Group actions on spheres
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{{Stub}} | {{Stub}} | ||
| + | == Topological actions == | ||
| − | == History == | + | == Smooth actions == |
| + | === Actions with exactly one fixed point === | ||
| + | ==== History ==== | ||
<wikitex>; | <wikitex>; | ||
In 1946, Montgomery and Samelson made a comment \cite{Montgomery&Samelson1946} that when a compact group $G$ acts smoothly on a sphere in such a way as to have one fixed point, it is likely that there must be a second fixed point. In 1977, Stein \cite{Stein1977} has obtained for the first time a counterexample to this speculation. For $G=SL_2(\mathbb{F}_5)$ or $SL_2(\mathbb{F}_5)\times \mathbb{Z}_r$ with $(120, r)=1$, he constructed a smooth action of $G$ on the sphere $S^7$ with exactly one fixed point. Then Petrie \cite{Petrie1982} described smooth one fixed point actions on spheres in the case the acting group $G$ is a finite abelian group of odd order and with three or more non-cyclic Sylow subgroups, as well as for $G=S^3$ or $SO(3)$. Moreover, he announced the existence of such actions for the non-solvable groups $SL_2(\mathbb{F}_q)$ and $PSL_2(\mathbb{F}_q)$, where $q\geq 5$ is a power of an odd prime. | In 1946, Montgomery and Samelson made a comment \cite{Montgomery&Samelson1946} that when a compact group $G$ acts smoothly on a sphere in such a way as to have one fixed point, it is likely that there must be a second fixed point. In 1977, Stein \cite{Stein1977} has obtained for the first time a counterexample to this speculation. For $G=SL_2(\mathbb{F}_5)$ or $SL_2(\mathbb{F}_5)\times \mathbb{Z}_r$ with $(120, r)=1$, he constructed a smooth action of $G$ on the sphere $S^7$ with exactly one fixed point. Then Petrie \cite{Petrie1982} described smooth one fixed point actions on spheres in the case the acting group $G$ is a finite abelian group of odd order and with three or more non-cyclic Sylow subgroups, as well as for $G=S^3$ or $SO(3)$. Moreover, he announced the existence of such actions for the non-solvable groups $SL_2(\mathbb{F}_q)$ and $PSL_2(\mathbb{F}_q)$, where $q\geq 5$ is a power of an odd prime. | ||
</wikitex> | </wikitex> | ||
| − | == | + | ==== Results ==== |
<wikitex>; | <wikitex>; | ||
{{beginthm|Theorem|\cite{Laitinen&Morimoto&Pawalowski1995}}} | {{beginthm|Theorem|\cite{Laitinen&Morimoto&Pawalowski1995}}} | ||
For any finite non-solvable group $G$, there exists a smooth action of $G$ on some sphere with exactly one fixed point. | For any finite non-solvable group $G$, there exists a smooth action of $G$ on some sphere with exactly one fixed point. | ||
{{endthm}} | {{endthm}} | ||
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{{beginthm|Theorem|\cite{Laitinen&Morimoto1998}\label{thm:one_fixed_point}}} | {{beginthm|Theorem|\cite{Laitinen&Morimoto1998}\label{thm:one_fixed_point}}} | ||
| − | For any finite Oliver group $G$, there exists a smooth action of $G$ on some sphere with exactly one fixed point. | + | For any finite [[Group_actions_on_disks#Oliver_group|Oliver group]] $G$, there exists a smooth action of $G$ on some sphere with exactly one fixed point. |
{{endthm}} | {{endthm}} | ||
Assume that a compact Lie group $G$ acts smoothly on a sphere with exactly one fixed point $x$. Then, the Slice Theorem allows us to remove from the sphere an invariant open ball neighbourhood of $x$. As a result, we obtain a smooth fixed point free action of $G$ on a disk, and so, $G$ is an Oliver group. | Assume that a compact Lie group $G$ acts smoothly on a sphere with exactly one fixed point $x$. Then, the Slice Theorem allows us to remove from the sphere an invariant open ball neighbourhood of $x$. As a result, we obtain a smooth fixed point free action of $G$ on a disk, and so, $G$ is an Oliver group. | ||
| − | {{beginthm|Corollary | + | {{beginthm|Corollary\label{cor:one_fixed_point}}} |
| − | A finite group $G$ has a smooth one fixed point action on some sphere if and only if $G$ is an Oliver group. | + | A finite group $G$ has a smooth one fixed point action on some sphere if and only if $G$ is an [[Group actions on disks#Oliver group|Oliver group]]. |
{{endthm}} | {{endthm}} | ||
Except for the two cases $G=S^3$ or $SO(3)$ proved by Petrie, the question whether for any compact Oliver group $G$ of positive dimension, the conclusion of Theorem \ref{thm:one_fixed_point} remains true is open. | Except for the two cases $G=S^3$ or $SO(3)$ proved by Petrie, the question whether for any compact Oliver group $G$ of positive dimension, the conclusion of Theorem \ref{thm:one_fixed_point} remains true is open. | ||
</wikitex> | </wikitex> | ||
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| + | === Fixed point sets === | ||
== References == | == References == | ||
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[[Category:Theory]] | [[Category:Theory]] | ||
| − | [[Category: | + | [[Category:Group actions on manifolds]] |
Latest revision as of 14:59, 4 December 2010
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This page has not been refereed. The information given here might be incomplete or provisional. |
Contents |
[edit] 1 Topological actions
[edit] 2 Smooth actions
[edit] 2.1 Actions with exactly one fixed point
[edit] 2.1.1 History
In 1946, Montgomery and Samelson made a comment [Montgomery&Samelson1946] that when a compact group 
acts smoothly on a sphere in such a way as to have one fixed point, it is likely that there must be a second fixed point. In 1977, Stein [Stein1977] has obtained for the first time a counterexample to this speculation. For 
or 
with 
, he constructed a smooth action of on the sphere 
with exactly one fixed point. Then Petrie [Petrie1982] described smooth one fixed point actions on spheres in the case the acting group is a finite abelian group of odd order and with three or more non-cyclic Sylow subgroups, as well as for 
or 
. Moreover, he announced the existence of such actions for the non-solvable groups 
and 
, where 
is a power of an odd prime.
[edit] 2.1.2 Results
Theorem 2.1 [Laitinen&Morimoto&Pawalowski1995].
For any finite non-solvable group , there exists a smooth action of on some sphere with exactly one fixed point.
Theorem 2.2 [Laitinen&Morimoto1998].
For any finite Oliver group , there exists a smooth action of on some sphere with exactly one fixed point.
Assume that a compact Lie group acts smoothly on a sphere with exactly one fixed point 
. Then, the Slice Theorem allows us to remove from the sphere an invariant open ball neighbourhood of . As a result, we obtain a smooth fixed point free action of on a disk, and so, is an Oliver group.
Corollary 2.3.
A finite group has a smooth one fixed point action on some sphere if and only if is an Oliver group.
Except for the two cases or proved by Petrie, the question whether for any compact Oliver group of positive dimension, the conclusion of Theorem 2.2 remains true is open.
[edit] 2.2 Fixed point sets
[edit] 3 References
- [Laitinen&Morimoto&Pawalowski1995] E. Laitinen, M. Morimoto and K. Pawałowski, Deleting-inserting theorem for smooth actions of finite nonsolvable groups on spheres, Comment. Math. Helv. 70 (1995), no.1, 10–38. MR1314939 (96b:57043) Zbl 0843.57034
- [Laitinen&Morimoto1998] E. Laitinen and M. Morimoto, Finite groups with smooth one fixed point actions on spheres, Forum Math. 10 (1998), no.4, 479–520. MR1631012 (99k:57078) Zbl 0905.57023
- [Montgomery&Samelson1946] D. Montgomery and H. Samelson, Fiberings with singularities, Duke Math. J. 13 (1946), 51–56. MR0015794 (7,471a) Zbl 0060.41501
- [Petrie1982] T. Petrie, One fixed point actions on spheres. I, II, Adv. in Math. 46 (1982), no.1, 3–14, 15–70. MR676986 (84b:57027) Zbl 0502.57021
- [Stein1977] E. Stein, Surgery on products with finite fundamental group, Topology 16 (1977), no.4, 473–493. MR0474336 (57 #13982) Zbl 0383.57014
