Harnessing the Combined Power of Theoretical and Experimental Data through Multiscale Informatics

Burke, Michael P.

doi:10.1002/kin.20984

Cited by 36 publications

(17 citation statements)

References 145 publications

(437 reference statements)

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“…The role of theory in developing a detailed molecular level description of low-temperature radical oxidation is then summarized through a review of our long-term studies of ethyl and propyl radical oxidations. A semiquantitative understanding of the uncertainties in theoretical predictions can be of great value in modeling, as demonstrated by Burke in his multiscale modeling approach [ 28 ]. These studies ultimately led us to the realization that at combustion temperatures the foundational assumption of thermalization prior to reaction is not always valid, and further that its breakdown significantly affects key combustion properties.…”

Section: Introductionmentioning

confidence: 99%

From theoretical reaction dynamics to chemical modeling of combustion

Klippenstein

2017

Proceedings of the Combustion Institute

223

228

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The chemical modeling of combustion treats the chemical conversion of hundreds of species through thousands of reactions. Recent advances in theoretical methodologies and computational capabilities have transformed theoretical chemical kinetics from a largely empirical to a highly predictive science. As a result, theoretical chemistry is playing an increasingly significant role in the combustion modeling enterprise. The accurate prediction of the temperature and pressure dependence of gas phase reactions requires state-of-the-art implementations of a variety of theoretical methods: ab initio electronic structure theory, transition state theory, classical trajectory simulations, and the master equation. In this work, we illustrate the current state-of-the-art in predicting the kinetics of gas-phase reactions through sample calculations for some prototypical reactions central to combustion chemistry. These studies are used to highlight the success of theory, as well as its remaining challenges, through comparisons with experiments ranging from elementary reaction kinetics studies through to global observations such as flame speed measurements. The illustrations progress from the treatment of relatively simple abstraction and addition reactions, which proceed over a single transition state, through to the complexity of multiwell multichannel reactions that commonly occur in studies of the growth of polycyclic aromatic hydrocarbons. In addition to providing high quality rate prescriptions for combustion modelers, theory will be seen to indicate various shortcomings in the foundations of chemical modeling. Future progress in the fidelity of the chemical modeling of combustion will benefit from more widespread applications of theoretical chemical kinetics and from increasingly intimate couplings of theory, experiment, and modeling.

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Section: Introductionmentioning

confidence: 99%

From theoretical reaction dynamics to chemical modeling of combustion

Klippenstein

2017

Proceedings of the Combustion Institute

223

228

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“…The combination of parameters that minimized the sum of square error between the log of the measured rate constants and the log of the RRKM/ME predictions was chosen as the optimum set. The optimization of electronic structure and master equation properties against experimental data is inspired by the Multiscale Informatics of Burke and co-workers. − …”

Section: Modelingmentioning

confidence: 99%

Shock Tube Laser Schlieren Study of the Pyrolysis of Isopropyl Nitrate

Fuller

Goldsmith

2019

J. Phys. Chem. A

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The decomposition of isopropyl nitrate was measured behind incident shock waves using laser schlieren densitometry in a diaphragmless shock tube. Experiments were conducted over the temperature range of 700–1000 K and at pressures of 71, 126, and 240 Torr. Electronic structure theory and RRKM Master Equation methods were used to predict the decomposition kinetics. RRKM/ME parameters were optimized against the experimental data to provide an accurate prediction over a broader range of conditions. The initial decomposition i-C3H7ONO2 ⇌ i-C3H7O + NO2 has a high-pressure limit rate coefficient of 5.70 × 1022 T –1.80 exp[−21287.5/T] s–1. A new chemical kinetic mechanism was developed to model the chemistry after the initial dissociation. A new shock tube module was developed for Cantera, which allows for arbitrarily large mechanisms in the simulation of laser schlieren experiments. The present work is in good agreement with previous experimental studies.

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“…In the meantime, mixture rules should be considered a significant structural uncertainty in chemical kinetics simulations and uncertainty quantification, 66−69 as discussed elsewhere. 69 While the present calculations use the commonly employed exponential-down model to facilitate straightforward interpretations of the analytical solutions and to allow compatibility with the vast majority of calculated rate constants, which use the same model, improved quantification of mixture effects in future studies could be attained by using energy and angular momentum transfer functions determined via trajectory calculations and/or experimental measurements within a twodimensional master equation. Naturally, as with rate constant calculations for even single-component bath gases for many pressure-dependent reactions, such mixture studies await such data to become available for a wider variety of bath gases and reactant complexes.…”

Section: The Journal Of Physical Chemistry Amentioning

confidence: 99%

Bath Gas Mixture Effects on Multichannel Reactions: Insights and Representations for Systems beyond Single-Channel Reactions

Lei

Burke

2018

J. Phys. Chem. A

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Nearly all studies of and available data for pressure-dependent reactions focus on pure bath gases. Of the comparatively fewer studies on bath gas mixtures, important to combustion and planetary atmospheres, nearly all focus on single-channel reactions. The present study explores, and seeks reliable representations of, bath gas mixture effects on multichannel reactions. Analytical and numerical solutions of the master equation here reveal several unique manifestations of mixture effects for multichannel reactions, including behavior completely opposite to trends observed for single-channel reactions. The most common way of evaluating mixture rate constants from data for pure components, the classic linear mixture rule, is found to yield errors exceeding a factor of ∼10. A new linear mixture rule based on the reduced pressure, instead of the absolute pressure, is found to be accurate within ∼30% for rate constants (and ∼50% for the branching ratio). A new nonlinear mixture rule that additionally incorporates analytically derived activity coefficients is found to be accurate within ∼10% for rate constants and branching ratios. These new mixture rules are therefore recommended for use in fundamental and applied chemical kinetics investigations of reacting mixtures, including reacting flow codes and experimental interpretations of third-body efficiencies.

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Harnessing the Combined Power of Theoretical and Experimental Data through Multiscale Informatics

Cited by 36 publications

References 145 publications

From theoretical reaction dynamics to chemical modeling of combustion

From theoretical reaction dynamics to chemical modeling of combustion

Shock Tube Laser Schlieren Study of the Pyrolysis of Isopropyl Nitrate

Bath Gas Mixture Effects on Multichannel Reactions: Insights and Representations for Systems beyond Single-Channel Reactions

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