Rate Constants, 1100 ≤ <i>T</i> ≤ 2000 K, for H + NO<sub>2</sub> → OH + NO Using Two Shock Tube Techniques:  Comparison of Theory to Experiment

Su, M.‐C.; Kumaran, S. S.; Lim, K. P.; Michael, J. V.; Wagner, Albert F.; Harding, Lawrence B.; Fang, De‐Cai

doi:10.1021/jp0141023

Cited by 61 publications

(72 citation statements)

References 59 publications

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“…50 Our results show that reaction (1) is efficient and leads to the formation of two reactants that act as parent species of more complex molecules observed in our experiments:…”

Section: Discussionsupporting

confidence: 58%

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO₂

Ioppolo

Fedoseev

Minissale

et al. 2014

Phys. Chem. Chem. Phys.

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“…50 Our results show that reaction (1) is efficient and leads to the formation of two reactants that act as parent species of more complex molecules observed in our experiments:…”

Section: Discussionsupporting

confidence: 58%

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO₂

Ioppolo

Fedoseev

Minissale

et al. 2014

Phys. Chem. Chem. Phys.

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“…For OH detection at 308 nm, a White cell, radially located at 6 cm from the endplate (as described previously [16][17][18]) was used to increase the absorption path length. It was constructed from two flat fused silica windows (3.81 cm), mounted on the tube across from one another, with broadband antireflection (BB AR) coating for UV light.…”

Section: Methodsmentioning

confidence: 99%

“…The distance between windows was 8.745 cm. The optical configuration consisted of an OH resonance lamp [16,17], multi-pass reflectors, an interference filter at 308 nm, and a photomultiplier tube (1P28) all mounted external to the shock tube. The photomultiplier signal was recorded with a LC334A LeCroy digital oscilloscope.…”

Section: Methodsmentioning

confidence: 99%

“…These reflectors were attached to adjustable mounts, and the center points of windows and mirrors were all in a coaxial position. With this new configuration, 48 multiple passes were used, thereby amplifying the measured absorbances by about a factor of ∼4.5 over that used in the previous work [17,18]. This increase in sensitivity for OH-radical detection allows for the detection of lower [OH] and therefore decreases the importance of secondary reaction perturbations.…”

Section: Methodsmentioning

confidence: 99%

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Shock tube measurements of high temperature rate constants for OH with cycloalkanes and methylcycloalkanes

Sivaramakrishnan

Michael

2009

Combustion and Flame

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“…Since k 14 is considered to be well-characterized (Ko and Fontijn, 1991;Su et al, 2002), measurements of O 2 and NO 2 profiles can be used to estimate the low-pressure rate constant of (R1), k 1,0 . This is evident by performing a steady-state analysis of HO 2 and NO 2 concentrations, using the reactions above, which yields:…”

Section: Summary Of Results and Discussionmentioning

confidence: 99%

Chemical Kinetics in Support of Syngas Turbine Combustion

Dryer¹

2007

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Executive SummaryThis document is the final report on an overall program formulated to extend our prior work in developing and validating kinetic models for the CO/hydrogen/oxygen reaction by carefully analyzing the individual and interactive behavior of specific elementary and subsets of elementary reactions at conditions of interest to syngas combustion in gas turbines. A summary of the tasks performed under this work are: 1. Determine experimentally the third body efficiencies in H+O 2 +M = HO 2 +M (R1) for CO 2 Results are summarized in this document and its appendices. Three archival papers which contain a majority of the research results have appeared. Those results not published elsewhere are highlighted here, and will appear as part of future publications. Portions of the work appearing in the above publications were also supported in part by the Department of Energy under Grant No. DE-FG02-86ER-13503.As a result of and during the research under the present contract, we became aware of other reported results that revealed substantial differences between experimental characterizations of ignition delays for syngas mixtures and ignition delay predictions based upon homogenous kinetic modeling. We adjusted emphasis of Task 2 to understand the source of these noted disparities because of their key importance to developing lean premixed combustion technologies of syngas turbine applications. In performing Task 3, we also suggest for the first time the very significant effect that metal carbonyls may have on syngas combustion properties. This work is fully detailed in Appendix C. The work on metal carbonyl effects is entirely computational in nature. Pursuit of experimental verification of these interactions was beyond the scope of the present work.3 Results over this Progress Period ApproachThe present research further extended our prior work in developing and validating kinetic models for the CO/hydrogen/oxygen principally studied under Department of Energy Grant No. DE-FG02-86ER-13503, by providing additional experimental data using a Variable Pressure Flow Reactor (VPFR) on the collisional efficiencies of water and carbon dioxide in the reaction H+O 2 +M = HO 2 + M (R1) by carefully analyzing the individual and interactive behavior of specific elementary and subsets of elementary reactions at the conditions of interest, and by extending computational model comparisons with data obtained in this program and those appearing in the literature since 2004 to further test and refine the model at conditions relevant to gas turbine applications. Additionally, syngas contaminant species such as small hydrocarbons (e.g., methane) and other combustion gas components (e.g. NO x ) have been identified and it is suspected that these contaminants may affect syngas chemistry in gas turbine applications, particularly in mixing regions of entering fuel and air. These contaminants can have significant influence on some of the kinetic behavior. The initial research plan was to investigate only the effects of small local amo...

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Rate Constants, 1100 ≤ T ≤ 2000 K, for H + NO₂ → OH + NO Using Two Shock Tube Techniques: Comparison of Theory to Experiment

Cited by 61 publications

References 59 publications

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO₂

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO₂

Shock tube measurements of high temperature rate constants for OH with cycloalkanes and methylcycloalkanes

Chemical Kinetics in Support of Syngas Turbine Combustion

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Rate Constants, 1100 ≤ T ≤ 2000 K, for H + NO2 → OH + NO Using Two Shock Tube Techniques: Comparison of Theory to Experiment

Cited by 61 publications

References 59 publications

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO2

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO2

Shock tube measurements of high temperature rate constants for OH with cycloalkanes and methylcycloalkanes

Chemical Kinetics in Support of Syngas Turbine Combustion

Contact Info

Product

Resources

About

Rate Constants, 1100 ≤ T ≤ 2000 K, for H + NO₂ → OH + NO Using Two Shock Tube Techniques: Comparison of Theory to Experiment

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO₂

Solid state chemistry of nitrogen oxides – Part II: surface consumption of NO₂