical Forest and Fire Emissions Experiment: method evaluation of volatile organic compound emissions measured by PTR-MS, FTIR, and GC from tropical biomass burning

et al. 2007

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Abstract. Volatile Organic Compound (VOC) emissions from fires in tropical forest fuels were quantified using Proton-Transfer-Reaction Mass Spectrometry (PTRMS), Fourier Transform Infrared Spectroscopy (FTIR) and gas chromatography (GC) coupled to PTRMS (GC-PTR-MS). We investigated VOC emissions from 19 controlled laboratory fires at the USFS (United States Forest Service) Fire Sciences Laboratory and 16 fires during an intensive airborne field campaign during the peak of the burning season in Brazil in 2004. The VOC emissions were dominated by oxygenated VOCs (OVOC) (OVOC/NMHC ∼4:1, NMHC: nonmethane hydrocarbons) The specificity of the PTR-MS instrument, which measures the mass to charge ratio of VOCs ionized by H 3 O + ions, was validated by gas chromatography and by intercomparing in-situ measurements with those obtained from an open path FTIR instrument. Emission ratios for methyl vinyl ketone, methacrolein, crotonaldehyde, acrylonitrile and pyrrole were measured in the field for the first time. Our measurements show a higher contribution of OVOCs than previously assumed for modeling purposes. Comparison of fresh (<15 min) and aged (>1 h-1 d) smoke suggests altered emission ratios due to gas phase chemistry for acetone but not for acetaldehyde and methanol. Emission ratios for numerous, important, reactive VOCs with respect to acetonitrile (a biomass burning tracer) are presented.

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Photochemical modeling of hydroxyl and its relationship to other species during the Tropospheric OH Photochemistry Experiment

Cited by 141 publications

References 55 publications

Kinetics of the OH‐initiated oxidation of isoprene

Kinetics of the OH‐initiated oxidation of isoprene

A flow-tube based laser-induced fluorescence instrument to measure OH reactivity in the troposphere

The Tropical Forest and Fire Emissions Experiment: method evaluation of volatile organic compound emissions measured by PTR-MS, FTIR, and GC from tropical biomass burning

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