Categories: Discrete groups | Lie groups | Automorphic forms

Kleinian group

In mathematics, a Kleinian group is a finitely generated discrete group Γ of conformal (i.e. angle-preserving) self-maps of the open unit ball $B 3$ in $R 3$ .

By considering the ball's boundary, a Kleinian group can also be defined as a subgroup Γ of PGL₂(C), the complex projective linear group, whose action by Möbius transformations at some point of the Riemann sphere is freely discontinuous.

When Γ is isomorphic to the fundamental group $π 1$ of a three-dimensional hyperbolic manifold, then the quotient space $H 3 / Γ$ becomes a Kleinian model of the manifold. Many authors use the terms Kleinian model and Kleinian group interchangeably, letting the one stand for the other.

Discreteness implies points in $B 3$ have finite stabilizers, and discrete orbits under the group $G$ . But the orbit $G p$ of a point $p$ will typically accumulate on the boundary of the closed ball $\bar{B}^3$ .

The boundary of the closed ball is called the sphere at infinity, and is denoted $S^2_\infty$ . The set of accumulation points of Gp in $S^2_\infty$ is called the limit set of $G$ , and usually denoted $Λ(G)$ .

The unit ball $B 3$ with its conformal structure is the Poincare model of hyperbolic 3-space. When we think of it metrically, it is denoted $H 3$ . The set of conformal self-maps of $B 3$ becomes the set of isometries (i.e. distance-preserving maps) of $H 3$ under this identification. Such maps restrict to conformal self-maps of $S^2_\infty$ , which are Mobius transformations. There are isomorphisms

$Mob(S^2_\infty) \cong Conf(B^3) \cong Isom(H^3)$

The subgroups of these groups consisting of orientation-preserving transformations are all isomorphic to the matrix group

P S L (2, C)

via the usual identification of the unit sphere with the complex projective line $C P 1$ .

1 Metric
2 References

Contents

1 Example

2 Example

Example

Reflection groups . Let $C i$ be the boundary circles of a finite collection of disjoint closed disks. The group generated by inversion in each circle is a Kleinian group. The limit set is a Cantor set, and the quotient $H 3 / G$ is a mirror orbifold with underlying space a ball. It is double covered by a handlebody; the corresponding index 2 subgroup is a Schottky group .

Example

Crystallographic groups. Let $T$ be a periodic tessellation of hyperbolic 3-space. The group of symmetries of the tessellation is a Kleinian group.

Metric

The canonical hyperbolic metric on the unit ball $B 3$ is given by

$ds^2= \frac{4 \left| dx \right|^2 }{\left( 1-|x|^2 \right)^2}$

for $x\in B^3$ .

References

Bernard Maskit, Kleinian Groups, (1988) Springer-Verlag New York ISBN 0-387-17746-9
Katsuhiko Matsuzaki and Masahiko Taniguchi, Hyberbolic Manifolds and Kleinian Groups, (1998) Clarendon Press, Oxford ISBN 0-19-850062-9

Categories: Discrete groups | Lie groups | Automorphic forms

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Kleinian group

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Example

Metric

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