Verfügbarkeit: Simulation of Flow in Porous Media :

Simulation of Flow in Porous Media :: Applications in Energy and Environment.

Thisbook is the firstvolume of three volume series recording the""Radon Special Semester 2011 on Multiscale Simulation & Analysis in Energy and the Environment"" taking placein Linz, Austria, October 3-7, 2011. Thevolume discusses new developments in computational methods for...

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Bibliographische Detailangaben
1. Verfasser:	Kraus, Johannes
Weitere Verfasser:	Bastian, Peter (Mathematician), Scheichl, Robert, 1972-, Wheeler, Mary F. (Mary Fanett)
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Berlin : De Gruyter, 2013.
Schriftenreihe:	Radon series on computational and applied mathematics.
Schlagworte:	Porous materials > Permeability > Mathematical models. Transport theory > Mathematical models. Fluid dynamics. Théorie du transport > Modèles mathématiques. Dynamique des fluides. TECHNOLOGY & ENGINEERING > Engineering (General) TECHNOLOGY & ENGINEERING > Reference. Fluid dynamics Porous materials > Permeability > Mathematical models Transport theory > Mathematical models Finite Element Method. Mortar Method. Multiscale Techniques. Partial Differential Equations. Phase Appearance/Disappearance. Porous Media. Stokes-Darcy Coupling. Electronic book.
Online-Zugang:	Volltext
Zusammenfassung:	Thisbook is the firstvolume of three volume series recording the""Radon Special Semester 2011 on Multiscale Simulation & Analysis in Energy and the Environment"" taking placein Linz, Austria, October 3-7, 2011. Thevolume discusses new developments in computational methods for the simulation of flows in porous media with applications in waste storage, CO2 sequestration and fuel cells. It records the achievements of Workshop 1 ""Simulation of Flow in Porous Media and Applications in Waste Management and CO2 Sequestration"". Itbrings together key numerical mathematiciansfrom the fields ofanalysis a.
Beschreibung:	3.3 Darcy flow.
Beschreibung:	1 online resource (224 pages)
Bibliographie:	Includes bibliographical references and index.
ISBN:	9783110282245 3110282240 9781523100484 1523100486
Zugangseinschränkungen:	Access restricted to Ryerson students, faculty and staff.

Internformat

MARC


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245	1	0	\|a Simulation of Flow in Porous Media : \|b Applications in Energy and Environment.
260			\|a Berlin : \|b De Gruyter, \|c 2013.
300			\|a 1 online resource (224 pages)
336			\|a text \|b txt \|2 rdacontent
337			\|a computer \|b c \|2 rdamedia
338			\|a online resource \|b cr \|2 rdacarrier
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505	0		\|a Preface; Upscaled models for CO2 injection and migration in geological systems; 1 Introduction; 2 Background; 3 Model description; 3.1 Key assumptions and dimensionless groupings; 3.2 Vertical fluid and pressure distribution; 3.3 Model derivation; 3.4 Upscaling and subscale processes; 4 Model application; 5 Summary; Multipoint flux approximation L-method in 3D: numerical convergence and application to two-phase flow through porous media; 1 Introduction; 2 The MPFA L-method in 3D; 2.1 Details of the scheme; 2.2 Criterion for choosing the proper L-stencil; 2.3 Boundary handling.
505	8		\|a 3 Numerical convergence3.1 Benchmark test 1; 3.2 Benchmark test 3; 4 Grid adaptivity; 4.1 Boundary handling; 5 Two-phase flow applications; 5.1 Two-phase model description; 5.2 Buckley-Leverett-type problem; 5.3 McWhorter-type problem; 5.4 DNAPL infiltration problem; 5.5 Refinement and coarsening indicator; 6 Summary and conclusions; Compositional two-phase flow in saturated-unsaturated porous media: benchmarks for phase appearance/disappearance; 1 Introduction; 2 Definition and basic assumptions; 3 Equations; 3.1 Mass conservation of each component; 4 Choice of the primary variables.
505	8		\|a 5 Presentation of the two test cases5.1 First test case: gas phase appearing/disappearing by gas injection in a water-saturated rock core sample; 5.2 Second test case: evolution from an initial out of equilibriumstate to a stabilized stationary one, in a sealed porous core sample; 6 Conclusions and perspectives; Coupling free and porous-media flows: models and numerical approximation; 1 Introduction; 2 Setting of the problem; 2.1 The surface-groundwater flow problem; 2.2 Interface conditions to couple surface and groundwater flows; 3 Weak formulation and analysis.
505	8		\|a 3.1 Mixed formulation of Darcy's equation3.2 Time-dependent Stokes/Darcy model; 4 Multidomain formulation of the coupled problem; 4.1 The Stokes/Darcy problem; 4.2 The Navier-Stokes/Darcy problem; 4.3 Well-posedness of the interface problems; 5 Finite element approximation of free and porous-media flows; 5.1 Galerkin finite-element approximation of the Stokes/Darcy problem; 6 Algebraic formulation of the linear interface problem and solution techniques; 6.1 Numerical results; 6.2 Other preconditioning methods; 7 Iterative methods for the Navier-Stokes/Darcy problem.
505	8		\|a 8 Subdomain iterative methods for the time-dependent (Navier- )Stokes/Darcy problemMathematical and numerical modeling of flow, transport, and reactions in porous structures of electrochemical devices; 1 Introduction; 1.1 Model scales; 1.2 The direct methanol fuel cell -- an example of an electrochemical device with a porous electrode; 2 Electrolytes and interfaces; 2.1 Dilute electrolytes; 2.2 Bulk electroneutrality; 2.3 Double layer; 2.4 Interface between electrode and electrolyte; 2.5 Faradaic reactions; 3 Porous electrodes; 3.1 Ideally polarizable porous matrix; 3.2 Species transport.
500			\|a 3.3 Darcy flow.
520			\|a Thisbook is the firstvolume of three volume series recording the""Radon Special Semester 2011 on Multiscale Simulation & Analysis in Energy and the Environment"" taking placein Linz, Austria, October 3-7, 2011. Thevolume discusses new developments in computational methods for the simulation of flows in porous media with applications in waste storage, CO2 sequestration and fuel cells. It records the achievements of Workshop 1 ""Simulation of Flow in Porous Media and Applications in Waste Management and CO2 Sequestration"". Itbrings together key numerical mathematiciansfrom the fields ofanalysis a.
588	0		\|a Print version record.
504			\|a Includes bibliographical references and index.
506			\|a Access restricted to Ryerson students, faculty and staff. \|5 CaOTR
650		0	\|a Porous materials \|x Permeability \|x Mathematical models.
650		0	\|a Transport theory \|x Mathematical models.
650		0	\|a Fluid dynamics. \|0 http://id.loc.gov/authorities/subjects/sh85049376
650		6	\|a Théorie du transport \|x Modèles mathématiques.
650		6	\|a Dynamique des fluides.
650		7	\|a TECHNOLOGY & ENGINEERING \|x Engineering (General) \|2 bisacsh
650		7	\|a TECHNOLOGY & ENGINEERING \|x Reference. \|2 bisacsh
650		7	\|a Fluid dynamics \|2 fast
650		7	\|a Porous materials \|x Permeability \|x Mathematical models \|2 fast
650		7	\|a Transport theory \|x Mathematical models \|2 fast
653			\|a Finite Element Method.
653			\|a Mortar Method.
653			\|a Multiscale Techniques.
653			\|a Partial Differential Equations.
653			\|a Phase Appearance/Disappearance.
653			\|a Porous Media.
653			\|a Stokes-Darcy Coupling.
655		4	\|a Electronic book.
700	1		\|a Bastian, Peter \|c (Mathematician) \|0 http://id.loc.gov/authorities/names/n2013022295
700	1		\|a Scheichl, Robert, \|d 1972- \|0 http://id.loc.gov/authorities/names/n2013022298
700	1		\|a Wheeler, Mary F. \|q (Mary Fanett) \|0 http://id.loc.gov/authorities/names/n87892319
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776	0	8	\|i Print version: \|a Kraus, Johannes. \|t Simulation of Flow in Porous Media : Applications in Energy and Environment. \|d Berlin : De Gruyter, ©2013 \|z 9783110282214
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Datensatz im Suchindex

DE-BY-FWS_katkey	ZDB-4-EBA-ocn858761757
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author	Kraus, Johannes
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contents	Preface; Upscaled models for CO2 injection and migration in geological systems; 1 Introduction; 2 Background; 3 Model description; 3.1 Key assumptions and dimensionless groupings; 3.2 Vertical fluid and pressure distribution; 3.3 Model derivation; 3.4 Upscaling and subscale processes; 4 Model application; 5 Summary; Multipoint flux approximation L-method in 3D: numerical convergence and application to two-phase flow through porous media; 1 Introduction; 2 The MPFA L-method in 3D; 2.1 Details of the scheme; 2.2 Criterion for choosing the proper L-stencil; 2.3 Boundary handling. 3 Numerical convergence3.1 Benchmark test 1; 3.2 Benchmark test 3; 4 Grid adaptivity; 4.1 Boundary handling; 5 Two-phase flow applications; 5.1 Two-phase model description; 5.2 Buckley-Leverett-type problem; 5.3 McWhorter-type problem; 5.4 DNAPL infiltration problem; 5.5 Refinement and coarsening indicator; 6 Summary and conclusions; Compositional two-phase flow in saturated-unsaturated porous media: benchmarks for phase appearance/disappearance; 1 Introduction; 2 Definition and basic assumptions; 3 Equations; 3.1 Mass conservation of each component; 4 Choice of the primary variables. 5 Presentation of the two test cases5.1 First test case: gas phase appearing/disappearing by gas injection in a water-saturated rock core sample; 5.2 Second test case: evolution from an initial out of equilibriumstate to a stabilized stationary one, in a sealed porous core sample; 6 Conclusions and perspectives; Coupling free and porous-media flows: models and numerical approximation; 1 Introduction; 2 Setting of the problem; 2.1 The surface-groundwater flow problem; 2.2 Interface conditions to couple surface and groundwater flows; 3 Weak formulation and analysis. 3.1 Mixed formulation of Darcy's equation3.2 Time-dependent Stokes/Darcy model; 4 Multidomain formulation of the coupled problem; 4.1 The Stokes/Darcy problem; 4.2 The Navier-Stokes/Darcy problem; 4.3 Well-posedness of the interface problems; 5 Finite element approximation of free and porous-media flows; 5.1 Galerkin finite-element approximation of the Stokes/Darcy problem; 6 Algebraic formulation of the linear interface problem and solution techniques; 6.1 Numerical results; 6.2 Other preconditioning methods; 7 Iterative methods for the Navier-Stokes/Darcy problem. 8 Subdomain iterative methods for the time-dependent (Navier- )Stokes/Darcy problemMathematical and numerical modeling of flow, transport, and reactions in porous structures of electrochemical devices; 1 Introduction; 1.1 Model scales; 1.2 The direct methanol fuel cell -- an example of an electrochemical device with a porous electrode; 2 Electrolytes and interfaces; 2.1 Dilute electrolytes; 2.2 Bulk electroneutrality; 2.3 Double layer; 2.4 Interface between electrode and electrolyte; 2.5 Faradaic reactions; 3 Porous electrodes; 3.1 Ideally polarizable porous matrix; 3.2 Species transport.
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genre	Electronic book.
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indexdate	2024-11-27T13:25:32Z
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series	Radon series on computational and applied mathematics.
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spelling	Kraus, Johannes. Simulation of Flow in Porous Media : Applications in Energy and Environment. Berlin : De Gruyter, 2013. 1 online resource (224 pages) text txt rdacontent computer c rdamedia online resource cr rdacarrier Radon Series on Computational and Applied Mathematics Preface; Upscaled models for CO2 injection and migration in geological systems; 1 Introduction; 2 Background; 3 Model description; 3.1 Key assumptions and dimensionless groupings; 3.2 Vertical fluid and pressure distribution; 3.3 Model derivation; 3.4 Upscaling and subscale processes; 4 Model application; 5 Summary; Multipoint flux approximation L-method in 3D: numerical convergence and application to two-phase flow through porous media; 1 Introduction; 2 The MPFA L-method in 3D; 2.1 Details of the scheme; 2.2 Criterion for choosing the proper L-stencil; 2.3 Boundary handling. 3 Numerical convergence3.1 Benchmark test 1; 3.2 Benchmark test 3; 4 Grid adaptivity; 4.1 Boundary handling; 5 Two-phase flow applications; 5.1 Two-phase model description; 5.2 Buckley-Leverett-type problem; 5.3 McWhorter-type problem; 5.4 DNAPL infiltration problem; 5.5 Refinement and coarsening indicator; 6 Summary and conclusions; Compositional two-phase flow in saturated-unsaturated porous media: benchmarks for phase appearance/disappearance; 1 Introduction; 2 Definition and basic assumptions; 3 Equations; 3.1 Mass conservation of each component; 4 Choice of the primary variables. 5 Presentation of the two test cases5.1 First test case: gas phase appearing/disappearing by gas injection in a water-saturated rock core sample; 5.2 Second test case: evolution from an initial out of equilibriumstate to a stabilized stationary one, in a sealed porous core sample; 6 Conclusions and perspectives; Coupling free and porous-media flows: models and numerical approximation; 1 Introduction; 2 Setting of the problem; 2.1 The surface-groundwater flow problem; 2.2 Interface conditions to couple surface and groundwater flows; 3 Weak formulation and analysis. 3.1 Mixed formulation of Darcy's equation3.2 Time-dependent Stokes/Darcy model; 4 Multidomain formulation of the coupled problem; 4.1 The Stokes/Darcy problem; 4.2 The Navier-Stokes/Darcy problem; 4.3 Well-posedness of the interface problems; 5 Finite element approximation of free and porous-media flows; 5.1 Galerkin finite-element approximation of the Stokes/Darcy problem; 6 Algebraic formulation of the linear interface problem and solution techniques; 6.1 Numerical results; 6.2 Other preconditioning methods; 7 Iterative methods for the Navier-Stokes/Darcy problem. 8 Subdomain iterative methods for the time-dependent (Navier- )Stokes/Darcy problemMathematical and numerical modeling of flow, transport, and reactions in porous structures of electrochemical devices; 1 Introduction; 1.1 Model scales; 1.2 The direct methanol fuel cell -- an example of an electrochemical device with a porous electrode; 2 Electrolytes and interfaces; 2.1 Dilute electrolytes; 2.2 Bulk electroneutrality; 2.3 Double layer; 2.4 Interface between electrode and electrolyte; 2.5 Faradaic reactions; 3 Porous electrodes; 3.1 Ideally polarizable porous matrix; 3.2 Species transport. 3.3 Darcy flow. Thisbook is the firstvolume of three volume series recording the""Radon Special Semester 2011 on Multiscale Simulation & Analysis in Energy and the Environment"" taking placein Linz, Austria, October 3-7, 2011. Thevolume discusses new developments in computational methods for the simulation of flows in porous media with applications in waste storage, CO2 sequestration and fuel cells. It records the achievements of Workshop 1 ""Simulation of Flow in Porous Media and Applications in Waste Management and CO2 Sequestration"". Itbrings together key numerical mathematiciansfrom the fields ofanalysis a. Print version record. Includes bibliographical references and index. Access restricted to Ryerson students, faculty and staff. CaOTR Porous materials Permeability Mathematical models. Transport theory Mathematical models. Fluid dynamics. http://id.loc.gov/authorities/subjects/sh85049376 Théorie du transport Modèles mathématiques. Dynamique des fluides. TECHNOLOGY & ENGINEERING Engineering (General) bisacsh TECHNOLOGY & ENGINEERING Reference. bisacsh Fluid dynamics fast Porous materials Permeability Mathematical models fast Transport theory Mathematical models fast Finite Element Method. Mortar Method. Multiscale Techniques. Partial Differential Equations. Phase Appearance/Disappearance. Porous Media. Stokes-Darcy Coupling. Electronic book. Bastian, Peter (Mathematician) http://id.loc.gov/authorities/names/n2013022295 Scheichl, Robert, 1972- http://id.loc.gov/authorities/names/n2013022298 Wheeler, Mary F. (Mary Fanett) http://id.loc.gov/authorities/names/n87892319 has work: Simulation of flow in porous media (Text) https://id.oclc.org/worldcat/entity/E39PCGXw7vt4GgpWcJTxBKtXFq https://id.oclc.org/worldcat/ontology/hasWork Print version: Kraus, Johannes. Simulation of Flow in Porous Media : Applications in Energy and Environment. Berlin : De Gruyter, ©2013 9783110282214 Radon series on computational and applied mathematics. http://id.loc.gov/authorities/names/no2008036485 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=641756 Volltext
spellingShingle	Kraus, Johannes Simulation of Flow in Porous Media : Applications in Energy and Environment. Radon series on computational and applied mathematics. Preface; Upscaled models for CO2 injection and migration in geological systems; 1 Introduction; 2 Background; 3 Model description; 3.1 Key assumptions and dimensionless groupings; 3.2 Vertical fluid and pressure distribution; 3.3 Model derivation; 3.4 Upscaling and subscale processes; 4 Model application; 5 Summary; Multipoint flux approximation L-method in 3D: numerical convergence and application to two-phase flow through porous media; 1 Introduction; 2 The MPFA L-method in 3D; 2.1 Details of the scheme; 2.2 Criterion for choosing the proper L-stencil; 2.3 Boundary handling. 3 Numerical convergence3.1 Benchmark test 1; 3.2 Benchmark test 3; 4 Grid adaptivity; 4.1 Boundary handling; 5 Two-phase flow applications; 5.1 Two-phase model description; 5.2 Buckley-Leverett-type problem; 5.3 McWhorter-type problem; 5.4 DNAPL infiltration problem; 5.5 Refinement and coarsening indicator; 6 Summary and conclusions; Compositional two-phase flow in saturated-unsaturated porous media: benchmarks for phase appearance/disappearance; 1 Introduction; 2 Definition and basic assumptions; 3 Equations; 3.1 Mass conservation of each component; 4 Choice of the primary variables. 5 Presentation of the two test cases5.1 First test case: gas phase appearing/disappearing by gas injection in a water-saturated rock core sample; 5.2 Second test case: evolution from an initial out of equilibriumstate to a stabilized stationary one, in a sealed porous core sample; 6 Conclusions and perspectives; Coupling free and porous-media flows: models and numerical approximation; 1 Introduction; 2 Setting of the problem; 2.1 The surface-groundwater flow problem; 2.2 Interface conditions to couple surface and groundwater flows; 3 Weak formulation and analysis. 3.1 Mixed formulation of Darcy's equation3.2 Time-dependent Stokes/Darcy model; 4 Multidomain formulation of the coupled problem; 4.1 The Stokes/Darcy problem; 4.2 The Navier-Stokes/Darcy problem; 4.3 Well-posedness of the interface problems; 5 Finite element approximation of free and porous-media flows; 5.1 Galerkin finite-element approximation of the Stokes/Darcy problem; 6 Algebraic formulation of the linear interface problem and solution techniques; 6.1 Numerical results; 6.2 Other preconditioning methods; 7 Iterative methods for the Navier-Stokes/Darcy problem. 8 Subdomain iterative methods for the time-dependent (Navier- )Stokes/Darcy problemMathematical and numerical modeling of flow, transport, and reactions in porous structures of electrochemical devices; 1 Introduction; 1.1 Model scales; 1.2 The direct methanol fuel cell -- an example of an electrochemical device with a porous electrode; 2 Electrolytes and interfaces; 2.1 Dilute electrolytes; 2.2 Bulk electroneutrality; 2.3 Double layer; 2.4 Interface between electrode and electrolyte; 2.5 Faradaic reactions; 3 Porous electrodes; 3.1 Ideally polarizable porous matrix; 3.2 Species transport. Porous materials Permeability Mathematical models. Transport theory Mathematical models. Fluid dynamics. http://id.loc.gov/authorities/subjects/sh85049376 Théorie du transport Modèles mathématiques. Dynamique des fluides. TECHNOLOGY & ENGINEERING Engineering (General) bisacsh TECHNOLOGY & ENGINEERING Reference. bisacsh Fluid dynamics fast Porous materials Permeability Mathematical models fast Transport theory Mathematical models fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85049376
title	Simulation of Flow in Porous Media : Applications in Energy and Environment.
title_auth	Simulation of Flow in Porous Media : Applications in Energy and Environment.
title_exact_search	Simulation of Flow in Porous Media : Applications in Energy and Environment.
title_full	Simulation of Flow in Porous Media : Applications in Energy and Environment.
title_fullStr	Simulation of Flow in Porous Media : Applications in Energy and Environment.
title_full_unstemmed	Simulation of Flow in Porous Media : Applications in Energy and Environment.
title_short	Simulation of Flow in Porous Media :
title_sort	simulation of flow in porous media applications in energy and environment
title_sub	Applications in Energy and Environment.
topic	Porous materials Permeability Mathematical models. Transport theory Mathematical models. Fluid dynamics. http://id.loc.gov/authorities/subjects/sh85049376 Théorie du transport Modèles mathématiques. Dynamique des fluides. TECHNOLOGY & ENGINEERING Engineering (General) bisacsh TECHNOLOGY & ENGINEERING Reference. bisacsh Fluid dynamics fast Porous materials Permeability Mathematical models fast Transport theory Mathematical models fast
topic_facet	Porous materials Permeability Mathematical models. Transport theory Mathematical models. Fluid dynamics. Théorie du transport Modèles mathématiques. Dynamique des fluides. TECHNOLOGY & ENGINEERING Engineering (General) TECHNOLOGY & ENGINEERING Reference. Fluid dynamics Porous materials Permeability Mathematical models Transport theory Mathematical models Electronic book.
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=641756
work_keys_str_mv	AT krausjohannes simulationofflowinporousmediaapplicationsinenergyandenvironment AT bastianpeter simulationofflowinporousmediaapplicationsinenergyandenvironment AT scheichlrobert simulationofflowinporousmediaapplicationsinenergyandenvironment AT wheelermaryf simulationofflowinporousmediaapplicationsinenergyandenvironment

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