Convergent iterative methods for multicomponent diffusion

Vincent Giovangigli

doi:10.1016/0899-8248(91)90010-R

Convergent iterative methods for multicomponent diffusion

Vincent Giovangigli

Research output: Contribution to journal › Article › peer-review

Abstract

We investigate iterative methods for solving consistent linear systems arising from the kinetic theory of gases and for providing multicomponent diffusion coefficients for gaseous mixtures. Various iterative schemes are proved to be convergent by using the properties of matrices with convergent powers and the properties of nonnegative matrices. In particular, we investigate Stefan-Maxwell diffusion equations and we express the multicomponent diffusion matrix as a symmetric convergent series. We also rigorously justify the accuracy of Hirschfelder-Curtiss approximations with mass correctors often used to approximate diffusion velocities in gas mixtures.

Original language	English
Pages (from-to)	244-276
Number of pages	33
Journal	IMPACT of Computing in Science and Engineering
Volume	3
Issue number	3
DOIs	https://doi.org/10.1016/0899-8248(91)90010-R
Publication status	Published - 1 Jan 1991

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title = "Convergent iterative methods for multicomponent diffusion",

abstract = "We investigate iterative methods for solving consistent linear systems arising from the kinetic theory of gases and for providing multicomponent diffusion coefficients for gaseous mixtures. Various iterative schemes are proved to be convergent by using the properties of matrices with convergent powers and the properties of nonnegative matrices. In particular, we investigate Stefan-Maxwell diffusion equations and we express the multicomponent diffusion matrix as a symmetric convergent series. We also rigorously justify the accuracy of Hirschfelder-Curtiss approximations with mass correctors often used to approximate diffusion velocities in gas mixtures.",

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AU - Giovangigli, Vincent

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N2 - We investigate iterative methods for solving consistent linear systems arising from the kinetic theory of gases and for providing multicomponent diffusion coefficients for gaseous mixtures. Various iterative schemes are proved to be convergent by using the properties of matrices with convergent powers and the properties of nonnegative matrices. In particular, we investigate Stefan-Maxwell diffusion equations and we express the multicomponent diffusion matrix as a symmetric convergent series. We also rigorously justify the accuracy of Hirschfelder-Curtiss approximations with mass correctors often used to approximate diffusion velocities in gas mixtures.

AB - We investigate iterative methods for solving consistent linear systems arising from the kinetic theory of gases and for providing multicomponent diffusion coefficients for gaseous mixtures. Various iterative schemes are proved to be convergent by using the properties of matrices with convergent powers and the properties of nonnegative matrices. In particular, we investigate Stefan-Maxwell diffusion equations and we express the multicomponent diffusion matrix as a symmetric convergent series. We also rigorously justify the accuracy of Hirschfelder-Curtiss approximations with mass correctors often used to approximate diffusion velocities in gas mixtures.

U2 - 10.1016/0899-8248(91)90010-R

DO - 10.1016/0899-8248(91)90010-R

M3 - Article

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SN - 0899-8248

VL - 3

SP - 244

EP - 276

JO - IMPACT of Computing in Science and Engineering

JF - IMPACT of Computing in Science and Engineering

IS - 3

ER -

Convergent iterative methods for multicomponent diffusion

Abstract

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