Electrostatics and Magnetostatics Equations
Maxwell's equations describe electrodynamics as:
Here, E and H are the electric and magnetic field intensities, D and B are the electric and magnetic flux densities, and ρ and J are the electric charge and current densities.
Electrostatics
For electrostatic problems, Maxwell's equations simplify to this form:
where ε is the electrical permittivity of the material.
Because the electric field E is the gradient of the electric potential V, , the first equation yields this PDE:
For electrostatic problems, Dirichlet boundary conditions specify the electric potential V on the boundary.
Magnetostatics
For magnetostatic problems, Maxwell's equations simplify to this form:
Because , there exists a magnetic vector potential A, such that . For non-ferromagnetic materials, , where µ is the magnetic permeability of the material. Therefore,
Using the identity
and the Coulomb gauge , simplify the equation for A in terms of J to this PDE:
For magnetostatic problems, Dirichlet boundary conditions specify the magnetic potential A on the boundary.
Magnetostatics with Permanent Magnets
In the case of a permanent magnet, the constitutive relation between B and H includes the magnetization M:
Here, , where μr is the relative magnetic permeability of the material, and μ0 is the vacuum permeability.
Because , there exists a magnetic vector potential A, such that . Therefore,
The equation for A in terms of the current density J and magnetization M is