## circle action on sphere

surely $S^1$ can act on $S^n$ as a rotation.I want to know if there is some other way that a circle can act on sphere.

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 It is not hard to list a few other actions... While we are at this: are such actions classified up to isotopy? – Mariano Suárez-Alvarez Mar 18 2010 at 11:51

One example: The sphere $S^{n+m+1}$ is the join $S^n*S^m$of $S^n$ and $S^m$, so having $S^1$ act on each of the factors you get an action on $S^{n+m+1}$.

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 Is that not a standard rotation action around a diagonal axis? – Tilman Mar 18 2010 at 12:22 No. Think of a double rotation (where the action on the two factors rotate by different speeds) on S^3. A standard rotation (on R^4) fixes a two-plane. A double rotation fixes only the center. – Willie Wong Mar 18 2010 at 13:20

A nice example is the Hopf fibration: $S^1 \subset C$ acts on $S^3\subset \mathbb C^2$ by scalar multiplication. The quotient is $\mathbb CP^1.$ Of course there are various generalizations.

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 This action is linear. – Igor Belegradek Mar 18 2010 at 12:27 Incidentally, higher (odd) dimensional spheres admit lots of non-linear free circle actions. They correspond to fake homotopy projective spaces. – Igor Belegradek Mar 18 2010 at 12:57

Classification of circle actions on (standard and on exotic) spheres is a classical activity in transformation groups, see e.g. the article of Schultz in the collection "Group actions on manifolds", proceedings from 1983 conference, or earlier account in Bredon's book "Introduction to compact transformation groups".

One standard example is this. Take a smooth compact contractible $(n+1)$-manifold $C$ and consider $C\times D^k$ where circle acts trivially on $C$ and linearly on the $k$-disk $D^k$, $k>0$. Now if $n+k>4$, the boundary of $C\times D^k$ is diffeomorphic to the standard sphere (after the corners of $C\times D^k$ are rounded). But the fixed point set of the action is the original homology sphere that bounds $C$. I think it is clear that the fixed point sets of linear actions are standard spheres.

Incidentally, in dimensions $k>4$ any homology $k$ sphere bounds a contractible manifold after possibly changing its smooth structure; also any homology $4$-sphere bounds a smooth contractible manifold, while any homology $3$-sphere bounds a topological contractible manifold, but not necessarily smooth ones. References to the above results can by found e.g. in my paper pp.8-9.

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I do not know, in which category your actions live. In the following answer I want to consider isometric actions.

Another classification problem might be:

Classify all periodic one parameter subgroups of $SO(n)$ up to conjugacy, which is the same problem as the classification of all such actions up to isometry.

There is a normal form for orthogonal matrices over the reals, which says, that every such matrix is conjugated to a block matrix consisting of $(2,2)$ rotation matrices and $(1,1)$ diagonal entries, which are $\pm 1$.

My claim would be that every isometric action decomposes (after congugation) uniquely as a induced action on each of the components of the decomposition

$S^n = S^1 * S^1 * \ldots * S^1 * S^0 * \ldots * S^0$ ($*$ should denote the join here). The isometric actions of $S^1$ on $S^1$ can be classified by the integers. The only possibilities are $(t,x)\mapsto mt+x$ for $m\in\mathbb{Z}$.

I think the upper normal forms for matrices should imply this. But I am not sure.

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