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Fundamental theorem of Riemannian Geometry question

Mathematics Asked by monoidaltransform on January 10, 2021

Theorem:

Let $(M,g)$ be a Riemannian Manifold. Then there exists a unique Riemannian connection on $M$.

My concern is with the existence part. In particular, I am unsure as to why the following holds:

Let $X,Y$ and $Z$ be smooth vector fields on $M$
Define $nabla_{X}Y$ by

begin{align}
langle nabla_{X}Y,Zrangle &= frac{1}{2}(Xlangle Y,Zrangle +Ylangle Z,Xrangle -Zlangle X,Yrangle \
& -langle X,[Y,Z]rangle +langle Y,[Z,X]rangle +langle Z,[X,Y]rangle ).
end{align}

This defines a connection on $M$. Why does this define $nabla_{X}Y?$ and how do I show that $nabla_{X}Y$ is a smooth vector field? Please do not use Christoffel symbols.

2 Answers

The actual verification is perhaps annoying but straightforward (people already linked other answers in the comments). But here's a few further comments about the truth behind the Koszul formula:

  1. to define $nabla$, you need to define $nabla Y$ for all $Y$, where $(nabla Y)(X) = nabla_XY$.

  2. since the metric is non-degenerate, knowing $nabla_XY$ is the same as knowing $langle nabla_XY,cdotrangle$. That is, the same as knowing $langle nabla_XY,Zrangle$ for all $Z$. This is exactly what the Koszul formula does.

  3. If we write $Y_flat = langle Y,cdotrangle$, the Koszul formula may be rewritten as $$2langle nabla_XY,Zrangle = (mathcal{L}_Yg)(X,Z) + {rm d}(Y_flat)(X,Z),$$where $g$ is the metric, $mathcal{L}$ denotes Lie derivative and ${rm d}$ is the exterior derivative. Since $nabla$ will satisfy a Leibniz rule, the above formula makes sense: we have a derivation term $mathcal{L}_Yg$ and a linear (in $Y$) term ${rm d}(Y_flat)$, which should be thought of as the curl of $Y$.

Also, smoothness of $nabla_XY$ follows from everything else in the Koszul formula being smooth (although smoothness can be shown easier with local computations using Christoffel symbols).

Correct answer by Ivo Terek on January 10, 2021

Given a fiber bundle $(E, M, pi)$, an affine connection is a bilinear form $$nabla : mathfrak{X}(M) times Gamma(E) to Gamma(E) $$ such that

(a.) $nabla_{fW}V = f nabla_W V,$

(b.) $nabla_W fV = f nabla_W V + W(f) V,$

where $W in mathfrak{X}(M), V in Gamma(E) $ e $f in mathcal{C}^{infty} (M)$.

A Riemannian connection is defined as an affine connection on the tangent bundle $TM$ of a Riemannian manifold $(M,g)$ which is compatible with the metric and torsion free.

To show that there exists a Riemannian connection you want to show that the Koszul formula defines a Riemannian connection, that is, it is enough to show that:

(1) $nabla_xY-nabla_YX = [X,Y],$ (torsion free)

(2) $X g(Y,Z) = g(nabla_XY,Z) + g(Y,nabla_X,Z)$, (compatible with the metric)

for all $X,Y,Z in mathfrak{X}(M)$.

Note that the space of sections of the tangent bundle is $mathfrak{X}(M)$. Then a Riemannian connection is a bilinear form $$nabla : mathfrak{X}(M) times mathfrak{X}(M) to mathfrak{X}(M), $$ so $nabla_X Y in mathfrak{X}(M)$.

To prove (1) note that it is equivalent to show that $$ g(nabla_xY-nabla_YX, Z) = g([X,Y], Z), forall Z in mathfrak{X}(M),$$ and to prove (2) just use the Koszul formula to calculate the right side of the equation (in (2)). There you go!

I hope this can help you.

Answered by Alice on January 10, 2021

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