Reeb sphere theorem explained

In mathematics, Reeb sphere theorem, named after Georges Reeb, states that

A closed oriented connected manifold Mⁿ that admits a singular foliation having only centers is homeomorphic to the sphere Sⁿ and the foliation has exactly two singularities.

Morse foliation

A singularity of a foliation F is of Morse type if in its small neighborhood all leaves of the foliation are level sets of a Morse function, being the singularity a critical point of the function. The singularity is a center if it is a local extremum of the function; otherwise, the singularity is a saddle.

The number of centers c and the number of saddles

, specifically

c-s

, is tightly connected with the manifold topology.

We denote

\operatorname{ind}p=min(k,n-k)

, the index of a singularity

, where k is the index of the corresponding critical point of a Morse function. In particular, a center has index 0, index of a saddle is at least 1.

A Morse foliation F on a manifold M is a singular transversely oriented codimension one foliation of class

C²

with isolated singularities such that:

each singularity of F is of Morse type,
each singular leaf L contains a unique singularity p; in addition, if

\operatorname{ind}p=1

then

L\setminusp

is not connected.

Reeb sphere theorem

This is the case

c>s=0

, the case without saddles.

Theorem:^[1] Let

Mⁿ

be a closed oriented connected manifold of dimension

n\ge2

. Assume that

Mⁿ

admits a

C¹

-transversely oriented codimension one foliation

with a non empty set of singularities all of them centers. Then the singular set of

consists of two points and

Mⁿ

is homeomorphic to the sphere

Sⁿ

It is a consequence of the Reeb stability theorem.

Generalization

More general case is

c>s\ge0.

In 1978, Edward Wagneur generalized the Reeb sphere theorem to Morse foliations with saddles. He showed that the number of centers cannot be too much as compared with the number of saddles, notably,

c\les+2

. So there are exactly two cases when

c>s

(1)

c=s+2,

(2)

c=s+1.

He obtained a description of the manifold admitting a foliation with singularities that satisfy (1).

Theorem:^[2] Let

Mⁿ

be a compact connected manifold admitting a Morse foliation

with

centers and

saddles. Then

c\les+2

. In case

c=s+2

is homeomorphic to

Sⁿ

all saddles have index 1,
each regular leaf is diffeomorphic to

S^n-1

Finally, in 2008, César Camacho and Bruno Scardua considered the case (2),

c=s+1

. This is possible in a small number of low dimensions.

Theorem:^[3] Let

Mⁿ

be a compact connected manifold and

a Morse foliation on

. If

s=c+1

, then

n=2,4,8

Mⁿ

is an Eells–Kuiper manifold.

References

External links

Reeb sphere theorem on nLab