Deprecated: $wgMWOAuthSharedUserIDs=false is deprecated, set $wgMWOAuthSharedUserIDs=true, $wgMWOAuthSharedUserSource='local' instead [Called from MediaWiki\HookContainer\HookContainer::run in /var/www/html/w/includes/HookContainer/HookContainer.php at line 135] in /var/www/html/w/includes/Debug/MWDebug.php on line 372
Numerical simulation of the motion of red blood cells and vesicles in microfluidic flows - MaRDI portal

Numerical simulation of the motion of red blood cells and vesicles in microfluidic flows

From MaRDI portal

Publication:424946

Jump to:navigation, search

DOI10.1007/S00791-012-0172-1zbMath1402.92066OpenAlexW2018726476MaRDI QIDQ424946

Thomas Franke, Carina Willbold, Ronald H. W. Hoppe, Christopher Linsenmann, Achim Wixforth, Lothar Schmid

Publication date: 7 June 2012

Published in: Computing and Visualization in Science (Search for Journal in Brave)

Full work available at URL: https://doi.org/10.1007/s00791-012-0172-1

zbMATH Keywords

stability analysis red blood cells vesicles CFL-type condition finite element immersed boundary method microfluidic flows

Mathematics Subject Classification ID

Finite element methods applied to problems in fluid mechanics (76M10) Physiological flows (76Z05) Physiological flow (92C35) Cell movement (chemotaxis, etc.) (92C17)

Related Items (12)

Qualitative properties of nonlinear parabolic operators ⋮ Numerical simulation of surface acoustic wave actuated enantiomer separation by the finite element immersed boundary method ⋮ A stable numerical method for the dynamics of fluidic membranes ⋮ Optimal Control of Surface Acoustic Wave Actuated Sorting of Biological Cells ⋮ Numerical simulation of surface acoustic wave actuated cell sorting ⋮ Finite element approximation for the dynamics of asymmetric fluidic biomembranes ⋮ An adaptive Newton continuation strategy for the fully implicit finite element immersed boundary method ⋮ Numerical simulations of the motion and deformation of three RBCs during Poiseuille flow through a constricted vessel using IB-LBM ⋮ Transport at Interfaces in Lipid Membranes and Enantiomer Separation ⋮ A multiscale framework for large deformation modeling of RBC membranes ⋮ The Finite Element Immersed Boundary Method for the Numerical Simulation of the Motion of Red Blood Cells in Microfluidic Flows ⋮ Discrete models for fluid-structure interactions: the finite element immersed boundary method

Cites Work

This page was built for publication: Numerical simulation of the motion of red blood cells and vesicles in microfluidic flows

Retrieved from "https://portal.mardi4nfdi.de/w/index.php?title=Publication:424946&oldid=12299738"