Fundamental theorem of Riemannian geometry
Template:Use American English Template:Short description The fundamental theorem of Riemannian geometry states that on any Riemannian manifold (or pseudo-Riemannian manifold) there is a unique affine connection that is torsion-free and metric-compatible, called the Levi-Civita connection or Template:NowrapRiemannian connection of the given metric. Because it is canonically defined by such properties, this connection is often automatically used when given a metric.
StatementEdit
The theorem can be stated as follows:
Fundamental theorem of Riemannian Geometry.Template:Sfnm Let Template:Math be a Riemannian manifold (or pseudo-Riemannian manifold). Then there is a unique connection Template:Math which satisfies the following conditions:
- for any vector fields Template:Mvar, Template:Mvar, and Template:Mvar we have <math display=block>X \big(g(Y,Z)\big) = g( \nabla_X Y,Z ) + g( Y,\nabla_X Z ),</math> where Template:Math denotes the derivative of the function Template:Math along vector field Template:Mvar.
- for any vector fields Template:Mvar, Template:Mvar, <math display=block>\nabla_XY-\nabla_YX=[X,Y],</math> where Template:Math denotes the Lie bracket of Template:Mvar and Template:Mvar.
The first condition is called metric-compatibility of Template:Math.Template:Sfnm It may be equivalently expressed by saying that, given any curve in Template:Mvar, the inner product of any two Template:Math–parallel vector fields along the curve is constant.Template:Sfnm It may also be equivalently phrased as saying that the metric tensor is preserved by parallel transport, which is to say that the metric is parallel when considering the natural extension of Template:Math to act on (0,2)-tensor fields: Template:Math.Template:Sfnm It is further equivalent to require that the connection is induced by a principal bundle connection on the orthonormal frame bundle.Template:Sfnm
The second condition is sometimes called symmetry of Template:Math.Template:Sfnm It expresses the condition that the torsion of Template:Math is zero, and as such is also called torsion-freeness.Template:Sfnm There are alternative characterizations.Template:Sfnm
An extension of the fundamental theorem states that given a pseudo-Riemannian manifold there is a unique connection preserving the metric tensor, with any given vector-valued 2-form as its torsion. The difference between an arbitrary connection (with torsion) and the corresponding Levi-Civita connection is the contorsion tensor.
The fundamental theorem asserts both existence and uniqueness of a certain connection, which is called the Levi-Civita connection or Template:NowrapRiemannian connection. However, the existence result is extremely direct, as the connection in question may be explicitly defined by either the second Christoffel identity or Koszul formula as obtained in the proofs below. This explicit definition expresses the Levi-Civita connection in terms of the metric and its first derivatives. As such, if the metric is Template:Mvar-times continuously differentiable, then the Levi-Civita connection is Template:Math-times continuously differentiable.Template:Sfnm
The Levi-Civita connection can also be characterized in other ways, for instance via the Palatini variation of the Einstein–Hilbert action.
ProofEdit
The proof of the theorem can be presented in various ways.<ref>See for instance pages 54-55 of Template:Harvtxt or pages 158-159 of Template:Harvtxt for presentations differing from those given here.</ref> Here the proof is first given in the language of coordinates and Christoffel symbols, and then in the coordinate-free language of covariant derivatives. Regardless of the presentation, the idea is to use the metric-compatibility and torsion-freeness conditions to obtain a direct formula for any connection that is both metric-compatible and torsion-free. This establishes the uniqueness claim in the fundamental theorem. To establish the existence claim, it must be directly checked that the formula obtained does define a connection as desired.
Local coordinatesEdit
Here the Einstein summation convention will be used, which is to say that an index repeated as both subscript and superscript is being summed over all values. Let Template:Mvar denote the dimension of Template:Mvar. Recall that, relative to a local chart, a connection is given by Template:Math smooth functions <math display=block>\left \{ \Gamma^l_{ij} \right \},</math> with <math display=block>(\nabla_XY)^i=X^j\partial_jY^i+X^jY^k\Gamma_{jk}^i</math> for any vector fields Template:Mvar and Template:Mvar.Template:Sfnm Torsion-freeness of the connection refers to the condition that Template:Math for arbitrary Template:Mvar and Template:Mvar. Written in terms of local coordinates, this is equivalent to <math display=block>0=X^jY^k(\Gamma_{jk}^i-\Gamma_{kj}^i),</math> which by arbitrariness of Template:Mvar and Template:Mvar is equivalent to the condition Template:Math.Template:Sfnm Similarly, the condition of metric-compatibility is equivalent to the conditionTemplate:Sfnm <math display=block>\partial_kg_{ij}=\Gamma_{ki}^lg_{lj}+\Gamma_{kj}^lg_{il}.</math> In this way, it is seen that the conditions of torsion-freeness and metric-compatibility can be viewed as a linear system of equations for the connection, in which the coefficients and 'right-hand side' of the system are given by the metric and its first derivative. The fundamental theorem of Riemannian geometry can be viewed as saying that this linear system has a unique solution. This is seen via the following computation:Template:Sfnm <math display=block>\begin{align}\partial_ig_{jl}+\partial_jg_{il}-\partial_lg_{ij}&=\left(\Gamma_{ij}^pg_{pl}+\Gamma_{il}^pg_{jp}\right)+\left(\Gamma_{ji}^pg_{pl}+\Gamma_{jl}^pg_{ip}\right)-\left(\Gamma_{li}^pg_{pj}+\Gamma_{lj}^pg_{ip}\right)\\ &=2\Gamma_{ij}^pg_{pl}\end{align}</math> in which the metric-compatibility condition is used three times for the first equality and the torsion-free condition is used three times for the second equality. The resulting formula is sometimes known as the first Christoffel identity.Template:Sfnm It can be contracted with the inverse of the metric, Template:Math, to find the second Christoffel identity:Template:Sfnm <math display=block>\Gamma^k_{ij} = \tfrac{1}{2} g^{kl}\left ( \partial_i g_{jl}+ \partial_j g_{il} - \partial_l g_{ij} \right ).</math> This proves the uniqueness of a torsion-free and metric-compatible condition; that is, any such connection must be given by the above formula. To prove the existence, it must be checked that the above formula defines a connection that is torsion-free and metric-compatible. This can be done directly.
Invariant formulationEdit
The above proof can also be expressed in terms of vector fields.Template:Sfnm Torsion-freeness refers to the condition that <math display=block>\nabla_XY-\nabla_YX=[X,Y],</math> and metric-compatibility refers to the condition that <math display=block>X\left(g(Y,Z)\right)=g(\nabla_XY,Z)+g(Y,\nabla_XZ),</math> where Template:Mvar, Template:Mvar, and Template:Mvar are arbitrary vector fields. The computation previously done in local coordinates can be written as <math display="block">\begin{align}X\left(g(Y,Z)\right)&+Y\left(g(X,Z)\right)-Z\left(g(X,Y)\right)\\ &=\Big(g(\nabla_XY,Z)+g(Y,\nabla_XZ)\Big)+\Big(g(\nabla_YX,Z)+g(X,\nabla_YZ)\Big)-\Big(g(\nabla_ZX,Y)+g(X,\nabla_ZY)\Big)\\ &=g(\nabla_XY+\nabla_YX,Z)+g(\nabla_XZ-\nabla_ZX,Y)+g(\nabla_YZ-\nabla_ZY,X)\\ &=g(2\nabla_XY+[Y,X],Z)+g([X,Z],Y)+g([Y,Z],X).\end{align}</math> This reduces immediately to the first Christoffel identity in the case that Template:Mvar, Template:Mvar, and Template:Mvar are coordinate vector fields. The equations displayed above can be rearranged to produce the Koszul formula or identity <math display="block">2g(\nabla_XY,Z)=X\left(g(Y,Z)\right)+Y\left(g(X,Z)\right)-Z\left(g(X,Y)\right)+g([X,Y],Z)-g([X,Z],Y)-g([Y,Z],X).</math> This proves the uniqueness of a torsion-free and metric-compatible condition, since if Template:Math is equal to Template:Math for arbitrary Template:Mvar, then Template:Mvar must equal Template:Mvar. This is a consequence of the non-degeneracy of the metric. In the local formulation above, this key property of the metric was implicitly used, in the same way, via the existence of Template:Math. Furthermore, by the same reasoning, the Koszul formula can be used to define a vector field Template:Math when given Template:Mvar and Template:Mvar, and it is routine to check that this defines a connection that is torsion-free and metric-compatible.Template:Sfnm
NotesEdit
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