In electromagnetism, the electromagnetic tensor or electromagnetic field tensor (sometimes called the field strength tensor, Faraday tensor or Maxwell bivector) is a mathematical object that describes the electromagnetic field in spacetime. The field tensor was first used after the four-dimensional tensor formulation of special relativity was introduced by Hermann Minkowski. The tensor allows related physical laws to be written concisely, and allows for the quantization of the electromagnetic field by the Lagrangian formulation described below.
The electromagnetic tensor, conventionally labelled F, is defined as the exterior derivative of the electromagnetic four-potential, A, a differential 1-form:[1] [2]
F \stackrel{def
Therefore, F is a differential 2-form— an antisymmetric rank-2 tensor field—on Minkowski space. In component form,
F\mu\nu=\partial\muA\nu-\partial\nuA\mu.
where
\partial
A
SI units for Maxwell's equations and the particle physicist's sign convention for the signature of Minkowski space, will be used throughout this article.
The Faraday differential 2-form is given by
F=(Ex/c) dx\wedgedt+(Ey/c) dy\wedgedt+(Ez/c) dz\wedgedt+Bx dy\wedgedz+By dz\wedgedx+Bz dx\wedgedy,
where
dt
c
This is the exterior derivative of its 1-form antiderivative
A=Ax dx+Ay dy+Az dz-(\phi/c) dt
where
\phi(\vec{x},t)
-\vec{\nabla}\phi=\vec{E}
\phi
\vec{E}
\vec{A}(\vec{x},t)
\vec{\nabla} x \vec{A}=\vec{B}
\vec{A}
\vec{B}
Note that
\begin{cases}dF=0\ {\star}d{\star}F=J\end{cases}
where
d
{\star}
J=-Jx dx-Jy dy-Jz dz+\rho dt
\vec{J}
\rho
The electric and magnetic fields can be obtained from the components of the electromagnetic tensor. The relationship is simplest in Cartesian coordinates:
Ei=cF0i,
Bi=-1/2\epsilonijkFjk,
\epsilonijk
F\mu\nu=\begin{bmatrix} 0&-Ex/c&-Ey/c&-Ez/c\\ Ex/c&0&-Bz&By\\ Ey/c&Bz&0&-Bx\\ Ez/c&-By&Bx&0 \end{bmatrix}.
The covariant form is given by index lowering,
F\mu\nu=η\alpha\nuF\beta\alphaη\mu\beta=\begin{bmatrix} 0&Ex/c&Ey/c&Ez/c\\ -Ex/c&0&-Bz&By\\ -Ey/c&Bz&0&-Bx\\ -Ez/c&-By&Bx&0 \end{bmatrix}.
{G\alpha\beta=
| 1 | |
| 2 |
\epsilon\alpha\beta\gamma\deltaF\gamma\delta=\begin{bmatrix} 0&-Bx&-By&-Bz\\ Bx&0&Ez/c&-Ey/c\\ By&-Ez/c&0&Ex/c\\ Bz&Ey/c&-Ex/c&0 \end{bmatrix} }
From now on in this article, when the electric or magnetic fields are mentioned, a Cartesian coordinate system is assumed, and the electric and magnetic fields are with respect to the coordinate system's reference frame, as in the equations above.
The matrix form of the field tensor yields the following properties:[3]
F\mu\nu
G\mu\nu
\epsilon\alpha\beta\gamma\delta
\epsilon0123=-1
which is proportional to the square of the above invariant.
which is equal to zero.
This tensor simplifies and reduces Maxwell's equations as four vector calculus equations into two tensor field equations. In electrostatics and electrodynamics, Gauss's law and Ampère's circuital law are respectively:
\nabla ⋅ E=
| \rho | |
| \epsilon0 |
, \nabla x B-
| 1 | |
| c2 |
| \partialE | |
| \partialt |
=\mu0J
and reduce to the inhomogeneous Maxwell equation:
\partial\alphaF\beta\alpha=-\mu0J\beta
J\alpha=(c\rho,J)
In magnetostatics and magnetodynamics, Gauss's law for magnetism and Maxwell–Faraday equation are respectively:
\nabla ⋅ B=0,
| \partialB | |
| \partialt |
+\nabla x E=0
which reduce to the Bianchi identity:
\partial\gammaF+\partial\alphaF+\partial\betaF=0
or using the index notation with square brackets for the antisymmetric part of the tensor:
\partialF=0
\equiv0
See main article: Maxwell's equations in curved spacetime.
The field tensor derives its name from the fact that the electromagnetic field is found to obey the tensor transformation law, this general property of physical laws being recognised after the advent of special relativity. This theory stipulated that all the laws of physics should take the same form in all coordinate systems – this led to the introduction of tensors. The tensor formalism also leads to a mathematically simpler presentation of physical laws.
The inhomogeneous Maxwell equation leads to the continuity equation:
\partial\alphaJ\alpha=
| \alpha{} | |
| J | |
| ,\alpha |
=0
implying conservation of charge.
Maxwell's laws above can be generalised to curved spacetime by simply replacing partial derivatives with covariant derivatives:
F[\alpha\beta;\gamma]=0
F\alpha\beta{};\alpha=\mu0J\beta
where the semicolon notation represents a covariant derivative, as opposed to a partial derivative. These equations are sometimes referred to as the curved space Maxwell equations. Again, the second equation implies charge conservation (in curved spacetime):
| \alpha{} | |
| J | |
| ;\alpha |
=0
See also: Classical field theory.
Classical electromagnetism and Maxwell's equations can be derived from the action:where
d4x
This means the Lagrangian density is
\begin{align} l{L}&=-
| 1 | |
| 4\mu0 |
F\mu\nuF\mu\nu-J\muA\mu\\ &=-
| 1 | |
| 4\mu0 |
\left(\partial\muA\nu-\partial\nuA\mu\right)\left(\partial\muA\nu-\partial\nuA\mu\right)-J\muA\mu\\ &=-
| 1 | |
| 4\mu0 |
\left(\partial\muA\nu\partial\muA\nu-\partial\nuA\mu\partial\muA\nu-\partial\muA\nu\partial\nuA\mu+\partial\nuA\mu\partial\nuA\mu\right)-J\muA\mu\\ \end{align}
The two middle terms in the parentheses are the same, as are the two outer terms, so the Lagrangian density is
l{L}=-
| 1 | |
| 2\mu0 |
\left(\partial\muA\nu\partial\muA\nu-\partial\nuA\mu\partial\muA\nu\right)-J\muA\mu.
Substituting this into the Euler–Lagrange equation of motion for a field:
\partial\mu\left(
| \partiall{L | |
So the Euler–Lagrange equation becomes:
-\partial\mu
| 1 | |
| \mu0 |
\left(\partial\muA\nu-\partial\nuA\mu\right)+J\nu=0.
The quantity in parentheses above is just the field tensor, so this finally simplifies to
\partial\muF\mu=\mu0J\nu
That equation is another way of writing the two inhomogeneous Maxwell's equations (namely, Gauss's law and Ampère's circuital law) using the substitutions:
\begin{align}
| 1 | |
| c |
Ei&=-F0\\ \epsilonijkBk&=-Fij\end{align}
where i, j, k take the values 1, 2, and 3.
The Hamiltonian density can be obtained with the usual relation,
| i,\pi | |
| l{H}(\phi | |
| i) |
=\pii
| \phi |
i(\phi
| i,\pi | |
| i) |
-l{L}
See main article: Quantum electrodynamics and quantum field theory.
The Lagrangian of quantum electrodynamics extends beyond the classical Lagrangian established in relativity to incorporate the creation and annihilation of photons (and electrons):
l{L}=\bar\psi\left(i\hbarc\gamma\alphaD\alpha-mc2\right)\psi-
| 1 | |
| 4\mu0 |
F\alpha\betaF\alpha\beta,
\psi