Current density

In electromagnetism, current density is the amount of charge per unit time that flows through a unit area of a chosen cross section. The current density vector is defined as a vector whose magnitude is the electric current per cross-sectional area at a given point in space, its direction being that of the motion of the positive charges at this point. In SI base units, the electric current density is measured in amperes per square metre.

Definition
Assume that $A$ (SI unit: m2) is a small surface centred at a given point $M$ and orthogonal to the motion of the charges at $M$. If $IA$ (SI unit: A) is the electric current flowing through $A$, then electric current density $j$ at $M$ is given by the limit:

$$j = \lim_{A \to 0} \frac{I_A}{A} = \left.\frac{\partial I}{\partial A} \right|_{A=0},$$

with surface $A$ remaining centered at $M$ and orthogonal to the motion of the charges during the limit process.

The current density vector $j$ is the vector whose magnitude is the electric current density, and whose direction is the same as the motion of the positive charges at $M$.

At a given time $t$, if $J$ is the velocity of the charges at $M$, and $dA$ is an infinitesimal surface centred at $M$ and orthogonal to $j$, then during an amount of time $dt$, only the charge contained in the volume formed by $dA$ and $$v \,dt$$ will flow through $dA$. This charge is equal to $$d q = \rho \, v\, dt \, dA,$$ where $ρ$ is the charge density at $M$. The electric current is $$dI = dq/dt = \rho v dA$$, it follows that the current density vector is the vector normal $$dA$$ (i.e. parallel to $v$) and of magnitude $$dI/dA = \rho v$$

$$\mathbf{j} = \rho \mathbf{v}.$$

The surface integral of $v$ over a surface $S$, followed by an integral over the time duration $v$ to $j$, gives the total amount of charge flowing through the surface in that time ($t_{1}$):

$$q=\int_{t_1}^{t_2}\iint_S \mathbf{j}\cdot\mathbf{\hat{n}}\,dA \,dt. $$

More concisely, this is the integral of the flux of $t_{2}$ across $S$ between $t_{2} − t_{1}$ and $j$.

The area required to calculate the flux is real or imaginary, flat or curved, either as a cross-sectional area or a surface. For example, for charge carriers passing through an electrical conductor, the area is the cross-section of the conductor, at the section considered.

The vector area is a combination of the magnitude of the area through which the charge carriers pass, $A$, and a unit vector normal to the area, $$\mathbf{\hat{n}}.$$ The relation is $$\mathbf{A} = A \mathbf{\hat{n}}.$$

The differential vector area similarly follows from the definition given above: $$ d\mathbf{A} = dA \mathbf{\hat{n}}.$$

If the current density $t_{1}$ passes through the area at an angle $θ$ to the area normal $$\mathbf{\hat{n}},$$ then

$$\mathbf{j}\cdot\mathbf{\hat{n}}= j\cos\theta $$

where $t_{2}$ is the dot product of the unit vectors. That is, the component of current density passing through the surface (i.e. normal to it) is $j$, while the component of current density passing tangential to the area is $⋅$, but there is no current density actually passing through the area in the tangential direction. The only component of current density passing normal to the area is the cosine component.

Importance
Current density is important to the design of electrical and electronic systems.

Circuit performance depends strongly upon the designed current level, and the current density then is determined by the dimensions of the conducting elements. For example, as integrated circuits are reduced in size, despite the lower current demanded by smaller devices, there is a trend toward higher current densities to achieve higher device numbers in ever smaller chip areas. See Moore's law.

At high frequencies, the conducting region in a wire becomes confined near its surface which increases the current density in this region. This is known as the skin effect.

High current densities have undesirable consequences. Most electrical conductors have a finite, positive resistance, making them dissipate power in the form of heat. The current density must be kept sufficiently low to prevent the conductor from melting or burning up, the insulating material failing, or the desired electrical properties changing. At high current densities the material forming the interconnections actually moves, a phenomenon called electromigration. In superconductors excessive current density may generate a strong enough magnetic field to cause spontaneous loss of the superconductive property.

The analysis and observation of current density also is used to probe the physics underlying the nature of solids, including not only metals, but also semiconductors and insulators. An elaborate theoretical formalism has developed to explain many fundamental observations.

The current density is an important parameter in Ampère's circuital law (one of Maxwell's equations), which relates current density to magnetic field.

In special relativity theory, charge and current are combined into a 4-vector.

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 $j cos θ$ at time $t$, 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
 * $j sin θ$ is the current density vector;
 * $r$ 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
 * $j(r, t)$ is the number of particles per unit volume ("number density") (SI unit: m&minus;3);
 * $q$ is the charge of the individual particles with density $n$ (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 $v_{d}(r, t)$ is the electric field and $σ$ is the electrical conductivity.

Conductivity $σ$ is the reciprocal (inverse) of electrical resistivity and has the SI units of siemens per metre (S⋅m&minus;1), and $n(r, t)$ has the SI units of newtons per coulomb (N⋅C&minus;1) or, equivalently, volts per metre (V⋅m&minus;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 $σ$, and the non-local nature of response to the field by the spatial dependence of $σ$, 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 $E$ 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 $E$:

$$\mathbf{j}_\mathrm{P} = \frac{\partial \mathbf{P}}{\partial t} $$

Similarly with magnetic materials, circulations of the magnetic dipole moments per unit volume, i.e. the magnetization $σ(k, ω)$, 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 $P$:

$$\mathbf{j}_\mathrm{D} = \frac{\partial \mathbf{D}}{\partial t} $$

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
Since charge is conserved, current density must satisfy a continuity equation. Here is a derivation from first principles.

The net flow out of some volume $V$ (which can have an arbitrary shape but fixed for the calculation) must equal the net change in charge held inside the volume:

$$\int_S { \mathbf{j} \cdot d\mathbf{A}} = -\frac{d}{dt} \int_V{\rho \; dV} = - \int_V { \frac{\partial \rho}{\partial t}\;dV}$$

where $ρ$ is the charge density, and $M$ is a surface element of the surface $S$ enclosing the volume $V$. The surface integral on the left expresses the current outflow from the volume, and the negatively signed volume integral on the right expresses the decrease in the total charge inside the volume. From the divergence theorem:

$$\oint_S { \mathbf{j} \cdot d\mathbf{A}} = \int_V {\boldsymbol{\nabla} \cdot \mathbf{j} \; dV}$$

Hence:

$$\int_V {\boldsymbol{\nabla} \cdot \mathbf{j}\; dV} \ = - \int_V{ \frac{\partial \rho}{\partial t} \;dV}$$

This relation is valid for any volume, independent of size or location, which implies that:

$$\nabla \cdot \mathbf{j} = - \frac{\partial \rho}{\partial t}$$

and this relation is called the continuity equation.

In practice
In electrical wiring, the maximum current density (for a given temperature rating) can vary from 4 A⋅mm−2 for a wire with no air circulation around it, to over 6 A⋅mm−2 for a wire in free air. Regulations for building wiring list the maximum allowed current of each size of cable in differing conditions. For compact designs, such as windings of SMPS transformers, the value might be as low as 2 A⋅mm−2. If the wire is carrying high-frequency alternating currents, the skin effect may affect the distribution of the current across the section by concentrating the current on the surface of the conductor. In transformers designed for high frequencies, loss is reduced if Litz wire is used for the windings. This is made of multiple isolated wires in parallel with a diameter twice the skin depth. The isolated strands are twisted together to increase the total skin area and to reduce the resistance due to skin effects.

For the top and bottom layers of printed circuit boards, the maximum current density can be as high as 35 A⋅mm−2 with a copper thickness of 35 μm. Inner layers cannot dissipate as much heat as outer layers; designers of circuit boards avoid putting high-current traces on inner layers.

In the semiconductors field, the maximum current densities for different elements are given by the manufacturer. Exceeding those limits raises the following problems:
 * The Joule effect which increases the temperature of the component.
 * The electromigration effect which will erode the interconnection and eventually cause an open circuit.
 * The slow diffusion effect which, if exposed to high temperatures continuously, will move metallic ions and dopants away from where they should be. This effect is also synonymous with ageing.

The following table gives an idea of the maximum current density for various materials.

Even if manufacturers add some margin to their numbers, it is recommended to, at least, double the calculated section to improve the reliability, especially for high-quality electronics. One can also notice the importance of keeping electronic devices cool to avoid exposing them to electromigration and slow diffusion.

In biological organisms, ion channels regulate the flow of ions (for example, sodium, calcium, potassium) across the membrane in all cells. The membrane of a cell is assumed to act like a capacitor. Current densities are usually expressed in pA⋅pF−1 (picoamperes per picofarad) (i.e., current divided by capacitance). Techniques exist to empirically measure capacitance and surface area of cells, which enables calculation of current densities for different cells. This enables researchers to compare ionic currents in cells of different sizes.

In gas discharge lamps, such as flashlamps, current density plays an important role in the output spectrum produced. Low current densities produce spectral line emission and tend to favour longer wavelengths. High current densities produce continuum emission and tend to favour shorter wavelengths. Low current densities for flash lamps are generally around 10 A⋅mm−2. High current densities can be more than 40 A⋅mm−2.