Hydrogen Peroxide Decomposition Rate: A Shock Tube Study Using Tunable Laser Absorption of H<sub>2</sub>O near 2.5 μm

Hong, Zekai; Farooq, Aamir; Barbour, Ethan A.; Davidson, David F.; Hanson, Ronald K.

doi:10.1021/jp907219f

Cited by 69 publications

(103 citation statements)

References 29 publications

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“…Both studies [93,94] fitted E values to match available experimental data. Troe [94] regards that the two theoretical studies [93,94] represent the experimental data within their scatter equally well, though we find that predictions of the present model using k 15 from Troe [94] yield better agreement than that of Sellevåg et al [93] with the experimental data of Hong et al [87,92] at combustion-relevant temperatures. In fact, predictions of the present model that use the k 15 expression from Troe [94] actually represent the experimental data of Hong et al [87,92] better than predictions of the present model that use the k 15 expression that Hong et al derive from their data (see Fig.…”

Section: Other Modificationsmentioning

confidence: 40%

“…The validation set here includes the full validation set from our previous models [12,47] as well as more recent measurements that have become available since the publication of the model of Li et al [12]; many of these newly available measurements focus on high-pressure, low-temperature conditions. For example, new measurements have become available for speciation during H 2 oxidation [42], H 2 O reaction with O 2 [71], and H 2 O 2 decomposition [87,92]; ignition delay times in shock tubes [10] and rapid compression machines (RCM) [11]; and flame speeds and mass burning rates [5][6][7][8][9].…”

Section: Model Performancementioning

confidence: 99%

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Comprehensive H₂/O₂ kinetic model for high‐pressure combustion

Burke¹,

Chaos²,

Ju³

et al. 2011

Int J of Chemical Kinetics

718

441

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An updated H 2 /O 2 kinetic model based on that of Li et al. (Int J Chem Kinet 36, 2004, 566-575) is presented and tested against a wide range of combustion targets. The primary motivations of the model revision are to incorporate recent improvements in rate constant treatment and resolve discrepancies between experimental data and predictions using recently published kinetic models in dilute, high-pressure flames. Attempts are made to identify major remaining sources of uncertainties, in both the reaction rate parameters and the assumptions of the kinetic model, affecting predictions of relevant combustion behavior. With regard to model parameters, present uncertainties in the temperature and pressure dependence of rate constants for HO 2 formation and consumption reactions are demonstrated to substantially affect predictive capabilities at high-pressure, low-temperature conditions. With regard to model assumptions, calculations are performed to investigate several reactions/processes that have not received much attention previously. Results from ab initio calculations and modeling studies imply that inclusion of H + HO 2 = H 2 O + O in the kinetic model might be warranted, though further studies are necessary to ascertain its role in combustion modeling. In addition, it appears that characterization of nonlinear bath-gas mixture rule behavior for H + O 2 (+ M) = HO 2 (+ M) in multicomponent bath gases might be necessary to predict high-pressure flame speeds within ∼15%. The updated model is tested against all of the previous validation targets considered by Li et al. as well as new targets from a number of recent studies. Special attention is devoted to establishing a context for evaluating model performance against experimental data by careful consideration of uncertainties in measurements, initial conditions, and physical modelCorrespondence to: Michael P. Burke;

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Section: Other Modificationsmentioning

confidence: 40%

Section: Model Performancementioning

confidence: 99%

Comprehensive H₂/O₂ kinetic model for high‐pressure combustion

Burke¹,

Chaos²,

Ju³

et al. 2011

Int J of Chemical Kinetics

718

441

View full text Add to dashboard Cite

show abstract

“…Incident shock speeds were extrapolated to the end wall by measuring the incident shock arrival times using five piezoelectric pressure transducers (PCB 134) spread over the last meter of the driven section. Temperatures and pressures behind the reflected shock waves were calculated using standard normal-shock relations and the measured incident shock speed, with an uncertainty of ∼1% over the high-quality test time of 2 ms [13]. The laser diagnostic, along with a Kistler piezoelectric pressure transducer (601B1) for pressure measurements, was located in the test section at 2 cm from the end wall.…”

Section: Shock Tube Facilitiesmentioning

confidence: 99%

“…In future work, the H 2 O concentration during hydrocarbon oxidation could be measured directly and accurately using tunable diode laser absorption near 2.5 μm, a method which has been developed and widely applied in shock tube studies of H 2 /O 2 combustion system in our laboratory [13,23,24]. Alternatively, a second CO 2 line (i.e., the P(28) transition at 10.675 μm), which is away from the peak ethylene absorption, could be selected to account for the H 2 O interfering absorbance.…”

Section: H 4 Time Histories During Ethylene Oxidationmentioning

confidence: 99%

IR laser absorption diagnostic for C₂H₄ in shock tube kinetics studies

Ren

Davidson

Hanson

2012

Int J of Chemical Kinetics

Self Cite

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An IR laser absorption diagnostic has been further developed for accurate and sensitive time-resolved measurements of ethylene in shock tube kinetic experiments. The diagnostic utilizes the P14 line of a tunable CO 2 gas laser at 10.532 μm (the (0 0 1) → (1 0 0) vibrational band) and achieves improved signal-to-noise ratio by using IR photovoltaic detectors and accurate identification of the P14 line via an MIR wavemeter. Ethylene absorption cross sections were measured over 643-1959 K and 0.3-18.6 atm behind both incident and reflected shock waves, showing evident exponential decay with temperature. Very weak pressure dependence was observed over the pressure range of 1.2-18.6 atm. By measuring ethylene decomposition time histories at high-temperature conditions (1519-1895 K, 2.0-2.8 atm) behind reflected shocks, the rate coefficient of the dominant elementary reaction C 2 H 4 + M → C 2 H 2 + H 2 + M was determined to be k 1 = (2.6 ± 0.5) × 10 16 exp(−34,130/T , K) cm 3 mol −1 s −1 with low data scatter. Ethylene concentration time histories were also measured during the oxidation of 0.5% C 2 H 4 /O 2 /Ar mixtures varying in equivalence ratio from 0.25 to 2. Initial reflected shock conditions ranged from 1267 to 1440 K and 2.95 to 3.45 atm. The measured time histories were compared to the modeled predictions of four ethylene oxidation mechanisms, showing excellent agreement with the Ranzi et al. mechanism (updated in 2011). This diagnostic scheme provides a promising tool for the study and validation of detailed hydrocarbon pyrolysis and oxidation mechanisms of fuel surrogates and realistic fuels. C 2012 Wiley Periodicals, Inc. Int J Chem

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“…Given our assumption that the model discrepancy is not time dependent we choose five data points where the level of the error is assumed to be constant. The detailed description of the shock tube experiment is provided in [5].…”

Section: Physical Model and Experimental Datamentioning

confidence: 99%

Bayesian optimal experimental design for the Shock-tube experiment

Terejanu¹,

Bryant²,

Miki³

2013

J. Phys.: Conf. Ser.

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Abstract. The sequential optimal experimental design formulated as an information-theoretic sensitivity analysis is applied to the ignition delay problem using real experimental. The optimal design is obtained by maximizing the statistical dependence between the model parameters and observables, which is quantified in this study using mutual information. This is naturally posed in the Bayesian framework. The study shows that by monitoring the information gain after each measurement update, one can design a stopping criteria for the experimental process which gives a minimal set of experiments to efficiently learn the Arrhenius parameters.

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Hydrogen Peroxide Decomposition Rate: A Shock Tube Study Using Tunable Laser Absorption of H₂O near 2.5 μm

Cited by 69 publications

References 29 publications

Comprehensive H₂/O₂ kinetic model for high‐pressure combustion

Comprehensive H₂/O₂ kinetic model for high‐pressure combustion

IR laser absorption diagnostic for C₂H₄ in shock tube kinetics studies

Bayesian optimal experimental design for the Shock-tube experiment

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Hydrogen Peroxide Decomposition Rate: A Shock Tube Study Using Tunable Laser Absorption of H2O near 2.5 μm

Cited by 69 publications

References 29 publications

Comprehensive H2/O2 kinetic model for high‐pressure combustion

Comprehensive H2/O2 kinetic model for high‐pressure combustion

IR laser absorption diagnostic for C2H4 in shock tube kinetics studies

Bayesian optimal experimental design for the Shock-tube experiment

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Product

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Hydrogen Peroxide Decomposition Rate: A Shock Tube Study Using Tunable Laser Absorption of H₂O near 2.5 μm

Comprehensive H₂/O₂ kinetic model for high‐pressure combustion

Comprehensive H₂/O₂ kinetic model for high‐pressure combustion

IR laser absorption diagnostic for C₂H₄ in shock tube kinetics studies