Electromagnetic wave equation

Template:More citations needed Template:Use American English Template:Short description The electromagnetic wave equation is a second-order partial differential equation that describes the propagation of electromagnetic waves through a medium or in a vacuum. It is a three-dimensional form of the wave equation. The homogeneous form of the equation, written in terms of either the electric field Template:Math or the magnetic field Template:Math, takes the form:

$${\displaystyle \begin{array}{cc}(v_{\mathrm{p}\mathrm{h}}^2{\mathrm{\nabla }}^2-\frac{{\partial }^2}{\partial t^2})𝐄& =\mathrm{𝟎}\\ (v_{\mathrm{p}\mathrm{h}}^2{\mathrm{\nabla }}^2-\frac{{\partial }^2}{\partial t^2})𝐁& =\mathrm{𝟎}\end{array}}$$

where

$${\displaystyle v_{\mathrm{p}\mathrm{h}}=\frac{1}{\sqrt{\mu \epsilon }}}$$

is the speed of light (i.e. phase velocity) in a medium with permeability Template:Mvar, and permittivity Template:Mvar, and Template:Math is the Laplace operator. In a vacuum, Template:Math, a fundamental physical constant.^[1] The electromagnetic wave equation derives from Maxwell's equations. In most older literature, Template:Math is called the magnetic flux density or magnetic induction. The following equations$${\displaystyle \begin{array}{cc}\mathrm{\nabla }\cdot 𝐄& =0\\ \mathrm{\nabla }\cdot 𝐁& =0\end{array}}$$predicate that any electromagnetic wave must be a transverse wave, where the electric field Template:Math and the magnetic field Template:Math are both perpendicular to the direction of wave propagation.

In his 1865 paper titled A Dynamical Theory of the Electromagnetic Field, James Clerk Maxwell utilized the correction to Ampère's circuital law that he had made in part III of his 1861 paper On Physical Lines of Force. In Part VI of his 1864 paper titled Electromagnetic Theory of Light,^[2] Maxwell combined displacement current with some of the other equations of electromagnetism and he obtained a wave equation with a speed equal to the speed of light. He commented:

The agreement of the results seems to show that light and magnetism are affections of the same substance, and that light is an electromagnetic disturbance propagated through the field according to electromagnetic laws.^[3]

Maxwell's derivation of the electromagnetic wave equation has been replaced in modern physics education by a much less cumbersome method involving combining the corrected version of Ampère's circuital law with Faraday's law of induction.

To obtain the electromagnetic wave equation in a vacuum using the modern method, we begin with the modern 'Heaviside' form of Maxwell's equations. In a vacuum- and charge-free space, these equations are:

$${\displaystyle \begin{array}{cc}\mathrm{\nabla }\cdot 𝐄& =0\\ \mathrm{\nabla }\times 𝐄& =-\frac{\partial 𝐁}{\partial t}\\ \mathrm{\nabla }\cdot 𝐁& =0\\ \mathrm{\nabla }\times 𝐁& ={\mu }_0{\epsilon }_0\frac{\partial 𝐄}{\partial t}\\ \end{array}}$$

These are the general Maxwell's equations specialized to the case with charge and current both set to zero. Taking the curl of the curl equations gives:

$${\displaystyle \begin{array}{cc}\mathrm{\nabla }\times (\mathrm{\nabla }\times 𝐄)& =\mathrm{\nabla }\times (-\frac{\partial 𝐁}{\partial t})=-\frac{\partial }{\partial t}(\mathrm{\nabla }\times 𝐁)=-{\mu }_0{\epsilon }_0\frac{{\partial }^2𝐄}{\partial t^2}\\ \mathrm{\nabla }\times (\mathrm{\nabla }\times 𝐁)& =\mathrm{\nabla }\times \left({\mu }_0{\epsilon }_0\frac{\partial 𝐄}{\partial t}\right)={\mu }_0{\epsilon }_0\frac{\partial }{\partial t}(\mathrm{\nabla }\times 𝐄)=-{\mu }_0{\epsilon }_0\frac{{\partial }^2𝐁}{\partial t^2}\end{array}}$$

We can use the vector identity

$${\displaystyle \mathrm{\nabla }\times (\mathrm{\nabla }\times 𝐕)=\mathrm{\nabla }(\mathrm{\nabla }\cdot 𝐕)-{\mathrm{\nabla }}^2𝐕}$$

where Template:Math is any vector function of space. And

$${\displaystyle {\mathrm{\nabla }}^2𝐕=\mathrm{\nabla }\cdot \left(\mathrm{\nabla }𝐕\right)}$$

where Template:Math is a dyadic which when operated on by the divergence operator Template:Math yields a vector. Since

$${\displaystyle \begin{array}{cc}\mathrm{\nabla }\cdot 𝐄& =0\\ \mathrm{\nabla }\cdot 𝐁& =0\end{array}}$$

then the first term on the right in the identity vanishes and we obtain the wave equations:

$${\displaystyle \begin{array}{cc}\frac{1}{c_0^2}\frac{{\partial }^2𝐄}{\partial t^2}-{\mathrm{\nabla }}^2𝐄& =\mathrm{𝟎}\\ \frac{1}{c_0^2}\frac{{\partial }^2𝐁}{\partial t^2}-{\mathrm{\nabla }}^2𝐁& =\mathrm{𝟎}\end{array}}$$

where

$${\displaystyle c_0=\frac{1}{\sqrt{{\mu }_0{\epsilon }_0}}=2.99792458\times 10^8\text{m/s}}$$

is the speed of light in free space.

These relativistic equations can be written in contravariant form as

$${\displaystyle ◻A^{\mu }=0}$$

where the electromagnetic four-potential is

$${\displaystyle A^{\mu }=(\frac{\varphi }{c},𝐀)}$$

with the Lorenz gauge condition:

$${\displaystyle {\partial }_{\mu }{A}^{\mu }=0,}$$

and where

$${\displaystyle ◻={\mathrm{\nabla }}^2-\frac{1}{c^2}\frac{{\partial }^2}{\partial t^2}}$$

is the d'Alembert operator.

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The electromagnetic wave equation is modified in two ways, the derivative is replaced with the covariant derivative and a new term that depends on the curvature appears.

$${\displaystyle -{A^{\alpha ;\beta }}_{;\beta }+{R^{\alpha }}_{\beta }{A}^{\beta }=0}$$

where ${\displaystyle {R^{\alpha }}_{\beta }}$ is the Ricci curvature tensor and the semicolon indicates covariant differentiation.

The generalization of the Lorenz gauge condition in curved spacetime is assumed:

$${\displaystyle {A^{\mu }}_{;\mu }=0.}$$

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Localized time-varying charge and current densities can act as sources of electromagnetic waves in a vacuum. Maxwell's equations can be written in the form of a wave equation with sources. The addition of sources to the wave equations makes the partial differential equations inhomogeneous.

Template:Main The general solution to the electromagnetic wave equation is a linear superposition of waves of the form

$${\displaystyle \begin{array}{cc}𝐄(𝐫,t)& =g(\varphi (𝐫,t))=g(\omega t-𝐤\cdot 𝐫)\\ 𝐁(𝐫,t)& =g(\varphi (𝐫,t))=g(\omega t-𝐤\cdot 𝐫)\end{array}}$$

for virtually Template:Em well-behaved function Template:Mvar of dimensionless argument Template:Mvar, where Template:Mvar is the angular frequency (in radians per second), and Template:Math is the wave vector (in radians per meter).

Although the function Template:Mvar can be and often is a monochromatic sine wave, it does not have to be sinusoidal, or even periodic. In practice, Template:Mvar cannot have infinite periodicity because any real electromagnetic wave must always have a finite extent in time and space. As a result, and based on the theory of Fourier decomposition, a real wave must consist of the superposition of an infinite set of sinusoidal frequencies.

In addition, for a valid solution, the wave vector and the angular frequency are not independent; they must adhere to the dispersion relation:

$${\displaystyle k=|𝐤|=\frac{\omega }{c}=\frac{2\pi }{\lambda }}$$

where Template:Mvar is the wavenumber and Template:Mvar is the wavelength. The variable Template:Mvar can only be used in this equation when the electromagnetic wave is in a vacuum.

The simplest set of solutions to the wave equation result from assuming sinusoidal waveforms of a single frequency in separable form:

$${\displaystyle 𝐄(𝐫,t)=\mathrm{\Re }\{𝐄(𝐫)e^{i\omega t}\}}$$

where

• Template:Mvar is the imaginary unit,
• Template:Math is the angular frequency in radians per second,
• Template:Math is the frequency in hertz, and
• ${\displaystyle e^{i\omega t}=\cos (\omega t)+i\sin (\omega t)}$ is Euler's formula.

Template:Main Consider a plane defined by a unit normal vector

$${\displaystyle 𝐧=\frac{𝐤}{k}.}$$

Then planar traveling wave solutions of the wave equations are

$${\displaystyle \begin{array}{cc}𝐄(𝐫)& ={𝐄}_0{e}^{-i𝐤\cdot 𝐫}\\ 𝐁(𝐫)& ={𝐁}_0{e}^{-i𝐤\cdot 𝐫}\end{array}}$$

where Template:Math is the position vector (in meters).

These solutions represent planar waves traveling in the direction of the normal vector Template:Math. If we define the Template:Mvar direction as the direction of Template:Math, and the Template:Mvar direction as the direction of Template:Math, then by Faraday's Law the magnetic field lies in the Template:Mvar direction and is related to the electric field by the relation

$${\displaystyle c^2\frac{\partial B}{\partial z}=\frac{\partial E}{\partial t}.}$$

Because the divergence of the electric and magnetic fields are zero, there are no fields in the direction of propagation.

This solution is the linearly polarized solution of the wave equations. There are also circularly polarized solutions in which the fields rotate about the normal vector.

Because of the linearity of Maxwell's equations in a vacuum, solutions can be decomposed into a superposition of sinusoids. This is the basis for the Fourier transform method for the solution of differential equations. The sinusoidal solution to the electromagnetic wave equation takes the form

$${\displaystyle \begin{array}{cc}𝐄(𝐫,t)& ={𝐄}_0\cos (\omega t-𝐤\cdot 𝐫+{\varphi }_0)\\ 𝐁(𝐫,t)& ={𝐁}_0\cos (\omega t-𝐤\cdot 𝐫+{\varphi }_0)\end{array}}$$

where

• Template:Mvar is time (in seconds),
• Template:Mvar is the angular frequency (in radians per second),
• Template:Math is the wave vector (in radians per meter), and
• ${\displaystyle {\varphi }_0}$ is the phase angle (in radians).

The wave vector is related to the angular frequency by

$${\displaystyle k=|𝐤|=\frac{\omega }{c}=\frac{2\pi }{\lambda }}$$

where Template:Mvar is the wavenumber and Template:Mvar is the wavelength.

The electromagnetic spectrum is a plot of the field magnitudes (or energies) as a function of wavelength.

Assuming monochromatic fields varying in time as ${\displaystyle e^{-i\omega t}}$, if one uses Maxwell's Equations to eliminate Template:Math, the electromagnetic wave equation reduces to the Helmholtz equation for Template:Math:

$${\displaystyle ({\mathrm{\nabla }}^2+k^2)𝐄=0,𝐁=-\frac{i}{k}\mathrm{\nabla }\times 𝐄,}$$

with Template:Math as given above. Alternatively, one can eliminate Template:Math in favor of Template:Math to obtain:

$${\displaystyle ({\mathrm{\nabla }}^2+k^2)𝐁=0,𝐄=-\frac{i}{k}\mathrm{\nabla }\times 𝐁.}$$

A generic electromagnetic field with frequency Template:Mvar can be written as a sum of solutions to these two equations. The three-dimensional solutions of the Helmholtz Equation can be expressed as expansions in spherical harmonics with coefficients proportional to the spherical Bessel functions. However, applying this expansion to each vector component of Template:Math or Template:Math will give solutions that are not generically divergence-free (Template:Math), and therefore require additional restrictions on the coefficients.

The multipole expansion circumvents this difficulty by expanding not Template:Math or Template:Math, but Template:Math or Template:Math into spherical harmonics. These expansions still solve the original Helmholtz equations for Template:Math and Template:Math because for a divergence-free field Template:Math, Template:Math. The resulting expressions for a generic electromagnetic field are:

$${\displaystyle \begin{array}{cc}𝐄& =e^{-i\omega t}\sum _{l,m}\sqrt{l(l+1)}[a_E(l,m){𝐄}_{l,m}^{(E)}+a_M(l,m){𝐄}_{l,m}^{(M)}]\\ 𝐁& =e^{-i\omega t}\sum _{l,m}\sqrt{l(l+1)}[a_E(l,m){𝐁}_{l,m}^{(E)}+a_M(l,m){𝐁}_{l,m}^{(M)}],\end{array}}$$

where ${\displaystyle {𝐄}_{l,m}^{(E)}}$ and ${\displaystyle {𝐁}_{l,m}^{(E)}}$ are the electric multipole fields of order (l, m), and ${\displaystyle {𝐄}_{l,m}^{(M)}}$ and ${\displaystyle {𝐁}_{l,m}^{(M)}}$ are the corresponding magnetic multipole fields, and Template:Math and Template:Math are the coefficients of the expansion. The multipole fields are given by

$${\displaystyle \begin{array}{cc}{𝐁}_{l,m}^{(E)}& =\sqrt{l(l+1)}[B_l^{(1)}{h}_l^{(1)}(kr)+B_l^{(2)}{h}_l^{(2)}(kr)]{\mathrm{\Phi }}_{l,m}\\ {𝐄}_{l,m}^{(E)}& =\frac{i}{k}\mathrm{\nabla }\times {𝐁}_{l,m}^{(E)}\\ {𝐄}_{l,m}^{(M)}& =\sqrt{l(l+1)}[E_l^{(1)}{h}_l^{(1)}(kr)+E_l^{(2)}{h}_l^{(2)}(kr)]{\mathrm{\Phi }}_{l,m}\\ {𝐁}_{l,m}^{(M)}& =-\frac{i}{k}\mathrm{\nabla }\times {𝐄}_{l,m}^{(M)},\end{array}}$$

where Template:Math are the spherical Hankel functions, Template:Math and Template:Math are determined by boundary conditions, and

$${\displaystyle {\mathrm{\Phi }}_{l,m}=\frac{1}{\sqrt{l(l+1)}}(𝐫\times \mathrm{\nabla })Y_{l,m}}$$

are vector spherical harmonics normalized so that

$${\displaystyle \int {\mathrm{\Phi }}_{l,m}^{*}\cdot {\mathrm{\Phi }}_{l^{\prime },m^{\prime }}d\mathrm{\Omega }={\delta }_{l,l^{\prime }}{\delta }_{m,m^{\prime }}.}$$

The multipole expansion of the electromagnetic field finds application in a number of problems involving spherical symmetry, for example antennae radiation patterns, or nuclear gamma decay. In these applications, one is often interested in the power radiated in the far-field. In this regions, the Template:Math and Template:Math fields asymptotically approach

$${\displaystyle \begin{array}{cc}𝐁& \approx \frac{e^{i(kr-\omega t)}}{kr}\sum _{l,m}(-i{)}^{l+1}[a_E(l,m){\mathrm{\Phi }}_{l,m}+a_M(l,m)\widehat{𝐫}\times {\mathrm{\Phi }}_{l,m}]\\ 𝐄& \approx 𝐁\times \widehat{𝐫}.\end{array}}$$

The angular distribution of the time-averaged radiated power is then given by

$${\displaystyle \frac{dP}{d\mathrm{\Omega }}\approx \frac{1}{2k^2}{|\sum _{l,m}(-i{)}^{l+1}[a_E(l,m){\mathrm{\Phi }}_{l,m}\times \widehat{𝐫}+a_M(l,m){\mathrm{\Phi }}_{l,m}]|}^2.}$$

Template:Col-begin Template:Col-break

• Maxwell's equations
• Wave equation
• Partial differential equation
• Computational electromagnetics
• Electromagnetic radiation
• Charge conservation
• Light

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• Electromagnetic spectrum
• Optics
• Special relativity
• General relativity
• Inhomogeneous electromagnetic wave equation
• Photon polarization
• Larmor power formula

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Template:Col-begin Template:Col-break

• Rainbow
• Cosmic microwave background
• Laser
• Laser fusion
• Photography
• X-ray
• X-ray crystallography
• Radar

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• Radio wave
• Optical computing
• Microwave
• Holography
• Microscope
• Telescope
• Gravitational lens
• Black-body radiation

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• André-Marie Ampère
• Albert Einstein
• Michael Faraday
• Heinrich Hertz
• Oliver Heaviside
• James Clerk Maxwell
• Hendrik Lorentz

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• Maxwell, James Clerk, "A Dynamical Theory of the Electromagnetic Field", Philosophical Transactions of the Royal Society of London 155, 459-512 (1865). (This article accompanied a December 8, 1864 presentation by Maxwell to the Royal Society.)

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• Hermann A. Haus and James R. Melcher, Electromagnetic Fields and Energy (Prentice-Hall, 1989) Template:ISBN.
• Banesh Hoffmann, Relativity and Its Roots (Freeman, New York, 1983). Template:ISBN.
• David H. Staelin, Ann W. Morgenthaler, and Jin Au Kong, Electromagnetic Waves (Prentice-Hall, 1994) Template:ISBN.
• Charles F. Stevens, The Six Core Theories of Modern Physics, (MIT Press, 1995) Template:ISBN.
• Markus Zahn, Electromagnetic Field Theory: a problem solving approach, (John Wiley & Sons, 1979) Template:ISBN

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• Landau, L. D., The Classical Theory of Fields (Course of Theoretical Physics: Volume 2), (Butterworth-Heinemann: Oxford, 1987). Template:ISBN.
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• Charles W. Misner, Kip S. Thorne, John Archibald Wheeler, Gravitation, (1970) W.H. Freeman, New York; Template:ISBN. (Provides a treatment of Maxwell's equations in terms of differential forms.)

• P. C. Matthews Vector Calculus, Springer 1998, Template:ISBN
• H. M. Schey, Div Grad Curl and all that: An informal text on vector calculus, 4th edition (W. W. Norton & Company, 2005) Template:ISBN.

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