学术文献库

Many vesicles have a spherical resting shape and exposure to fluid flows induces an exchange between sub-optical area and visible (systematic) deformation, while the total area is conserved. The dynamics which controls the exchange between sub-optical and visible area depends on membrane properties such as bending rigidity and initial tension. Conversely, observation of these dynamics can be used to determine the membrane properties. The goal of this work is to create a general numerical model which accounts for the exchange between sub-optical and visible area. Unlike prior modeling efforts, the model does not pre-assume a shape type, such as nearly-spherical, or applied flow field, allowing the model to capture a wider variety of flow conditions. Based on implicit interface tracking and using a volume-preserving multiphase Navier-Stokes solver, the model is compared to several experimental results, showing excellent agreement. It is used to explore regimes not possible with previously published models, such as the variable viscosity case, and how these system properties influence experimentally measurable parameters such as deformation parameter. By creating a more generalized framework for the modeling of vesicles with sub-optical area, it will now be possible to make predictions on vesicle material properties from a wider variety of experimental results.