Fully irreducible automorphism explained

In the mathematical subject geometric group theory, a fully irreducible automorphism of the free group F_n is an element of Out(F_n) which has no periodic conjugacy classes of proper free factors in F_n (where n > 1). Fully irreducible automorphisms are also referred to as "irreducible with irreducible powers" or "iwip" automorphisms. The notion of being fully irreducible provides a key Out(F_n) counterpart of the notion of a pseudo-Anosov element of the mapping class group of a finite type surface. Fully irreducibles play an important role in the study of structural properties of individual elements and of subgroups of Out(F_n).

Formal definition

Let

\varphi\in\operatorname{Out}(F_n)

where

n\ge2

. Then

\varphi

is called fully irreducible^[1] if there do not exist an integer

p\ne0

and a proper free factor

F_n

such that

\varphi^p([A])=[A]

, where

[A]

is the conjugacy class of

F_n

. Here saying that

is a proper free factor of

F_n

means that

A\ne1

and there exists a subgroup

B\leF_n,B\ne1

such that

F_n=A\astB

Also,

\Phi\in\operatorname{Aut}(F_n)

is called fully irreducible if the outer automorphism class

\varphi\in\operatorname{Out}(F_n)

\Phi

is fully irreducible.

Two fully irreducibles

\varphi,\psi\in\operatorname{Out}(F_n)

are called independent if

\langle\varphi\rangle\cap\langle\psi\rangle=\{1\}

Relationship to irreducible automorphisms

The notion of being fully irreducible grew out of an older notion of an "irreducible" outer automorphism of

F_n

originally introduced in. An element

\varphi\in\operatorname{Out}(F_n)

, where

n\ge2

, is called irreducible if there does not exist a free product decomposition

F_n=A_1\ast...\astA_k\astC

with

k\ge1

, and with

A_i\ne1,i=1,...k

being proper free factors of

F_n

, such that

\varphi

permutes the conjugacy classes

[A_1],...,[A_k]

Then

\varphi\in\operatorname{Out}(F_n)

is fully irreducible in the sense of the definition above if and only if for every

p\ne0

\varphi^p

is irreducible.

It is known that for any atoroidal

\varphi\in\operatorname{Out}(F_n)

(that is, without periodic conjugacy classes of nontrivial elements of

F_n

), being irreducible is equivalent to being fully irreducible.^[2] For non-atoroidal automorphisms, Bestvina and Handel produce an example of an irreducible but not fully irreducible element of

\operatorname{Out}(F_n)

, induced by a suitably chosen pseudo-Anosov homeomorphism of a surface with more than one boundary component.

Properties

\varphi\in\operatorname{Out}(F_n)

and

p\ne0

then

\varphi

is fully irreducible if and only if

\varphi^p

is fully irreducible.

Every fully irreducible

\varphi\in\operatorname{Out}(F_n)

can be represented by an expanding irreducible train track map.^[3]

Every fully irreducible

\varphi\in\operatorname{Out}(F_n)

has exponential growth in

F_n

given by a stretch factor

λ=λ(\varphi)>1

. This stretch factor has the property that for every free basis

F_n

(and, more generally, for every point of the Culler–Vogtmann Outer space

X\incv_n

) and for every

1\neg\inF_n

one has:

\lim_k\toinfty

	k(g)\\|
\sqrt[k]{\\|\varphi
	X}=λ.

Moreover,

λ=λ(\varphi)

is equal to the Perron–Frobenius eigenvalue of the transition matrix of any train track representative of

\varphi

.^[3] ^[4]

Unlike for stretch factors of pseudo-Anosov surface homeomorphisms, it can happen that for a fully irreducible

\varphi\in\operatorname{Out}(F_n)

one has

λ(\varphi)\neλ(\varphi^-1)

^[5] and this behavior is believed to be generic. However, Handel and Mosher^[6] proved that for every

n\ge2

there exists a finite constant

0<C_n<infty

such that for every fully irreducible

\varphi\in\operatorname{Out}(F_n)

	logλ(\varphi)
	logλ(\varphi^-1)

\leC_n.

A fully irreducible

\varphi\in\operatorname{Out}(F_n)

is non-atoroidal, that is, has a periodic conjugacy class of a nontrivial element of

F_n

, if and only if

\varphi

is induced by a pseudo-Anosov homeomorphism of a compact connected surface with one boundary component and with the fundamental group isomorphic to

F_n

.^[3]

A fully irreducible element

\varphi\in\operatorname{Out}(F_n)

has exactly two fixed points in the Thurston compactification

\overline{CV}_n

of the projectivized Outer space

CV_n

, and

\varphi\in\operatorname{Out}(F_n)

acts on

\overline{CV}_n

with "North-South" dynamics.

For a fully irreducible element

\varphi\in\operatorname{Out}(F_n)

, its fixed points in

\overline{CV}_n

are projectivized

-trees

[T_+(\varphi)],[T_-(\varphi)]

, where

T_+(\varphi),T_{-(\varphi)\in}\overline{cv}_n

, satisfying the property that

T_{+(\varphi)\varphi=λ(\varphi)}T_+(\varphi)

and

	-1
T
	-(\varphi)\varphi

=λ(\varphi^-1)T_-(\varphi)

A fully irreducible element

\varphi\in\operatorname{Out}(F_n)

acts on the space of projectivized geodesic currents

PCurr(F_n)

with either "North-South" or "generalized North-South" dynamics, depending on whether

\varphi

is atoroidal or non-atoroidal.^[7] ^[8]

\varphi\in\operatorname{Out}(F_n)

is fully irreducible, then the commensurator

Comm(\langle\varphi\rangle)\le\operatorname{Out}(F_n)

is virtually cyclic.^[9] In particular, the centralizer and the normalizer of

\langle\varphi\rangle

\operatorname{Out}(F_n)

are virtually cyclic.

\varphi,\psi\in\operatorname{Out}(F_n)

are independent fully irreducibles, then

[T_{\pm(\varphi)],}[T_{\pm(\psi)]\in}\overline{CV}_n

are four distinct points, and there exists

M\ge1

such that for every

p,q\geM

the subgroup

\langle\varphi^p,\psi^q\rangle\le\operatorname{Out}(F_n)

is isomorphic to

F₂

\varphi\in\operatorname{Out}(F_n)

is fully irreducible and

\varphi\inH\le\operatorname{Out}(F_n)

, then either

is virtually cyclic or

contains a subgroup isomorphic to

F₂

.^[10] [This statement provides a strong form of the [[Tits alternative]] for subgroups of

\operatorname{Out}(F_n)

containing fully irreducibles.]

H\le\operatorname{Out}(F_n)

is an arbitrary subgroup, then either

contains a fully irreducible element, or there exist a finite index subgroup

H_0\leH

and a proper free factor

F_n

such that

H_0[A]=[A]

.^[11]

An element

\varphi\in\operatorname{Out}(F_n)

acts as a loxodromic isometry on the free factor complex

l{FF}_n

if and only if

\varphi

is fully irreducible.^[12]

It is known that "random" (in the sense of random walks) elements of

\operatorname{Out}(F_n)

are fully irreducible. More precisely, if

\mu

is a measure on

\operatorname{Out}(F_n)

whose support generates a semigroup in

\operatorname{Out}(F_n)

containing some two independent fully irreducibles. Then for the random walk of length

\operatorname{Out}(F_n)

determined by

\mu

, the probability that we obtain a fully irreducible element converges to 1 as

k\toinfty

.^[13]

A fully irreducible element

\varphi\in\operatorname{Out}(F_n)

admits a (generally non-unique) periodic axis in the volume-one normalized Outer space

X_n

, which is geodesic with respect to the asymmetric Lipschitz metric on

X_n

and possesses strong "contraction"-type properties.^[14] A related object, defined for an atoroidal fully irreducible

\varphi\in\operatorname{Out}(F_n)

, is the axis bundle

A_{\varphi\subseteq}X_n

, which is a certain

\varphi

-invariant closed subset proper homotopy equivalent to a line.^[15]

Notes and References

Thierry Coulbois and Arnaud Hilion, Botany of irreducible automorphisms of free groups, Pacific Journal of Mathematics 256 (2012), 291–307
Ilya Kapovich, Algorithmic detectability of iwip automorphisms. Bulletin of the London Mathematical Society 46 (2014), no. 2, 279–290.
Mladen Bestvina, and Michael Handel, Train tracks and automorphisms of free groups. Annals of Mathematics (2), vol. 135 (1992), no. 1, pp. 1 - 51
Oleg Bogopolski. Introduction to group theory. EMS Textbooks in Mathematics. European Mathematical Society, Zürich, 2008.
Michael Handel, and Lee Mosher, Parageometric outer automorphisms of free groups. Transactions of the American Mathematical Society 359 (2007), no. 7, 3153–3183
Michael Handel, Lee Mosher, The expansion factors of an outer automorphism and its inverse. Transactions of the American Mathematical Society 359 (2007), no. 7, 3185–3208
Caglar Uyanik, Dynamics of hyperbolic iwips. Conformal Geometry and Dynamics 18 (2014), 192–216.
Caglar Uyanik, Generalized north-south dynamics on the space of geodesic currents. Geometriae Dedicata 177 (2015), 129–148.
Ilya Kapovich, and Martin Lustig, Stabilizers of
R

-trees with free isometric actions of F_N. Journal of Group Theory 14 (2011), no. 5, 673–694.
Mladen Bestvina, Mark Feighn and Michael Handel, Laminations, trees, and irreducible automorphisms of free groups. Geometric and Functional Analysis 7 (1997), 215–244.
Camille Horbez, A short proof of Handel and Mosher's alternative for subgroups of Out(F_N). Groups, Geometry, and Dynamics 10 (2016), no. 2, 709–721.
Mladen Bestvina, and Mark Feighn, Hyperbolicity of the complex of free factors. Advances in Mathematics 256 (2014), 104–155.
Joseph Maher and Giulio Tiozzo, Random walks on weakly hyperbolic groups, Journal für die reine und angewandte Mathematik, Ahead of print (Jan 2016); c.f. Theorem 1.4
Yael Algom-Kfir,Strongly contracting geodesics in outer space. Geometry & Topology 15 (2011), no. 4, 2181–2233.
Michael Handel, and Lee Mosher,Axes in outer space. Memoirs of the American Mathematical Society 213 (2011), no. 1004; .

Fully irreducible automorphism explained

Formal definition

Relationship to irreducible automorphisms

Properties

Further reading

Notes and References