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Framework for multiscale flow simulation of deformable rocks

Publication ,  Chapter
Lesueur, M; Camila Casadiego, M; Poulet, T; Veveakis, M
January 1, 2017

A Finite Element implementation is presented to solve for Stokes flow on a deformable rock matrix reconstituted from a stack of computerized tomography images. Tightly coupling this flow solution with a mechanical deformation model exhibits the hydro-mechanical evolution of permeability in a fully saturated rock under compression. The scope of the presented micro-scale computation of permeability is demonstrated through a multi-scale simulation of pore pressure progression within a petroleum reservoir under production.

Duke Scholars

DOI

Publication Date

January 1, 2017

Volume

0

Start / End Page

475 / 480
 

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Lesueur, M., Camila Casadiego, M., Poulet, T., & Veveakis, M. (2017). Framework for multiscale flow simulation of deformable rocks (Vol. 0, pp. 475–480). https://doi.org/10.1007/978-3-319-56397-8_60
Lesueur, M., M. Camila Casadiego, T. Poulet, and M. Veveakis. “Framework for multiscale flow simulation of deformable rocks,” 0:475–80, 2017. https://doi.org/10.1007/978-3-319-56397-8_60.
Lesueur M, Camila Casadiego M, Poulet T, Veveakis M. Framework for multiscale flow simulation of deformable rocks. In 2017. p. 475–80.
Lesueur, M., et al. Framework for multiscale flow simulation of deformable rocks. Vol. 0, 2017, pp. 475–80. Scopus, doi:10.1007/978-3-319-56397-8_60.
Lesueur M, Camila Casadiego M, Poulet T, Veveakis M. Framework for multiscale flow simulation of deformable rocks. 2017. p. 475–480.

DOI

Publication Date

January 1, 2017

Volume

0

Start / End Page

475 / 480