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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An a posteriori framework implemented in PyMHD estimates numerical dissipation in Alfvénic, dynamo, and MRI-driven MHD turbulence, showing it has distinct spectral and anisotropic properties from physical dissipation.
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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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Characterization of Numerical Dissipation in Simulations of Magnetohydrodynamic Turbulence
An a posteriori framework implemented in PyMHD estimates numerical dissipation in Alfvénic, dynamo, and MRI-driven MHD turbulence, showing it has distinct spectral and anisotropic properties from physical dissipation.