A diffuse interface mixture formulation coupled to immersed boundary method enables simulation of oxygen transport and metabolism with deforming RBCs in straight and networked capillaries, indicating autonomous RBC regulation that produces homogeneous tissue oxygenation.
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2 Pith papers cite this work. Polarity classification is still indexing.
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physics.flu-dyn 2verdicts
UNVERDICTED 2representative citing papers
High-resolution two-phase simulations and perturbative analysis show wave decay adds first- and second-order corrections to Stokes drift plus net vertical transport from inertia-viscosity balance.
citing papers explorer
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Diffuse interface approach to oxygen transport and metabolism under blood flow dynamics in microcirculations
A diffuse interface mixture formulation coupled to immersed boundary method enables simulation of oxygen transport and metabolism with deforming RBCs in straight and networked capillaries, indicating autonomous RBC regulation that produces homogeneous tissue oxygenation.
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Beyond Stokes drift -- Lagrangian transport in evolving gravity waves
High-resolution two-phase simulations and perturbative analysis show wave decay adds first- and second-order corrections to Stokes drift plus net vertical transport from inertia-viscosity balance.