Pages that link to "Item:Q2955703"

The following pages link to Probing red blood cell mechanics, rheology and dynamics with a two-component multi-scale model (Q2955703):

Displaying 15 items.

• MD study of solution concentrations on ion distribution in a nanopore-based device inspired from red blood cells (Q519621) (← links)
• Using 3D fluid-structure interaction model to analyse the biomechanical properties of erythrocyte (Q552870) (← links)
• Getting in shape and swimming: the role of cortical forces and membrane heterogeneity in eukaryotic cells (Q667693) (← links)
• A new two-component approach in modeling red blood cells (Q827584) (← links)
• Many-body dissipative particle dynamics with energy conservation: temperature-dependent long-term attractive interaction (Q2164449) (← links)
• Atomistic-continuum model for probing the biomechanical properties of human erythrocyte membrane under extreme conditions (Q2310004) (← links)
• A 3D isogeometric BE-FE analysis with dynamic remeshing for the simulation of a deformable particle in shear flows (Q2310051) (← links)
• Multiscale modelling of erythrocytes in Stokes flow (Q2893702) (← links)
• (Q3347519) (← links)
• A LATTICE BOLTZMANN STUDY ON THE LARGE DEFORMATION OF RED BLOOD CELLS IN SHEAR FLOW (Q3499088) (← links)
• Dissipative Particle Dynamics: Foundation, Evolution, Implementation, and Applications (Q4609709) (← links)
• An Improved Coarse-Grained Model to Accurately Predict Red Blood Cell Morphology and Deformability (Q5141313) (← links)
• Analytical and Computational Studies of Correlations of Hydrodynamic Fluctuations in Shear Flow (Q5158979) (← links)
• Coarse-grained methods for heterogeneous vesicles with phase-separated domains: elastic mechanics of shape fluctuations, plate compression, and channel insertion (Q6104705) (← links)
• Assessment of coupled bilayer–cytoskeleton modelling strategy for red blood cell dynamics in flow (Q6146271) (← links)