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Electric Scalar-Scalar Potential Coupling (): Assures continuity of the electric potential across boundaries between The Electrostatics Interface and The Electrostatics, Boundary Elements Interface.
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Magnetic Scalar-Scalar Potential Coupling (): Assures continuity of the magnetic scalar potential across boundaries between The Magnetic Fields, Currents Only Interface and The Magnetic Fields, No Currents, Boundary Elements Interface.
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Magnetic Vector-Scalar Potential Coupling (): Assures continuity of the magnetic flux density across boundaries between The Magnetic Fields Interface and The Magnetic Fields, No Currents, Boundary Elements Interface.
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Electric Currents Solid to Shell Via Boundary (): Assures continuity of the electric potential across boundaries between The Electric Currents Interface and The Electric Currents in Shells Interface or The Electric Currents in Layered Shells Interface.
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Lorentz Coupling (): A multiphysics coupling feature between the Magnetic Fields interface and the Solid Mechanics interface. It passes the Lorentz force from the Magnetic Fields interface to the Solid Mechanics interface and, passes the induced electric field from the Solid Mechanics interface to the Magnetic Fields interface. The Lorentz force effect on a moving structure is similar to that of the Rayleigh alpha-damping, where the damping coefficient is proportional to the background magnetic field and the material electric conductivity.
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Electromagnetic Heating, Layered Shell (): Use it to account for electromagnetic surface losses as a heat source in the heat equation in layered materials represented by boundaries.
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Thermoelectric Effect, Layered Shell (): Use it to account for a Peltier heat source or sink in layered materials represented by boundaries where electrical and thermal models are defined.
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