Multiphysics Couplings
The Charged Particle Tracing and Particle Tracing for Fluid Flow interfaces can be used to create unidirectional, or one-way, couplings between particles and fields. For example, when using the Charged Particle Tracing interface, it is possible to compute the electric potential using a Stationary study and then use the computed potential to exert an electric force on the particles.
It is also possible to create bidirectional couplings, in which the particles contribute to fields in the surrounding domains, which may then exert forces on the particles. A typical example is a diverging beam of charged particles.
Dedicated Multiphysics nodes are available for several of the most common examples of bidirectional coupling between particles and fields. The following Multiphysics nodes are available depending on the other physics interfaces that are present:
In addition, it is possible to add all of the physics interfaces necessary for a specific Multiphysics node by using the dedicated Multiphysics interfaces:
For example, to model a nonrelativistic beam of electrons that diverges due to self-potential, add the Particle Field Interaction, Non-Relativistic interface. This automatically adds instances of the Charged Particle Tracing and Electrostatics physics interfaces and the Electric Particle Field Interaction Multiphysics node.
Child’s Law Benchmark: Application Library path Particle_Tracing_Module/Charged_Particle_Tracing/childs_law_benchmark
Electron Beam Divergence Due to Self Potential: Application Library path Particle_Tracing_Module/Charged_Particle_Tracing/electron_beam_divergence
Thermionic Emission in a Planar Diode: Application Library path Particle_Tracing_Module/Charged_Particle_Tracing/planar_diode
The Particle Field Interaction, Relativistic interface is used in the example Relativistic Diverging Electron Beam: Application Library path Particle_Tracing_Module/Charged_Particle_Tracing/electron_beam_divergence_relativistic.