Margulis lemma explained

In differential geometry, the Margulis lemma (named after Grigory Margulis) is a result about discrete subgroups of isometries of a non-positively curved Riemannian manifold (e.g. the hyperbolic n-space). Roughly, it states that within a fixed radius, usually called the Margulis constant, the structure of the orbits of such a group cannot be too complicated. More precisely, within this radius around a point all points in its orbit are in fact in the orbit of a nilpotent subgroup (in fact a bounded finite number of such).

The Margulis lemma for manifolds of non-positive curvature

Formal statement

The Margulis lemma can be formulated as follows.

Let

be a simply-connected manifold of non-positive bounded sectional curvature. There exist constants

C,\varepsilon>0

with the following property. For any discrete subgroup

\Gamma

of the group of isometries of

and any

x\inX

, if

F_x

is the set:

F_x=\{g\in\Gamma:d(x,gx)<\varepsilon\}

then the subgroup generated by

F_x

contains a nilpotent subgroup of index less than

. Here

is the distance induced by the Riemannian metric.

An immediately equivalent statement can be given as follows: for any subset

of the isometry group, if it satisfies that:

there exists a

x\inX

such that

\forallg\inF:d(x,gx)<\varepsilon

;

the group

\langleF\rangle

generated by

is discretethen

\langleF\rangle

contains a nilpotent subgroup of index

\leC

Margulis constants

The optimal constant

\varepsilon

in the statement can be made to depend only on the dimension and the lower bound on the curvature; usually it is normalised so that the curvature is between -1 and 0. It is usually called the Margulis constant of the dimension.

One can also consider Margulis constants for specific spaces. For example, there has been an important effort to determine the Margulis constant of the hyperbolic spaces (of constant curvature -1). For example:

the optimal constant for the hyperbolic plane is equal to

2\operatorname{arsinh}\left(\sqrt{

	2\cos(2\pi/7)-1
	8\cos(\pi/7)+7

} \right) \simeq 0.2629 ;^[1]

In general the Margulis constant

\varepsilon_n

for the hyperbolic

-space is known to satisfy the bounds:

c^ < \varepsilon_n < K/\sqrt n

for some

0<c<1,K>0

.^[2]

Zassenhaus neighbourhoods

A particularly studied family of examples of negatively curved manifolds are given by the symmetric spaces associated to semisimple Lie groups. In this case the Margulis lemma can be given the following, more algebraic formulation which dates back to Hans Zassenhaus.

is a semisimple Lie group there exists a neighbourhood

\Omega

of the identity in

and a

C>0

such that any discrete subgroup

\Gamma

which is generated by

\Gamma\cap\Omega

contains a nilpotent subgroup of index

\leC

Such a neighbourhood

\Omega

is called a Zassenhaus neighbourhood in

. If

is compact this theorem amounts to Jordan's theorem on finite linear groups.

Thick-thin decomposition

Let

be a Riemannian manifold and

\varepsilon>0

. The thin part of

is the subset of points

x\inM

where the injectivity radius of

is less than

\varepsilon

, usually denoted

M_<

, and the thick part its complement, usually denoted

M_\ge

. There is a tautological decomposition into a disjoint union

M=M_<\cupM_\ge

When

is of negative curvature and

\varepsilon

is smaller than the Margulis constant for the universal cover

\widetildeM</Math>,thestructureofthecomponentsofthethinpartisverysimple.Letusrestricttothecaseofhyperbolicmanifoldsoffinitevolume.Supposethat<math>\varepsilon

is smaller than the Margulis constant for

Hⁿ

and let

be a hyperbolic

-manifold of finite volume. Then its thin part has two sorts of components:

Cusps

these are the unbounded components, they are diffeomorphic to a flat

(n-1)

-manifold times a line;

Margulis tubes: these are neighbourhoods of closed geodesics of length

<\varepsilon

. They are bounded and (if

is orientable) diffeomorphic to a circle times a

(n-1)

-disc.

In particular, a complete finite-volume hyperbolic manifold is always diffeomorphic to the interior of a compact manifold (possibly with empty boundary).

Other applications

The Margulis lemma is an important tool in the study of manifolds of negative curvature. Besides the thick-thin decomposition some other applications are:

The collar lemma: this is a more precise version of the description of the compact components of the thin parts. It states that any closed geodesic of length

\ell<\varepsilon

on an hyperbolic surface is contained in an embedded cylinder of diameter of order

\ell^-1

The Margulis lemma gives an immediate qualitative solution to the problem of minimal covolume among hyperbolic manifolds: since the volume of a Margulis tube can be seen to be bounded below by a constant depending only on the dimension, it follows that there exists a positive infimum to the volumes of hyperbolic n-manifolds for any n.
The existence of Zassenhaus neighbourhoods is a key ingredient in the proof of the Kazhdan–Margulis theorem.
One can recover the Jordan–Schur theorem as a corollary to the existence of Zassenhaus neighbourhoods.

References

Book: Ballmann . Werner . Gromov . Mikhail . Schroeder . Viktor . Manifolds of Nonpositive Curvature . Birkhâuser . 1985.
Book: Raghunathan, M. S. . Discrete subgroups of Lie groups . . Ergebnisse de Mathematik und ihrer Grenzgebiete . 1972 . 0507234.
Book: Ratcliffe, John . Foundations of hyperbolic manifolds, Second edition . Springer . 2006 . xii+779 . 978-0387-33197-3.
Book: Thurston, William . Three-dimensional geometry and topology. Vol. 1 . Princeton University Press . 1997.

Notes and References

Yamada . A. . On Marden's universal constant of Fuchsian groups . Kodai Math. J. . 4 . 1981 . 2 . 266–277. 10.2996/kmj/1138036373 .
Book: Belolipetsky, Mikhail . Hyperbolic orbifolds of small volume . Proceedings of ICM 2014 . 2014 . Kyung Moon SA . 1402.5394 .

Margulis lemma explained

The Margulis lemma for manifolds of non-positive curvature

Formal statement

Margulis constants

Zassenhaus neighbourhoods

Thick-thin decomposition

Other applications

See also

References

Notes and References