Standard

Mutual influence between flow compressibility and chemical-reaction rates in gas mixtures. / Kustova, Elena V.; Nagnibeda, Ekaterina A.; Giordano, Domenico.

In: European Space Agency (Scientific and Technical Reports) ESA STR, No. 255, 01.01.2008, p. 1-48.

Research output: Contribution to journalArticlepeer-review

Harvard

Kustova, EV, Nagnibeda, EA & Giordano, D 2008, 'Mutual influence between flow compressibility and chemical-reaction rates in gas mixtures', European Space Agency (Scientific and Technical Reports) ESA STR, no. 255, pp. 1-48.

APA

Kustova, E. V., Nagnibeda, E. A., & Giordano, D. (2008). Mutual influence between flow compressibility and chemical-reaction rates in gas mixtures. European Space Agency (Scientific and Technical Reports) ESA STR, (255), 1-48.

Vancouver

Kustova EV, Nagnibeda EA, Giordano D. Mutual influence between flow compressibility and chemical-reaction rates in gas mixtures. European Space Agency (Scientific and Technical Reports) ESA STR. 2008 Jan 1;(255):1-48.

Author

Kustova, Elena V. ; Nagnibeda, Ekaterina A. ; Giordano, Domenico. / Mutual influence between flow compressibility and chemical-reaction rates in gas mixtures. In: European Space Agency (Scientific and Technical Reports) ESA STR. 2008 ; No. 255. pp. 1-48.

BibTeX

@article{d3f40af4e1f04b3a89930c7aa9a85c16,
title = "Mutual influence between flow compressibility and chemical-reaction rates in gas mixtures",
abstract = "This report deals with a theoretical study of chemical reaction rates and transport processes in non-equilibrium reacting gas flows and the influence of gas mixture compressibility on the reaction rates. A self-consistent model based on the kinetic theory methods is developed taking into account strongly non-equilibrium chemical kinetics in a flow. Tempered reaction regime is studied in the frame of the one-temperature approximation. Gas mixtures with bimolecular reactions, dissociation and recombination are considered. A closed set of non-equilibrium gas dynamic equations coupled to the equations of chemical kinetics in a flow is derived, and distribution functions in the zero and first-order approximations and corresponding expressions for the transport and source terms are obtained. The algorithms for the calculation of transport and reaction rate coefficients are elaborated, allowing to reduce integral equations to the linear algebraic equations. Relations of the reaction rate coefficients to the bulk viscosity coefficient and chemical-reaction contribution to the normal mean stress are established. An alternative problem formulation relating reaction rates and reaction contribution to the normal mean stress to the chemical reaction affinities is proposed, and cross effects between reaction rates and diagonal elements of the viscous stress tensor are found. Thus a consistency of the kinetic theory results with the ones given by linear irreversible thermodynamics is shown.",
author = "Kustova, {Elena V.} and Nagnibeda, {Ekaterina A.} and Domenico Giordano",
year = "2008",
month = jan,
day = "1",
language = "English",
pages = "1--48",
journal = "European Space Agency (Scientific and Technical Reports) ESA STR",
issn = "0379-4067",
publisher = "ESA Publication Division",
number = "255",

}

RIS

TY - JOUR

T1 - Mutual influence between flow compressibility and chemical-reaction rates in gas mixtures

AU - Kustova, Elena V.

AU - Nagnibeda, Ekaterina A.

AU - Giordano, Domenico

PY - 2008/1/1

Y1 - 2008/1/1

N2 - This report deals with a theoretical study of chemical reaction rates and transport processes in non-equilibrium reacting gas flows and the influence of gas mixture compressibility on the reaction rates. A self-consistent model based on the kinetic theory methods is developed taking into account strongly non-equilibrium chemical kinetics in a flow. Tempered reaction regime is studied in the frame of the one-temperature approximation. Gas mixtures with bimolecular reactions, dissociation and recombination are considered. A closed set of non-equilibrium gas dynamic equations coupled to the equations of chemical kinetics in a flow is derived, and distribution functions in the zero and first-order approximations and corresponding expressions for the transport and source terms are obtained. The algorithms for the calculation of transport and reaction rate coefficients are elaborated, allowing to reduce integral equations to the linear algebraic equations. Relations of the reaction rate coefficients to the bulk viscosity coefficient and chemical-reaction contribution to the normal mean stress are established. An alternative problem formulation relating reaction rates and reaction contribution to the normal mean stress to the chemical reaction affinities is proposed, and cross effects between reaction rates and diagonal elements of the viscous stress tensor are found. Thus a consistency of the kinetic theory results with the ones given by linear irreversible thermodynamics is shown.

AB - This report deals with a theoretical study of chemical reaction rates and transport processes in non-equilibrium reacting gas flows and the influence of gas mixture compressibility on the reaction rates. A self-consistent model based on the kinetic theory methods is developed taking into account strongly non-equilibrium chemical kinetics in a flow. Tempered reaction regime is studied in the frame of the one-temperature approximation. Gas mixtures with bimolecular reactions, dissociation and recombination are considered. A closed set of non-equilibrium gas dynamic equations coupled to the equations of chemical kinetics in a flow is derived, and distribution functions in the zero and first-order approximations and corresponding expressions for the transport and source terms are obtained. The algorithms for the calculation of transport and reaction rate coefficients are elaborated, allowing to reduce integral equations to the linear algebraic equations. Relations of the reaction rate coefficients to the bulk viscosity coefficient and chemical-reaction contribution to the normal mean stress are established. An alternative problem formulation relating reaction rates and reaction contribution to the normal mean stress to the chemical reaction affinities is proposed, and cross effects between reaction rates and diagonal elements of the viscous stress tensor are found. Thus a consistency of the kinetic theory results with the ones given by linear irreversible thermodynamics is shown.

UR - http://www.scopus.com/inward/record.url?scp=39749167760&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:39749167760

SP - 1

EP - 48

JO - European Space Agency (Scientific and Technical Reports) ESA STR

JF - European Space Agency (Scientific and Technical Reports) ESA STR

SN - 0379-4067

IS - 255

ER -

ID: 34514465