The Importance of Relative Reaction Rates in the Optimization of Detailed Kinetic Models

Manion, Jeffrey A.; McGivern, W. Sean

doi:10.1002/kin.20996

Cited by 15 publications

(14 citation statements)

References 52 publications

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“…However, they did not perform a detailed evaluation of this assumption, which is one of the objectives of the present work. In addition, they did not consider other interdependencies, such as relative correlations arising between competing reactions explored within the present work and that of Manion et al [10]. The authors of this latter study suggested that ignoring such information in the forward propagation of uncertainty and model optimization schemes can lead to physically unrealistic results.…”

Section: Discussionmentioning

confidence: 73%

“…Perhaps for this reason not much attention has been paid to the effects of correlations among reactions. However, from the few studies that have examined these relationships, the effects of neglecting correlations can be non-negligible [6][7][8][9][10]. This phenomenon is also well established in the broader UQ literature for cases where uncertainties are large and correlations are strong between important variables [11].…”

Section: Compression Ignition (Hcci) Reactivity Controlled Compressimentioning

confidence: 88%

“…While kinetic rates for two reactions cannot be exactly equal, it should be expected that a high degree of correlation exists among very similar reactions. Strong correlations between reactions with multiple branches can arise in cases when the total rate constant of a reaction may be known better than the branching ratios [8], or vice versa [10], attributed to experimental or theoretical limitations. Proper treatment of correlations arising from the use of rate rules in forward propagation of uncertainty was left as an open question in [3], and this serves as part of the motivation of the present study.…”

Section: Compression Ignition (Hcci) Reactivity Controlled Compressimentioning

confidence: 99%

“…Very recently, in a similarly motivated study using a small representative model, Manion et al [10] showed that for UQ where very precise relative rate constant measurements are available, e.g., branching ratios, treating reactions as independent variables can grossly overestimate the extent of uncertainty in the predicted ignition delays. Their observations are consistent with the present simulation results for Case 5 in Fig.…”

Section: Correlations Between Reactions With Multiple Branchesmentioning

confidence: 99%

See 3 more Smart Citations

The role of correlations in uncertainty quantification of transportation relevant fuel models

Fridlyand

Johnson

Goldsborough

et al. 2017

Combustion and Flame

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Large reaction mechanisms are often used to describe the combustion behavior of transportation-relevant fuels like gasoline, where these are typically represented by surrogate blends, e.g., n-heptane/iso-octane/toluene. We describe efforts to quantify the uncertainty in the predictions of such mechanisms at realistic engine conditions, seeking to better understand the robustness of the model as well as the important reaction pathways and their impacts on combustion behavior. In this work, we examine the importance of taking into account correlations among reactions that utilize the same rate rules and those with multiple product channels on forward propagation of uncertainty by Monte Carlo simulations. Automated means are developed to generate the uncertainty factor assignment for a detailed chemical kinetic mechanism, by first uniquely identifying each reacting species, then sorting each of the reactions based on the rate rule utilized. Simulation results reveal that in the low temperature combustion regime for iso-octane, the majority of the uncertainty in the model predictions can be attributed to low temperature reactions of the fuel sub-mechanism. The foundational, or small-molecule chemistry (C 0-C 4) only contributes significantly to uncertainties in the predictions at the highest temperatures (Tc=900 K). Accounting for correlations between important reactions is shown to produce non-negligible differences in the estimates of uncertainty. Including correlations among reactions that use the same rate rules increases uncertainty in the model predictions, while accounting for correlations among reactions with multiple branches decreases uncertainty in some cases. Significant non-linear response is observed in the model predictions depending on how the probability distributions of the uncertain rate constants are defined. It is concluded that care must be exercised in defining these probability distributions in order to reduce bias, and physically unrealistic estimates in the forward propagation of uncertainty for a range of UQ activities.

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Section: Discussionmentioning

confidence: 73%

Section: Compression Ignition (Hcci) Reactivity Controlled Compressimentioning

confidence: 88%

Section: Compression Ignition (Hcci) Reactivity Controlled Compressimentioning

confidence: 99%

Section: Correlations Between Reactions With Multiple Branchesmentioning

confidence: 99%

See 2 more Smart Citations

The role of correlations in uncertainty quantification of transportation relevant fuel models

Fridlyand

Johnson

Goldsborough

et al. 2017

Combustion and Flame

View full text Add to dashboard Cite

show abstract

“…The deduction of chemical models from experimental observations is a central problem of current chemical kinetics [1][2][3][4][5][6][7][8][9]. In practice, elementary reactions can seldom be investigated without the interference of other processes as kinetic coupling is a very common phenomenon.…”

Section: Introductionmentioning

confidence: 99%

Double Exponential Evaluation under Non-Pseudo-First-Order Conditions: A Mixed Second-Order Process Followed by a First-Order Reaction

Kiss

Ősz

2017

Int. J. Chem. Kinet.

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In this paper, a double exponential approximating approach is described for a quite common kinetic model (mixed second‐order formation of an intermediate followed by its first‐order decay) under non‐pseudo–first‐order conditions (i.e., when the initial ratio of the two reactants is between 1 and 10). For the evaluation, first the exact kinetic curves predicted by the two‐step model were calculated and then fitted to a double exponential function. The goodness of the fits and the estimated parameters of the double exponential function for both I and P concentrations were determined as a function of the rate constants and initial concentrations in the two‐step model. It was found that the fit of the double exponential function is acceptable or very good under these conditions despite the fact that none of the reagents is in a large excess. Since UV–vis absorption spectroscopy is probably the most common technique to follow kinetic traces, we also made efforts to deal with the typical properties of monitoring the process through UV–vis. It was found that the experimental curves can be fitted quite well with a double exponential function if the reagents have minor absorption compared to the intermediate and/or product. The connection between the observed rate constants and the rate constants of the above‐mentioned mechanism is also studied.

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Kinetics of isopropanol decomposition and reaction with H atoms from shock tube experiments and rate constant optimization using the method of uncertainty minimization using polynomial chaos expansions (MUM‐PCE)

Mertens

Manion

2020

Int J of Chemical Kinetics

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We have used the single-pulse shock tube technique with postshock GC/MS product analysis to investigate the mechanism and kinetics of the unimolecular decomposition of isopropanol, a potential biofuel, and of its reaction with H atoms at 918-1212 K and 183-484 kPa. Experiments employed dilute mixtures in argon of isopropanol, a radical scavenger, and, for H-atom studies, two different thermal precursors of H. Without an added H source, isopropanol decomposes in our studies predominantly by molecular dehydration. Added H atoms significantly augment decomposition, mainly by abstraction of the tertiary and primary hydrogens, reactions that, respectively, lead to acetone and propene as stable organic products. Traces of acetaldehyde were observed in some experiments above ≈ 1100 K and establish branching limits for minor decomposition pathways. To quantitatively account for secondary chemistry and optimize rate constants of interest, we employed the method of uncertainty minimization using polynomial chaos expansions (MUM-PCE) to carry out a unified analysis of all datasets using a chemical model-based originally on JetSurF 2.0. We find: k(isopropanol → propene + H 2 O) = 10 (13.87 ± 0.69) exp(−(33 099 ± 979) K/ T) s −1 at 979-1212 K and 286-484 kPa, with a factor of two uncertainty (2σ), including systematic errors. For H atom reactions, optimization yields: k(H + isopropanol → H 2 + p-C 3 H 6 OH) = 10 (6.25 ± 0.42) T 2.54 exp(−(3993 ± 1028) K /T) cm 3 mol −1 s −1 and k(H + isopropanol → H 2 + t-C 3 H 6 OH) = 10 (5.83 ± 0.37) T 2.40 exp(−(1507 ± 957) K /T) cm 3 mol −1 s −1 at 918-1142 K and 183-323 kPa. We compare our measured rate constants with estimates used in current combustion models and discuss how hydrocarbon functionalization with an OH group affects H abstraction rates.

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The Importance of Relative Reaction Rates in the Optimization of Detailed Kinetic Models

Cited by 15 publications

References 52 publications

The role of correlations in uncertainty quantification of transportation relevant fuel models

The role of correlations in uncertainty quantification of transportation relevant fuel models

Double Exponential Evaluation under Non-Pseudo-First-Order Conditions: A Mixed Second-Order Process Followed by a First-Order Reaction

Kinetics of isopropanol decomposition and reaction with H atoms from shock tube experiments and rate constant optimization using the method of uncertainty minimization using polynomial chaos expansions (MUM‐PCE)

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