Thermoporoelasticity via homogenization: Modeling and formal two-scale expansions

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • C. J. van Duijn
  • Andro Mikelić
  • Mary F. Wheeler
  • Thomas Wick

Organisationseinheiten

Externe Organisationen

  • Eindhoven University of Technology (TU/e)
  • Utrecht University
  • Universität Lyon
  • University of Texas at Austin
  • École polytechnique
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Details

OriginalspracheEnglisch
Seiten (von - bis)1-25
Seitenumfang25
FachzeitschriftInternational Journal of Engineering Science
Jahrgang138
Frühes Online-Datum2 März 2019
PublikationsstatusVeröffentlicht - Mai 2019

Abstract

In this paper we derive a macroscopic model for thermoporoelasticity from the pore scale linearized fluid-structure and energy equations. We consider the continuum mechanics thermodynamically compatible pore scale equations corresponding to realistic rock mechanics parameters. They are upscaled using two-scale asymptotic expansions. For the upscaled equations a Lyapunov functional (a generalization of Biot's free energy) is constructed and the well-posedness of the model is discussed. Possible applications to large time numerical simulations are pointed out.

ASJC Scopus Sachgebiete

Zitieren

Thermoporoelasticity via homogenization: Modeling and formal two-scale expansions. / van Duijn, C. J.; Mikelić, Andro; Wheeler, Mary F. et al.
in: International Journal of Engineering Science, Jahrgang 138, 05.2019, S. 1-25.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

van Duijn CJ, Mikelić A, Wheeler MF, Wick T. Thermoporoelasticity via homogenization: Modeling and formal two-scale expansions. International Journal of Engineering Science. 2019 Mai;138:1-25. Epub 2019 Mär 2. doi: 10.1016/j.ijengsci.2019.02.005
van Duijn, C. J. ; Mikelić, Andro ; Wheeler, Mary F. et al. / Thermoporoelasticity via homogenization: Modeling and formal two-scale expansions. in: International Journal of Engineering Science. 2019 ; Jahrgang 138. S. 1-25.
Download
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abstract = "In this paper we derive a macroscopic model for thermoporoelasticity from the pore scale linearized fluid-structure and energy equations. We consider the continuum mechanics thermodynamically compatible pore scale equations corresponding to realistic rock mechanics parameters. They are upscaled using two-scale asymptotic expansions. For the upscaled equations a Lyapunov functional (a generalization of Biot's free energy) is constructed and the well-posedness of the model is discussed. Possible applications to large time numerical simulations are pointed out.",
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note = "Funding Information: C.J.v.D. acknowledges support of the LABEX MILYON (ANR-10-LABX-0070) of Universit{\'e} de Lyon, within the program “Investissements d'Avenir” (ANR-11-IDEX-0007) operated by the French National Research Agency (ANR), as well as the support of the Center for Subsurface Modeling, Institute for Computational Engineering and Science (ICES), UT Austin. A.M. was partially supported by Darcy Center, The Netherlands and by The J. Tinsley Oden Faculty Fellowship Research Program at the Institute for Computational Engineering and Science (ICES), UT Austin. T.W. was partially supported by the Center for Subsurface Modeling and the Institute for Computational Engineering and Science (ICES) through the J. Tinsley Oden Faculty Fellowship Research Program.",
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T1 - Thermoporoelasticity via homogenization: Modeling and formal two-scale expansions

AU - van Duijn, C. J.

AU - Mikelić, Andro

AU - Wheeler, Mary F.

AU - Wick, Thomas

N1 - Funding Information: C.J.v.D. acknowledges support of the LABEX MILYON (ANR-10-LABX-0070) of Université de Lyon, within the program “Investissements d'Avenir” (ANR-11-IDEX-0007) operated by the French National Research Agency (ANR), as well as the support of the Center for Subsurface Modeling, Institute for Computational Engineering and Science (ICES), UT Austin. A.M. was partially supported by Darcy Center, The Netherlands and by The J. Tinsley Oden Faculty Fellowship Research Program at the Institute for Computational Engineering and Science (ICES), UT Austin. T.W. was partially supported by the Center for Subsurface Modeling and the Institute for Computational Engineering and Science (ICES) through the J. Tinsley Oden Faculty Fellowship Research Program.

PY - 2019/5

Y1 - 2019/5

N2 - In this paper we derive a macroscopic model for thermoporoelasticity from the pore scale linearized fluid-structure and energy equations. We consider the continuum mechanics thermodynamically compatible pore scale equations corresponding to realistic rock mechanics parameters. They are upscaled using two-scale asymptotic expansions. For the upscaled equations a Lyapunov functional (a generalization of Biot's free energy) is constructed and the well-posedness of the model is discussed. Possible applications to large time numerical simulations are pointed out.

AB - In this paper we derive a macroscopic model for thermoporoelasticity from the pore scale linearized fluid-structure and energy equations. We consider the continuum mechanics thermodynamically compatible pore scale equations corresponding to realistic rock mechanics parameters. They are upscaled using two-scale asymptotic expansions. For the upscaled equations a Lyapunov functional (a generalization of Biot's free energy) is constructed and the well-posedness of the model is discussed. Possible applications to large time numerical simulations are pointed out.

KW - Fluid-structure interaction

KW - Heat transfer

KW - Linear thermoelasticity

KW - Porous media

KW - Two-scale expansions

KW - Upscaling

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VL - 138

SP - 1

EP - 25

JO - International Journal of Engineering Science

JF - International Journal of Engineering Science

SN - 0020-7225

ER -

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