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In | In [[mathematics]], '''Novikov's compact leaf theorem''', named after [[Sergei Novikov (mathematician)|Sergei Novikov]], states that | ||
: ''A codimension-one [[foliation]] of a compact 3-manifold whose [[universal covering space]] is not contractible must have a compact leaf.'' | |||
== Novikov's compact leaf theorem for ''S''<sup>3</sup> == | |||
Theorem: ''A smooth codimension-one foliation of the [[3-sphere]]'' ''S''<sup>3</sup> ''has a compact leaf. The leaf is a torus'' ''T''<sup>2</sup> ''bounding a [[solid torus]] with the [[Reeb foliation]].'' | |||
The theorem was proved by [[Sergei Novikov (mathematician)|Sergey Novikov]] in 1964. Earlier [[Charles Ehresmann]] had conjectured that every smooth codimension-one foliation on ''S''<sup>3</sup> had a compact leaf, which was true for all known examples; in particular, [[Reeb foliation]] had a compact leaf that was ''T''<sup>2</sup>. | |||
== Novikov's compact leaf theorem for any ''M''<sup>3</sup> == | |||
In 1965, Novikov proved the compact leaf theorem for any ''M''<sup>3</sup>: | |||
Theorem: ''Let'' ''M''<sup>3</sup> ''be a closed 3-manifold with a smooth codimension-one foliation'' ''F''. ''Suppose any of the following conditions is satisfied:'' | |||
# the ''[[fundamental group]] <math>\pi_1(M^3)</math> is finite,'' | |||
# the ''second [[homotopy group]] <math>\pi_2(M^3)\ne 0</math>,'' | |||
# ''there exists a leaf <math>L\in F</math> such that the map <math>\pi_1(L)\to\pi_1(M^3)</math> induced by inclusion has a non-trivial [[Kernel (algebra)|kernel]]. | |||
'' | |||
''Then'' ''F'' ''has a compact leaf of [[genus]]'' ''g'' ≤ 1. | |||
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In fact, except in case (2), where the closed leaf might be ''S''<sup>2</sup> or <math>RP^2</math>, in all other cases, the foliation contains a Reeb component. | |||
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In terms of covering spaces: | |||
''A codimension-one [[foliation]] of a compact 3-manifold whose [[universal covering space]] is not contractible must have a compact leaf. | |||
'' | |||
==References== | |||
* ''S. Novikov''. The topology of foliations//Trudy Moskov. Mat. Obshch, 1965, v. 14, p. 248–278.[http://www.mi.ras.ru/~snovikov/23.pdf] | |||
* ''I. Tamura''. Topology of foliations — AMS, v.97, 2006. | |||
* ''D. Sullivan'', Cycles for the dynamical study of foliated manifolds and complex manifolds, ''Invent. Math.'', '''36''' (1976), p. 225–255. [http://www.kryakin.com/files/Invent_mat_%282_8%29/36/36_08.pdf] | |||
[[Category:Foliations]] | |||
[[Category:Theorems in topology]] | |||
{{topology-stub}} | |||
Revision as of 11:11, 6 June 2013
In mathematics, Novikov's compact leaf theorem, named after Sergei Novikov, states that
- A codimension-one foliation of a compact 3-manifold whose universal covering space is not contractible must have a compact leaf.
Novikov's compact leaf theorem for S3
Theorem: A smooth codimension-one foliation of the 3-sphere S3 has a compact leaf. The leaf is a torus T2 bounding a solid torus with the Reeb foliation.
The theorem was proved by Sergey Novikov in 1964. Earlier Charles Ehresmann had conjectured that every smooth codimension-one foliation on S3 had a compact leaf, which was true for all known examples; in particular, Reeb foliation had a compact leaf that was T2.
Novikov's compact leaf theorem for any M3
In 1965, Novikov proved the compact leaf theorem for any M3:
Theorem: Let M3 be a closed 3-manifold with a smooth codimension-one foliation F. Suppose any of the following conditions is satisfied:
- the fundamental group is finite,
- the second homotopy group ,
- there exists a leaf such that the map induced by inclusion has a non-trivial kernel.
Then F has a compact leaf of genus g ≤ 1.
In terms of covering spaces:
A codimension-one foliation of a compact 3-manifold whose universal covering space is not contractible must have a compact leaf.