Electromagnetic stress–energy tensor

In relativistic physics, the electromagnetic stress–energy tensor is the contribution to the stress–energy tensor due to the electromagnetic field.[1] The stress–energy tensor describes the flow of energy and momentum in spacetime. The electromagnetic stress–energy tensor contains the negative of the classical Maxwell stress tensor that governs the electromagnetic interactions.

Definition

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ISQ convention

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The electromagnetic stress–energy tensor in the International System of Quantities (ISQ), which underlies the SI, is[1]   where   is the electromagnetic tensor and where   is the Minkowski metric tensor of metric signature (− + + +) and Einstein's summation convention over repeated indices is used.

Explicitly in matrix form:   where   is the Poynting vector,   is the Maxwell stress tensor, and   is the speed of light. Thus, each component of   is dimensionally equivalent to pressure (with SI unit pascal).

Gaussian CGS conventions

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The permittivity of free space and permeability of free space in the Gaussian convention are   then:   and in explicit matrix form:   where the Poynting vector becomes:  

The stress–energy tensor for an electromagnetic field in a dielectric medium is less well understood and is the subject of the unresolved Abraham–Minkowski controversy.[2]

The element   of the stress–energy tensor represents the flux of the μth-component of the four-momentum of the electromagnetic field,  , going through a hyperplane. It represents the contribution of electromagnetism to the source of the gravitational field (curvature of spacetime) in general relativity.

Algebraic properties

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The electromagnetic stress–energy tensor has several algebraic properties:

  • It is a symmetric tensor:  
  • The tensor   is traceless:  
    Proof

    Starting with  

    Using the explicit form of the tensor,  

    Lowering the indices and using the fact that  ,  

    Then, using  ,  

    Note that in the first term,   and   are dummy indices, so we relabel them as   and   respectively.  

  • The energy density is positive-definite:  

The symmetry of the tensor is as for a general stress–energy tensor in general relativity. The trace of the energy–momentum tensor is a Lorentz scalar; the electromagnetic field (and in particular electromagnetic waves) has no Lorentz-invariant energy scale, so its energy–momentum tensor must have a vanishing trace. This tracelessness eventually relates to the masslessness of the photon.[3]

Conservation laws

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The electromagnetic stress–energy tensor allows a compact way of writing the conservation laws of linear momentum and energy in electromagnetism. The divergence of the stress–energy tensor is:   where   is the (4D) Lorentz force per unit volume on matter.

This equation is equivalent to the following 3D conservation laws   respectively describing the flux of electromagnetic energy density   and electromagnetic momentum density   where   is the electric current density,   the electric charge density, and   is the Lorentz force density.

See also

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References

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  1. ^ a b Gravitation, J.A. Wheeler, C. Misner, K.S. Thorne, W.H. Freeman & Co, 1973, ISBN 0-7167-0344-0
  2. ^ however see Pfeifer et al., Rev. Mod. Phys. 79, 1197 (2007)
  3. ^ Garg, Anupam. Classical Electromagnetism in a Nutshell, p. 564 (Princeton University Press, 2012).