electrodynamics In physics, electromagnetism is an interaction that occurs between particles with electric charge. It is the second-strongest of the four fundamental interactions, after the strong force, and it is the dominant force in the interactions o ...

, the retarded potentials are the

electromagnetic potential An electromagnetic four-potential is a relativistic vector function from which the electromagnetic field can be derived. It combines both an electric scalar potential and a magnetic vector potential into a single four-vector.Gravitation, J.A. ...

s for the electromagnetic field generated by time-varying electric current or

charge distribution In electromagnetism, charge density is the amount of electric charge per unit length, surface area, or volume. Volume charge density (symbolized by the Greek letter ρ) is the quantity of charge per unit volume, measured in the SI system in co ...

s in the past. The fields propagate at the

speed of light The speed of light in vacuum, commonly denoted , is a universal physical constant that is important in many areas of physics. The speed of light is exactly equal to ). According to the special theory of relativity, is the upper limit ...

''c'', so the delay of the fields connecting cause and effect at earlier and later times is an important factor: the signal takes a finite time to propagate from a point in the charge or current distribution (the point of cause) to another point in space (where the effect is measured), see figure below.

In the Lorenz gauge

The starting point is Maxwell's equations in the potential formulation using the Lorenz gauge: :

\Box \varphi = \dfrac \,,\quad \Box \mathbf = \mu_0\mathbf

where φ(r, ''t'') is the

electric potential The electric potential (also called the ''electric field potential'', potential drop, the electrostatic potential) is defined as the amount of work energy needed to move a unit of electric charge from a reference point to the specific point in ...

and A(r, ''t'') is the magnetic vector potential, for an arbitrary source of

charge density In electromagnetism, charge density is the amount of electric charge per unit length, surface area, or volume. Volume charge density (symbolized by the Greek letter ρ) is the quantity of charge per unit volume, measured in the SI system in ...

ρ(r, ''t'') and current density J(r, ''t''), and

\Box

is the

D'Alembert operator In special relativity, electromagnetism and wave theory, the d'Alembert operator (denoted by a box: \Box), also called the d'Alembertian, wave operator, box operator or sometimes quabla operator (''cf''. nabla symbol) is the Laplace operator of Mi ...

. Solving these gives the retarded potentials below (all in SI units).

For time-dependent fields

For time-dependent fields, the retarded potentials are: :

\mathrm\varphi (\mathbf r , t) = \frac\int \frac\, \mathrm^3\mathbf r'

\mathbf A (\mathbf r , t) = \frac\int \frac\, \mathrm^3\mathbf r'\,.

where r is a point in space, ''t'' is time, :

t_r = t-\frac

is the retarded time, and d³r' is the integration measure using r'. From φ(r, t) and A(r, ''t''), the fields E(r, ''t'') and B(r, ''t'') can be calculated using the definitions of the potentials: :

-\mathbf = \nabla\varphi +\frac\,,\quad \mathbf=\nabla\times\mathbf A\,.

and this leads to

Jefimenko's equations In electromagnetism, Jefimenko's equations (named after Oleg D. Jefimenko) give the electric field and magnetic field due to a distribution of electric charges and electric current in space, that takes into account the propagation delay ( reta ...

. The corresponding advanced potentials have an identical form, except the advanced time :

t_a = t+\frac

replaces the retarded time.

In comparison with static potentials for time-independent fields

In the case the fields are time-independent (

electrostatic Electrostatics is a branch of physics that studies electric charges at rest ( static electricity). Since classical times, it has been known that some materials, such as amber, attract lightweight particles after rubbing. The Greek word for amb ...

and

magnetostatic Magnetostatics is the study of magnetic fields in systems where the currents are steady (not changing with time). It is the magnetic analogue of electrostatics, where the charges are stationary. The magnetization need not be static; the equati ...

fields), the time derivatives in the

\Box

operators of the fields are zero, and Maxwell's equations reduce to :

\nabla^2 \varphi =-\dfrac\,,\quad \nabla^2 \mathbf =- \mu_0 \mathbf\,,

where ∇² is the Laplacian, which take the form of

Poisson's equation Poisson's equation is an elliptic partial differential equation of broad utility in theoretical physics. For example, the solution to Poisson's equation is the potential field caused by a given electric charge or mass density distribution; with t ...

in four components (one for φ and three for A), and the solutions are: :

\mathrm\varphi (\mathbf) = \frac\int \frac\, \mathrm^3\mathbf r'

\mathbf A (\mathbf) = \frac\int \frac\, \mathrm^3\mathbf r'\,.

These also follow directly from the retarded potentials.

In the Coulomb gauge

In the

Coulomb gauge In the physics of gauge theories, gauge fixing (also called choosing a gauge) denotes a mathematical procedure for coping with redundant degrees of freedom in field variables. By definition, a gauge theory represents each physically distinct co ...

, Maxwell's equations are :

\nabla^2 \varphi =-\dfrac

\nabla^2 \mathbf - \dfrac\dfrac=- \mu_0 \mathbf +\dfrac\nabla\left(\dfrac\right)\,,

although the solutions contrast the above, since A is a retarded potential yet φ changes ''instantly'', given by: :

\varphi(\mathbf, t) = \dfrac\int \dfrac\mathrm^3\mathbf'

\mathbf(\mathbf,t) = \dfrac \nabla\times\int \mathrm^3\mathbf \int_0^ \mathrmt_r \dfrac\times (\mathbf-\mathbf') \,.

This presents an advantage and a disadvantage of the Coulomb gauge - φ is easily calculable from the charge distribution ρ but A is not so easily calculable from the current distribution j. However, provided we require that the potentials vanish at infinity, they can be expressed neatly in terms of fields: :

\varphi(\mathbf, t) = \dfrac\int \dfrac\mathrm^3\mathbf'

\mathbf(\mathbf,t) = \dfrac\int \dfrac\mathrm^3\mathbf'

In linearized gravity

The retarded potential in linearized general relativity is closely analogous to the electromagnetic case. The trace-reversed tensor

\tilde h_ = h_ - \frac 1 2 \eta_ h

plays the role of the four-vector potential, the harmonic gauge

\tilde h^_ = 0

replaces the electromagnetic Lorenz gauge, the field equations are

\Box \tilde h_ = -16\pi G T_

, and the retarded-wave solution is

\tilde h_(\mathbf r, t) = 4 G \int \frac \mathrm d^3 \mathbf r'.

Using SI units, the expression must be divided by

c^4

, as can be confirmed by dimensional analysis.

Occurrence and application

A many-body theory which includes an average of retarded and ''advanced''

Liénard–Wiechert potential The Liénard–Wiechert potentials describe the classical electromagnetic effect of a moving electric point charge in terms of a vector potential and a scalar potential in the Lorenz gauge. Stemming directly from Maxwell's equations, these descr ...

s is the

Wheeler–Feynman absorber theory The Wheeler–Feynman absorber theory (also called the Wheeler–Feynman time-symmetric theory), named after its originators, the physicists Richard Feynman and John Archibald Wheeler, is an interpretation of electrodynamics derived from the assu ...

also known as the Wheeler–Feynman time-symmetric theory.

Example

The potential of charge with uniform speed on a straight line has

inversion in a point In geometry, a point reflection (point inversion, central inversion, or inversion through a point) is a type of isometry of Euclidean space. An object that is invariant under a point reflection is said to possess point symmetry; if it is invari ...

that is in the recent position. The potential is not changed in the direction of movement.Feynman, Lecture 26, Lorentz Transformations of the Fields
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References

{{Reflist Potentials