Antisymmetric tensor

Tensor equal to the negative of any of its transpositions

In mathematics and theoretical physics, a tensor is antisymmetric on (or with respect to) an index subset if it alternates sign (+/−) when any two indices of the subset are interchanged.[1][2] The index subset must generally either be all covariant or all contravariant.

For example,

T i j k = T j i k = T j k i = T k j i = T k i j = T i k j {\displaystyle T_{ijk\dots }=-T_{jik\dots }=T_{jki\dots }=-T_{kji\dots }=T_{kij\dots }=-T_{ikj\dots }}
holds when the tensor is antisymmetric with respect to its first three indices.

If a tensor changes sign under exchange of each pair of its indices, then the tensor is completely (or totally) antisymmetric. A completely antisymmetric covariant tensor field of order k {\displaystyle k} may be referred to as a differential k {\displaystyle k} -form, and a completely antisymmetric contravariant tensor field may be referred to as a k {\displaystyle k} -vector field.

Antisymmetric and symmetric tensors

A tensor A that is antisymmetric on indices i {\displaystyle i} and j {\displaystyle j} has the property that the contraction with a tensor B that is symmetric on indices i {\displaystyle i} and j {\displaystyle j} is identically 0.

For a general tensor U with components U i j k {\displaystyle U_{ijk\dots }} and a pair of indices i {\displaystyle i} and j , {\displaystyle j,} U has symmetric and antisymmetric parts defined as:

U ( i j ) k = 1 2 ( U i j k + U j i k ) {\displaystyle U_{(ij)k\dots }={\frac {1}{2}}(U_{ijk\dots }+U_{jik\dots })}   (symmetric part)
U [ i j ] k = 1 2 ( U i j k U j i k ) {\displaystyle U_{[ij]k\dots }={\frac {1}{2}}(U_{ijk\dots }-U_{jik\dots })}   (antisymmetric part).

Similar definitions can be given for other pairs of indices. As the term "part" suggests, a tensor is the sum of its symmetric part and antisymmetric part for a given pair of indices, as in

U i j k = U ( i j ) k + U [ i j ] k . {\displaystyle U_{ijk\dots }=U_{(ij)k\dots }+U_{[ij]k\dots }.}

Notation

A shorthand notation for anti-symmetrization is denoted by a pair of square brackets. For example, in arbitrary dimensions, for an order 2 covariant tensor M,

M [ a b ] = 1 2 ! ( M a b M b a ) , {\displaystyle M_{[ab]}={\frac {1}{2!}}(M_{ab}-M_{ba}),}
and for an order 3 covariant tensor T,
T [ a b c ] = 1 3 ! ( T a b c T a c b + T b c a T b a c + T c a b T c b a ) . {\displaystyle T_{[abc]}={\frac {1}{3!}}(T_{abc}-T_{acb}+T_{bca}-T_{bac}+T_{cab}-T_{cba}).}

In any 2 and 3 dimensions, these can be written as

M [ a b ] = 1 2 ! δ a b c d M c d , T [ a b c ] = 1 3 ! δ a b c d e f T d e f . {\displaystyle {\begin{aligned}M_{[ab]}&={\frac {1}{2!}}\,\delta _{ab}^{cd}M_{cd},\\[2pt]T_{[abc]}&={\frac {1}{3!}}\,\delta _{abc}^{def}T_{def}.\end{aligned}}}
where δ a b c d {\displaystyle \delta _{ab\dots }^{cd\dots }} is the generalized Kronecker delta, and we use the Einstein notation to summation over like indices.

More generally, irrespective of the number of dimensions, antisymmetrization over p {\displaystyle p} indices may be expressed as

T [ a 1 a p ] = 1 p ! δ a 1 a p b 1 b p T b 1 b p . {\displaystyle T_{[a_{1}\dots a_{p}]}={\frac {1}{p!}}\delta _{a_{1}\dots a_{p}}^{b_{1}\dots b_{p}}T_{b_{1}\dots b_{p}}.}

In general, every tensor of rank 2 can be decomposed into a symmetric and anti-symmetric pair as:

T i j = 1 2 ( T i j + T j i ) + 1 2 ( T i j T j i ) . {\displaystyle T_{ij}={\frac {1}{2}}(T_{ij}+T_{ji})+{\frac {1}{2}}(T_{ij}-T_{ji}).}

This decomposition is not in general true for tensors of rank 3 or more, which have more complex symmetries.

Examples

Totally antisymmetric tensors include:

  • Trivially, all scalars and vectors (tensors of order 0 and 1) are totally antisymmetric (as well as being totally symmetric).
  • The electromagnetic tensor, F μ ν {\displaystyle F_{\mu \nu }} in electromagnetism.
  • The Riemannian volume form on a pseudo-Riemannian manifold.

See also

  • Antisymmetric matrix – Form of a matrixPages displaying short descriptions of redirect targets
  • Exterior algebra – Algebra of exterior/ wedge products
  • Levi-Civita symbol – Antisymmetric permutation object acting on tensors
  • Ricci calculus – Tensor index notation for tensor-based calculations
  • Symmetric tensor – Tensor invariant under permutations of vectors it acts on
  • Symmetrization – process that converts any function in n variables to a symmetric function in n variablesPages displaying wikidata descriptions as a fallback

Notes

  1. ^ K.F. Riley; M.P. Hobson; S.J. Bence (2010). Mathematical methods for physics and engineering. Cambridge University Press. ISBN 978-0-521-86153-3.
  2. ^ Juan Ramón Ruíz-Tolosa; Enrique Castillo (2005). From Vectors to Tensors. Springer. p. 225. ISBN 978-3-540-22887-5. section §7.

References

  • Penrose, Roger (2007). The Road to Reality. Vintage books. ISBN 978-0-679-77631-4.
  • J.A. Wheeler; C. Misner; K.S. Thorne (1973). Gravitation. W.H. Freeman & Co. pp. 85–86, §3.5. ISBN 0-7167-0344-0.

External links

  • Antisymmetric Tensor – mathworld.wolfram.com
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