A finite element method for simulating soft active non-shearable rods immersed in generalized Newtonian fluids

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autorschaft

  • Roberto Federico Ausas
  • Cristian Guillermo Gebhardt
  • Gustavo Carlos Buscaglia

Organisationseinheiten

Externe Organisationen

  • Universidade de Sao Paulo
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Details

OriginalspracheEnglisch
Aufsatznummer106213
FachzeitschriftCommunications in Nonlinear Science and Numerical Simulation
Jahrgang108
Frühes Online-Datum27 Dez. 2021
PublikationsstatusVeröffentlicht - Mai 2022

Abstract

We propose a finite element method for simulating one-dimensional solid models with finite thickness and finite length that move and experience large deformations while immersed in generalized Newtonian fluids. The method is oriented towards applications involving microscopic devices or organisms in the soft-bio-matter realm. By considering that the strain energy of the solid may explicitly depend on time, we incorporate a mechanism for active response. The solids are modeled as Cosserat rods, a detailed formulation being provided for the planar non-shearable case. The discretization adopts one-dimensional Hermite elements for the rod and two-dimensional low-order Lagrange elements for the fluid's velocity and pressure. The fluid mesh is boundary-fitted, with remeshing at each time step. Several time marching schemes are studied, of which a semi-implicit scheme emerges as most effective. The method is demonstrated in very challenging examples: the roll-up of a rod to circular shape and later sudden release, the interaction of a soft rod with a fluid jet and the active self-locomotion of a sperm-like rod. The article includes a detailed description of a code that implements the method in the Firedrake library.

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A finite element method for simulating soft active non-shearable rods immersed in generalized Newtonian fluids. / Ausas, Roberto Federico; Gebhardt, Cristian Guillermo; Buscaglia, Gustavo Carlos.
in: Communications in Nonlinear Science and Numerical Simulation, Jahrgang 108, 106213, 05.2022.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Ausas RF, Gebhardt CG, Buscaglia GC. A finite element method for simulating soft active non-shearable rods immersed in generalized Newtonian fluids. Communications in Nonlinear Science and Numerical Simulation. 2022 Mai;108:106213. Epub 2021 Dez 27. doi: 10.1016/j.cnsns.2021.106213
Ausas, Roberto Federico ; Gebhardt, Cristian Guillermo ; Buscaglia, Gustavo Carlos. / A finite element method for simulating soft active non-shearable rods immersed in generalized Newtonian fluids. in: Communications in Nonlinear Science and Numerical Simulation. 2022 ; Jahrgang 108.
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abstract = "We propose a finite element method for simulating one-dimensional solid models with finite thickness and finite length that move and experience large deformations while immersed in generalized Newtonian fluids. The method is oriented towards applications involving microscopic devices or organisms in the soft-bio-matter realm. By considering that the strain energy of the solid may explicitly depend on time, we incorporate a mechanism for active response. The solids are modeled as Cosserat rods, a detailed formulation being provided for the planar non-shearable case. The discretization adopts one-dimensional Hermite elements for the rod and two-dimensional low-order Lagrange elements for the fluid's velocity and pressure. The fluid mesh is boundary-fitted, with remeshing at each time step. Several time marching schemes are studied, of which a semi-implicit scheme emerges as most effective. The method is demonstrated in very challenging examples: the roll-up of a rod to circular shape and later sudden release, the interaction of a soft rod with a fluid jet and the active self-locomotion of a sperm-like rod. The article includes a detailed description of a code that implements the method in the Firedrake library.",
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AU - Ausas, Roberto Federico

AU - Gebhardt, Cristian Guillermo

AU - Buscaglia, Gustavo Carlos

N1 - Funding Information: Roberto Federico Ausas and Gustavo Carlos Buscaglia gratefully acknowledge financial support from the São Paulo Research Foundation FAPESP and from the Conselho Nacional de Desenvolvimento Científico e Tecnológico (grants CEPID-CeMEAI 2013/07375-0 and INCT-MACC ). Funding Information: Roberto Federico Ausas and Gustavo Carlos Buscaglia gratefully acknowledge financial support from the S?o Paulo Research Foundation FAPESP and from the Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico (grants CEPID-CeMEAI 2013/07375-0 and INCT-MACC). The authors acknowledge as well the University of Bergen for the open access funding. Finally, the authors thank to D. Ham and K. Sagiyama from the Firedrake project and P. Farrell for giving some guidelines in the initial stages of the development.

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