A fully coupled 3d transport model in SPH for multi-species reaction-diffusion systems

S. Adami; X. Y. Hu; N. A. Adams; E. M. Ryan; A. M. Tartakovsky

A fully coupled 3d transport model in SPH for multi-species reaction-diffusion systems

S. Adami
, X. Y. Hu
, N. A. Adams
, E. M. Ryan
, A. M. Tartakovsky

Chair of Aerodynamics and Fluid mechanics

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

In this paper we present a fully generalized transport model for multiple species in complex two and three-dimensional geometries. Based on previous work [1] we have extended our interfacial reaction-diffusion model to handle arbitrary numbers of species allowing for coupled reaction models. Each species is tracked independently and we consider different physics of a species with respect to the bulk phases in contact. We use our SPH model to simulate the reaction-diffusion problem on a pore-scale level of a solid oxide fuel cell (SOFC) with special emphasize on the effect of surface diffusion.

Original language	English
Title of host publication	Particle-Based Methods II - Fundamentals and Applications
Pages	139-151
Number of pages	13
State	Published - 2011
Event	2nd International Conference on Particle-Based Methods, PARTICLES 2011 - Barcelona, Spain Duration: 26 Oct 2011 → 28 Oct 2011

Publication series

Name	Particle-Based Methods II - Fundamentals and Applications

Conference

Conference	2nd International Conference on Particle-Based Methods, PARTICLES 2011
Country/Territory	Spain
City	Barcelona
Period	26/10/11 → 28/10/11

Keywords

Porous media
Reaction-diffusion
SPH

Cite this

@inproceedings{86a594b7ea584644865b228fe17a700b,

title = "A fully coupled 3d transport model in SPH for multi-species reaction-diffusion systems",

abstract = "In this paper we present a fully generalized transport model for multiple species in complex two and three-dimensional geometries. Based on previous work [1] we have extended our interfacial reaction-diffusion model to handle arbitrary numbers of species allowing for coupled reaction models. Each species is tracked independently and we consider different physics of a species with respect to the bulk phases in contact. We use our SPH model to simulate the reaction-diffusion problem on a pore-scale level of a solid oxide fuel cell (SOFC) with special emphasize on the effect of surface diffusion.",

keywords = "Porous media, Reaction-diffusion, SPH",

author = "S. Adami and Hu, \{X. Y.\} and Adams, \{N. A.\} and Ryan, \{E. M.\} and Tartakovsky, \{A. M.\}",

year = "2011",

language = "English",

isbn = "9788489925670",

series = "Particle-Based Methods II - Fundamentals and Applications",

pages = "139--151",

booktitle = "Particle-Based Methods II - Fundamentals and Applications",

note = "2nd International Conference on Particle-Based Methods, PARTICLES 2011 ; Conference date: 26-10-2011 Through 28-10-2011",

}

Adami, S, Hu, XY, Adams, NA, Ryan, EM & Tartakovsky, AM 2011, A fully coupled 3d transport model in SPH for multi-species reaction-diffusion systems. in Particle-Based Methods II - Fundamentals and Applications. Particle-Based Methods II - Fundamentals and Applications, pp. 139-151, 2nd International Conference on Particle-Based Methods, PARTICLES 2011, Barcelona, Spain, 26/10/11.

A fully coupled 3d transport model in SPH for multi-species reaction-diffusion systems. / Adami, S.; Hu, X. Y.; Adams, N. A. et al.
Particle-Based Methods II - Fundamentals and Applications. 2011. p. 139-151 (Particle-Based Methods II - Fundamentals and Applications).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - A fully coupled 3d transport model in SPH for multi-species reaction-diffusion systems

AU - Adami, S.

AU - Hu, X. Y.

AU - Adams, N. A.

AU - Ryan, E. M.

AU - Tartakovsky, A. M.

PY - 2011

Y1 - 2011

N2 - In this paper we present a fully generalized transport model for multiple species in complex two and three-dimensional geometries. Based on previous work [1] we have extended our interfacial reaction-diffusion model to handle arbitrary numbers of species allowing for coupled reaction models. Each species is tracked independently and we consider different physics of a species with respect to the bulk phases in contact. We use our SPH model to simulate the reaction-diffusion problem on a pore-scale level of a solid oxide fuel cell (SOFC) with special emphasize on the effect of surface diffusion.

AB - In this paper we present a fully generalized transport model for multiple species in complex two and three-dimensional geometries. Based on previous work [1] we have extended our interfacial reaction-diffusion model to handle arbitrary numbers of species allowing for coupled reaction models. Each species is tracked independently and we consider different physics of a species with respect to the bulk phases in contact. We use our SPH model to simulate the reaction-diffusion problem on a pore-scale level of a solid oxide fuel cell (SOFC) with special emphasize on the effect of surface diffusion.

KW - Porous media

KW - Reaction-diffusion

KW - SPH

UR - https://www.scopus.com/pages/publications/84860228038

M3 - Conference contribution

AN - SCOPUS:84860228038

SN - 9788489925670

T3 - Particle-Based Methods II - Fundamentals and Applications

SP - 139

EP - 151

BT - Particle-Based Methods II - Fundamentals and Applications

T2 - 2nd International Conference on Particle-Based Methods, PARTICLES 2011

Y2 - 26 October 2011 through 28 October 2011

ER -

A fully coupled 3d transport model in SPH for multi-species reaction-diffusion systems

Abstract

Publication series

Conference

Keywords

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