Torsion of a linear connection: Difference between revisions

Revision as of 17:46, 6 January 2012

This article defines a tensor (viz a section on a tensor bundle over the manifold) of type (1,2)

Definition

Given data

A differential manifold $M$
A linear connection $\nabla$ on $M$ (viz., a connection on the tangent bundle $TM$ ).

Definition part

The torsion of $\nabla$ , denoted as $\tau (\nabla )$ , is defined as a map that takes as input 2 vector fields and outputs a third vector field, as follows:

$\tau (\nabla )(X,Y)=\nabla _{X}Y-\nabla _{Y}X-[X,Y]$

A linear connection whose torsion is zero is termed a torsion-free linear connection.

Facts

Tensoriality

Further information: Torsion is tensorial

The torsion map is a $(1,2)$ tensor. It is tensorial in both $X$ and $Y$ . This means that the value of the torsion of a connection for two vector fields at a point depends only on the values of the vector fields at that point. In other words, $\tau (\nabla )(X,Y)$ at $p$ depends on $\nabla ,X(p),Y(p)$ only and does not depend on how $X$ and $Y$ behave elsewhere on the manifold.

@@ Line 15: / Line 15: @@
 A linear connection whose torsion is zero is termed a '''torsion-free linear connection'''.
+==Facts==
 ===Tensoriality===
 {{further|[[Torsion is tensorial]]}}
-The torsion map is a <math>(1,2)</math> tensor. It is tensorial in both <math>X</math> and <math>Y</math>.
+The torsion map is a <math>(1,2)</math> tensor. It is tensorial in both <math>X</math> and <math>Y</math>. This means that the value of the torsion of a connection for two vector fields at a point depends only on the values of the vector fields at that point. In other words, <math>\tau(\nabla)(X,Y)</math> at <math>p</math> depends on <math>\nabla, X(p), Y(p)</math> only and does not depend on how <math>X</math> and <math>Y</math> behave elsewhere on the manifold.