Free currents Charge carriers which are free to move constitute a
free current density, which are given by expressions such as those in this section. Electric current is a coarse, average quantity that tells what is happening in an entire wire. At position at time , the
distribution of
charge flowing is described by the current density: \mathbf{j}(\mathbf{r}, t) = \rho(\mathbf{r},t) \; \mathbf{v}_\text{d} (\mathbf{r},t) where • is the current density vector; • is the particles' average
drift velocity (SI unit:
m∙
s−1); • \rho(\mathbf{r}, t) = q \, n(\mathbf{r},t) is the
charge density (SI unit: coulombs per
cubic metre), in which • is the number of particles per unit volume ("number density") (SI unit: m−3); • is the charge of the individual particles with density (SI unit:
coulombs). A common approximation to the current density assumes the current simply is proportional to the electric field, as expressed by: \mathbf{j} = \sigma \mathbf{E} where is the
electric field and is the
electrical conductivity. This is also an alternative representation of
Ohm's law. Conductivity is the
reciprocal (
inverse) of electrical
resistivity and has the SI units of
siemens per metre (S⋅m−1), and has the SI units of
newtons per coulomb (N⋅C−1) or, equivalently,
volts per metre (V⋅m−1). A more fundamental approach to calculation of current density is based upon: \mathbf{j} (\mathbf{r}, t) = \int_{-\infty}^t \left[ \int_{V} \sigma(\mathbf{r}-\mathbf{r}', t-t') \; \mathbf{E}(\mathbf{r}', t') \; \text{d}^3 \mathbf{r}' \, \right] \text{d}t' indicating the lag in response by the time dependence of , and the non-local nature of response to the field by the spatial dependence of , both calculated in principle from an underlying microscopic analysis, for example, in the case of small enough fields, the
linear response function for the conductive behaviour in the material. See, for example, Giuliani & Vignale (2005) or Rammer (2007). The integral extends over the entire past history up to the present time. The above conductivity and its associated current density reflect the fundamental mechanisms underlying charge transport in the medium, both in time and over distance. A
Fourier transform in space and time then results in: \mathbf{j} (\mathbf{k}, \omega) = \sigma(\mathbf{k}, \omega) \; \mathbf{E}(\mathbf{k}, \omega) where is now a
complex function. In many materials, for example, in crystalline materials, the conductivity is a
tensor, and the current is not necessarily in the same direction as the applied field. Aside from the material properties themselves, the application of magnetic fields can alter conductive behaviour.
Polarization and magnetization currents Currents arise in materials when there is a non-uniform distribution of charge. In
dielectric materials, there is a current density corresponding to the net movement of
electric dipole moments per unit volume, i.e. the
polarization : \mathbf{j}_\mathrm{P} = \frac{\partial \mathbf{P}}{\partial t} Similarly with
magnetic materials, circulations of the
magnetic dipole moments per unit volume, i.e. the
magnetization , lead to
magnetization currents: \mathbf{j}_\mathrm{M} = \nabla\times\mathbf{M} Together, these terms add up to form the
bound current density in the material (resultant current due to movements of electric and magnetic dipole moments per unit volume): \mathbf{j}_\mathrm{b} = \mathbf{j}_\mathrm{P}+\mathbf{j}_\mathrm{M}
Total current in materials The total current is simply the sum of the free and bound currents: \mathbf{j} = \mathbf{j}_\mathrm{f} + \mathbf{j}_\mathrm{b}
Displacement current There is also a
displacement current corresponding to the time-varying
electric displacement field : \mathbf{j}_\mathrm{D} = \frac{\partial \mathbf{D}}{\partial t} which is an important term in
Ampere's circuital law, one of Maxwell's equations, since absence of this term would not predict
electromagnetic waves to propagate, or the time evolution of
electric fields in general. == Continuity equation ==