**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. Built directly from Maxwell's equations, these potentials describe the complete, relativistically correct, time-varying electromagnetic field for a point charge in arbitrary motion, but are not corrected for quantum-mechanical effects. Electromagnetic radiation in the form of waves can be obtained from these potentials. These expressions were developed in part by Alfred-Marie Liénard in 1898 and independently by Emil Wiechert in 1900.^{[1]}

The Liénard–Wiechert potentials (scalar potential field) and (vector potential field) are for a source point charge at position traveling with velocity :

and

where:

is the velocity of the source expressed as a fraction of the speed of light

is the distance from the source

and is the unit vector pointing in the direction from the source.

(see also **retarded potential**.)

We can calculate the electric and magnetic fields directly from the potentials using the definitions:

- and

The calculation is nontrivial and requires a number of steps. The electric and magnetic fields are (in non-covariant form):

and

where , and (the Lorentz factor).

Note that the part of the first term updates the direction of the field toward the instantaneous position of the charge, if it continues to move with constant velocity . This term is connected with the "static" part of the electromagnetic field of the charge.

The second term, which is connected with electromagnetic radiation by the moving charge, requires charge acceleration and if this is zero, the value of this term is zero, and the charge does not radiate (emit electromagnetic radiation). This term requires additionally that a component of the charge acceleration be in a direction transverse to the line which connects the charge and the observer of the field . The direction of the field associated with this radiative term is toward the fully time-retarded position of the charge (i.e. where the charge was when it was accelerated).

In the case that there are no boundaries surrounding the sources, the retarded solutions for the scalar and vector potentials (SI units) of the nonhomogeneous wave equations with sources given by the charge and current densities and are in the Lorenz gauge (see Nonhomogeneous electromagnetic wave equation)

and

where is the retarded time.

For a moving point charge whose trajectory is given as a function of time by , the charge and current densities are as follows:

where is the three-dimensional Dirac delta function and is the velocity of the point charge.

Substituting into the expressions for the potential gives

These integrals are difficult to evaluate in their present form, so we will rewrite them by replacing with and integrating over the delta distribution :

We exchange the order of integration:

The delta function picks out which allows us to perform the inner integration with ease. Note that is a function of , so this integration also fixes .

The retarded time is a function of the field point and the source trajectory , and hence depends on . To evaluate this integral, therefore, we need the identity

where each is a zero of . Because there is only one retarded time for any given space-time coordinates and source trajectory , this reduces to:

where and are evaluated at the retarded time, and we have used the identity . Finally, the delta function picks out , and

which are the Liénard–Wiechert potentials.

In order to calculate the derivatives of and it is convenient to first compute the derivatives of the retarded time. Taking the derivatives of both sides of its defining equation (remembering that ):

Differentiating with respect to t,

Similarly, Taking the gradient with respect to gives

It follows that

These can be used in calculating the derivatives of the vector potential and the resulting expressions are

These show that the Lorenz gauge is satisfied, namely that .

Similarly one calculates:

By noting that for any vectors , , :

The expression for the electric field mentioned above becomes

which is easily seen to be equal to

Similarly gives the expression of the magnetic field mentioned above:

The study of classical electrodynamics was instrumental in Einstein's development of the theory of relativity. Analysis of the motion and propagation of electromagnetic waves led to the special relativity description of space and time. The Liénard–Wiechert formulation is an important launchpad into a deeper analysis of relativistic moving particles.

The Liénard–Wiechert description is accurate for a large (i.e., not quantum mechanical), independent (i.e., free of external influence) moving particle.The Liénard–Wiechert formulation always provides two sets of solutions: Advanced fields are absorbed by the charges and retarded fields are emitted. Schwarzschild and Fokker considered the advanced field of a system of moving charges, and the retarded field of a system of charges having the same geometry and opposite charges. Linearity of Maxwell's equations in vacuum allows one to add both systems, so that the charges disappear: This trick allows Maxwell's equations to become linear in matter. Multiplying electric parameters of both problems by arbitrary real constants produces a coherent interaction of light with matter which generalizes Einstein's theory (A. Einstein, “Zur Quantentheorie der Strahlung.” Phys. Z. 18 121-128, 1917) which is now considered as founding theory of lasers: it is not necessary to study a large set of identical molecules to get coherent amplification in the mode obtained by arbitrary multiplications of advanced and retarded fields. To compute energy, it is necessary to use the absolute fields which includes the zero point field; otherwise, an error appears, for instance in photon counting.

It is important to take into account the zero point field discovered by Planck (M. Planck, Deutsche Physikalische Gesellschaft, Vol. 13, 1911, pp. 138–175.). It replaces Einstein's "A" coefficient and explains that the classical electron is stable on Rydberg's classical orbits. Moreover, introducing the fluctuations of the zero point field produces Willis E. Lamb's correction of levels of H atom.

Quantum electrodynamics helped bring together the radiative behavior with the quantum constraints. It introduces quantization of normal modes of the electromagnetic field in assumed perfect optical resonators.

The force on a particle at a given location * r* and time

where is the distance of the particle from the source at the retarded time. Only electromagnetic wave effects depend fully on the retarded time.

A novel feature in the Liénard–Wiechert potential is seen in the breakup of its terms into two types of field terms (see below), only one of which depends fully on the retarded time. The first of these is the static electric (or magnetic) field term that depends only on the distance to the moving charge, and does not depend on the retarded time at all, if the velocity of the source is constant. The other term is dynamic, in that it requires that the moving charge be *accelerating* with a component perpendicular to the line connecting the charge and the observer and does not appear unless the source changes velocity. This second term is connected with electromagnetic radiation.

The first term describes near field effects from the charge, and its direction in space is updated with a term that corrects for any constant-velocity motion of the charge on its distant static field, so that the distant static field appears at distance from the charge, with **no** aberration of light or light-time correction. This term, which corrects for time-retardation delays in the direction of the static field, is required by Lorentz invariance. A charge moving with a constant velocity must appear to a distant observer in exactly the same way as a static charge appears to a moving observer, and in the latter case, the direction of the static field must change instantaneously, with no time-delay. Thus, static fields (the first term) point exactly at the true instantaneous (non-retarded) position of the charged object if its velocity has not changed over the retarded time delay. This is true over any distance separating objects.

The second term, however, which contains information about the acceleration and other unique behavior of the charge that cannot be removed by changing the Lorentz frame (inertial reference frame of the observer), is fully dependent for direction on the time-retarded position of the source. Thus, electromagnetic radiation (described by the second term) always appears to come from the direction of the position of the emitting charge **at the retarded time**. Only this second term describes information transfer about the behavior of the charge, which transfer occurs (radiates from the charge) at the speed of light. At "far" distances (longer than several wavelengths of radiation), the 1/R dependence of this term makes electromagnetic field effects (the value of this field term) more powerful than "static" field effects, which are described by the 1/R^{2} field of the first (static) term and thus decay more rapidly with distance from the charge.

The retarded time is not guaranteed to exist in general. For example, if, in a given frame of reference, an electron has just been created, then at this very moment another electron does not yet feel its electromagnetic force at all. However, under certain conditions, there always exists a retarded time. For example, if the source charge has existed for an unlimited amount of time, during which it has always travelled at a speed not exceeding , then there exists a valid retarded time . This can be seen by considering the function . At the present time ; . The derivative is given by

By the mean value theorem, . By making sufficiently large, this can become negative, *i.e.*, at some point in the past, . By the intermediate value theorem, there exists an intermediate with , the defining equation of the retarded time. Intuitively, as the source charge moves back in time, the cross section of its light cone at present time expands faster than it can recede, so eventually it must reach the point . This is not necessarily true if the source charge's speed is allowed to be arbitrarily close to , *i.e.*, if for any given speed there was some time in the past when the charge was moving at this speed. In this case the cross section of the light cone at present time approaches the point as the observer travels back in time but does not necessarily ever reach it.

For a given point and trajectory of the point source , there is at most one value of the retarded time , *i.e.*, one value such that . This can be realized by assuming that there are two retarded times and , with . Then, and . Subtracting gives by the triangle inequality. Unless , this then implies that the average velocity of the charge between and is , which is impossible. The intuitive interpretation is that one can only ever "see" the point source at one location/time at once unless it travels at least at the speed of light to another location. As the source moves forward in time, the cross section of its light cone at present time contracts faster than the source can approach, so it can never intersect the point again.

The conclusion is that, under certain conditions, the retarded time exists and is unique.

- Maxwell's equations which govern classical electromagnetism
- Classical electromagnetism for the larger theory surrounding this analysis
- Relativistic electromagnetism
- Special relativity, which was a direct consequence of these analyses
- Rydberg formula for quantum description of the EM radiation due to atomic orbital electrons
- Jefimenko's equations
- Larmor formula
- Abraham–Lorentz force
- Inhomogeneous electromagnetic wave equation
- Wheeler–Feynman absorber theory also known as the Wheeler–Feynman time-symmetric theory
- Paradox of a charge in a gravitational field
- Whitehead's theory of gravitation

- Griffiths, David. Introduction to Electrodynamics. Prentice Hall, 1999. ISBN 0-13-805326-X.

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