2024.1
Physics and theory for nanoFluidX.
Learn more about the physics features in nanoFluidX.
View new features for nanoFluidX 2024.1.
Discover nanoFluidX functionality with interactive tutorials.
Create a nanoFluidX model using SimLab.
nanoFluidX commands and parameters with examples.
The body force, defined through acceleration in units of [m/s2], can be varied over time using an input file.
Enable the contact angle parameter to allow different wetting behaviors.
Energy equation in nanoFluidX is implemented so that it accommodates for conduction and convection heat transfer with initial or Dirichlet boundary conditions.
nanoFluidX implementation of the multiphase surface tension model heavily relies on the work of Adami et al.
Both single phase surface tension and adhesion modeling is based on the work of Akinci et al.
nanoFluidX now supports both temperature-viscosity and non-Newtonian modeling behavior. For temperature-viscosity, three models were implemented: polynomial, Sutherland, and power law. For non-Newtonian, the Cross model is available, which can be used to approximate power law behavior without risking instabilities due to viscosity unboundness of the power model.
Learn more about the boundary conditions in nanoFluidX.
Learn more about the measurements features in nanoFluidX.
Learn more about advanced solver features in nanoFluidX.
This glossary contains generic messages generated by nanoFluidX, their likely causes, and possible methods to resolve the related issues.
This section provides quick responses to typical and frequently asked questions regarding nanoFluidX.
References used throughout the nanoFluidX manual.
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