Contorsion tensor

The contorsion tensor in differential geometry expresses the difference between a metric-compatible affine connection with Christoffel symbol  \Gamma_{ij}{}^k and the unique torsion-free Levi-Civita connection for the same metric.

The contortion tensor {K_{ab}}^c is defined in terms of the torsion tensor {T_{ij}}^k= {\Gamma_{ij}}^k -{\Gamma_{ji}}^k as

K_{ijk}= \frac{1}{2} (T_{ijk} - T_{jki} + T_{kij}  ),

where the indices are being raised and lowered with respect to the metric:

T_{ijk} \equiv  g_{kl} {T_{ij}}^l.

The reason for the non-obvious sum in the definition is that the contortion tensor, being the difference between two metric-compatible Christoffel symbols, must be antisymmetric in the last two indices, whilst the torsion tensor itself is antisymmetric in its first two indices.

The connection can now be written as

 {\Gamma_{kj}}^i =\bar\Gamma_{kj}{}^i + {K_{kj}}^i,

where  \bar\Gamma_{kj}{}^i is the torsion-free Levi-Civita connection.