Slice theorem (differential geometry)

Template:Short description In differential geometry, the slice theorem states:^[1] given a manifold ${\displaystyle M}$ on which a Lie group ${\displaystyle G}$ acts as diffeomorphisms, for any ${\displaystyle x}$ in ${\displaystyle M}$, the map ${\displaystyle G/G_x\to M,[g]\mapsto g\cdot x}$ extends to an invariant neighborhood of ${\displaystyle G/G_x}$ (viewed as a zero section) in ${\displaystyle G{\times }_{G_x}{T}_{x}M/T_x(G\cdot x)}$ so that it defines an equivariant diffeomorphism from the neighborhood to its image, which contains the orbit of ${\displaystyle x}$.

The important application of the theorem is a proof of the fact that the quotient ${\displaystyle M/G}$ admits a manifold structure when ${\displaystyle G}$ is compact and the action is free.

In algebraic geometry, there is an analog of the slice theorem; it is called Luna's slice theorem.

Since ${\displaystyle G}$ is compact, there exists an invariant metric; i.e., ${\displaystyle G}$ acts as isometries. One then adapts the usual proof of the existence of a tubular neighborhood using this metric.

• Luna's slice theorem, an analogous result for reductive algebraic group actions on algebraic varieties

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• On a proof of the existence of tubular neighborhoods
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