The different physics interfaces involving only the scalar electric potential can be interpreted in terms of the charge relaxation process. The fundamental equations involved are Ohm’s law for the conduction current density

is called the charge relaxation time. For a good conductor like copper, τ is of the order of 10−19 s, whereas for a good insulator like silica glass, it is of the order of 103 s. For a pure insulator, it becomes infinite.

When modeling real-world devices, there is not only the intrinsic time scale of the charge relaxation time but also an external time scale t at which a device is energized or the observation time. It is the relation between the external time scale and the charge relaxation time that determines what physics interface and study type to use. The results are summarized in Table 2-1 below,

If the external time scale is short compared to the charge relaxation time, the charges do not have time to redistribute to any significant degree. Thus the charge distribution can be considered as a given model input. The best approach is to solve the Electrostatics formulation using the electric potential V.

By combining the definition of the potential with Gauss’ law, you can derive the classical Poisson’s equation. Under static conditions, the electric potential V is defined by the equivalence E = −∇V. Using this together with the constitutive relation D = ε0E + P between D and E, you can rewrite Gauss’ law as a variant of Poisson’s equation

where Je is an externally generated current density. The static form of the equation of continuity then reads

with the equation (∇⋅ D = ρ) yields the following equation for the frequency domain study type: