Free factor complex

In mathematics, the free factor complex (sometimes also called the complex of free factors) is a free group counterpart of the notion of the curve complex of a finite type surface. The free factor complex was originally introduced in a 1998 paper of Allen Hatcher and Karen Vogtmann.^[1] Like the curve complex, the free factor complex is known to be Gromov-hyperbolic. The free factor complex plays a significant role in the study of large-scale geometry of ${\displaystyle \mathrm{Out}(Fn)}$.

For a free group ${\displaystyle G}$ a proper free factor of ${\displaystyle G}$ is a subgroup ${\displaystyle A\le G}$ such that ${\displaystyle A\ne \{1\},A\ne G}$ and that there exists a subgroup ${\displaystyle B\le G}$ such that ${\displaystyle G=A\ast B}$.

Let ${\displaystyle n\ge 3}$ be an integer and let ${\displaystyle F_n}$ be the free group of rank ${\displaystyle n}$. The free factor complex ${\displaystyle {{ℱ}}_n}$ for ${\displaystyle F_n}$ is a simplicial complex where:

(1) The 0-cells are the conjugacy classes in ${\displaystyle F_n}$ of proper free factors of ${\displaystyle F_n}$, that is

${\displaystyle {{ℱ}}_n^{(0)}=\{[A]|A\le F_n\text{ is a proper free factor of }{F}_n\}.}$

(2) For ${\displaystyle k\ge 1}$, a ${\displaystyle k}$-simplex in ${\displaystyle {{ℱ}}_n}$ is a collection of ${\displaystyle k+1}$ distinct 0-cells ${\displaystyle \{v_0,v_1,\dots ,v_k\}\subset {{ℱ}}_n^{(0)}}$ such that there exist free factors ${\displaystyle A_0,A_1,\dots ,A_k}$ of ${\displaystyle F_n}$ such that ${\displaystyle v_i=A_i}$ for ${\displaystyle i=0,1,\dots ,k}$, and that ${\displaystyle A_0\le A_1\le \dots \le A_k}$. [The assumption that these 0-cells are distinct implies that ${\displaystyle A_i\ne A_{i+1}}$ for ${\displaystyle i=0,1,\dots ,k-1}$]. In particular, a 1-cell is a collection ${\displaystyle \{[A],[B]\}}$ of two distinct 0-cells where ${\displaystyle A,B\le F_n}$ are proper free factors of ${\displaystyle F_n}$ such that ${\displaystyle A⪇B}$.

For ${\displaystyle n=2}$ the above definition produces a complex with no ${\displaystyle k}$-cells of dimension ${\displaystyle k\ge 1}$. Therefore, ${\displaystyle {{ℱ}}_2}$ is defined slightly differently. One still defines ${\displaystyle {{ℱ}}_2^{(0)}}$ to be the set of conjugacy classes of proper free factors of ${\displaystyle F_2}$; (such free factors are necessarily infinite cyclic). Two distinct 0-simplices ${\displaystyle \{v_0,v_1\}\subset {{ℱ}}_2^{(0)}}$ determine a 1-simplex in ${\displaystyle {{ℱ}}_2}$ if and only if there exists a free basis ${\displaystyle a,b}$ of ${\displaystyle F_2}$ such that ${\displaystyle v_0=[⟨a⟩],v_1=[⟨b⟩]}$. The complex ${\displaystyle {{ℱ}}_2}$ has no ${\displaystyle k}$-cells of dimension ${\displaystyle k\ge 2}$.

For ${\displaystyle n\ge 2}$ the 1-skeleton ${\displaystyle {{ℱ}}_n^{(1)}}$ is called the free factor graph for ${\displaystyle F_n}$.

• For every integer ${\displaystyle n\ge 3}$ the complex ${\displaystyle {{ℱ}}_n}$ is connected, locally infinite, and has dimension ${\displaystyle n-2}$. The complex ${\displaystyle {{ℱ}}_2}$ is connected, locally infinite, and has dimension 1.
• For ${\displaystyle n=2}$, the graph ${\displaystyle {{ℱ}}_2}$ is isomorphic to the Farey graph.
• There is a natural action of ${\displaystyle \mathrm{Out}(Fn)}$ on ${\displaystyle {{ℱ}}_n}$ by simplicial automorphisms. For a k-simplex ${\displaystyle \mathrm{\Delta }=\{[A_0],\dots ,[A_k]\}}$ and ${\displaystyle \phi \in \mathrm{Out}(F_n)}$ one has ${\displaystyle \phi \mathrm{\Delta }:=\{[\phi (A_0)],\dots ,[\phi (A_k)]\}}$.
• For ${\displaystyle n\ge 3}$ the complex ${\displaystyle {{ℱ}}_n}$ has the homotopy type of a wedge of spheres of dimension ${\displaystyle n-2}$.^[1]
• For every integer ${\displaystyle n\ge 2}$, the free factor graph ${\displaystyle {{ℱ}}_n^{(1)}}$, equipped with the simplicial metric (where every edge has length 1), is a connected graph of infinite diameter.^[2][3]
• For every integer ${\displaystyle n\ge 2}$, the free factor graph ${\displaystyle {{ℱ}}_n^{(1)}}$, equipped with the simplicial metric, is Gromov-hyperbolic. This result was originally established by Mladen Bestvina and Mark Feighn;^[4] see also ^[5][6] for subsequent alternative proofs.
• An element ${\displaystyle \phi \in \mathrm{Out}(F_n)}$ acts as a loxodromic isometry of ${\displaystyle {{ℱ}}_n^{(1)}}$ if and only if ${\displaystyle \phi }$ is fully irreducible.^[4]
• There exists a coarsely Lipschitz coarsely ${\displaystyle \mathrm{Out}(F_n)}$-equivariant coarsely surjective map ${\displaystyle {{ℱ}{𝒮}}_n\to {{ℱ}}_n^{(1)}}$, where ${\displaystyle {{ℱ}{𝒮}}_n}$ is the free splittings complex. However, this map is not a quasi-isometry. The free splitting complex is also known to be Gromov-hyperbolic, as was proved by Handel and Mosher.^[7]
• Similarly, there exists a natural coarsely Lipschitz coarsely ${\displaystyle \mathrm{Out}(F_n)}$-equivariant coarsely surjective map ${\displaystyle C{V}_n\to {{ℱ}}_n^{(1)}}$, where ${\displaystyle C{V}_n}$ is the (volume-ones normalized) Culler–Vogtmann Outer space, equipped with the symmetric Lipschitz metric. The map ${\displaystyle \pi }$ takes a geodesic path in ${\displaystyle C{V}_n}$ to a path in ${\displaystyle {ℱ}{F}_n}$ contained in a uniform Hausdorff neighborhood of the geodesic with the same endpoints.^[4]
• The hyperbolic boundary ${\displaystyle \partial {{ℱ}}_n^{(1)}}$ of the free factor graph can be identified with the set of equivalence classes of "arational" ${\displaystyle F_n}$-trees in the boundary ${\displaystyle \partial C{V}_n}$ of the Outer space ${\displaystyle C{V}_n}$.^[8]
• The free factor complex is a key tool in studying the behavior of random walks on ${\displaystyle \mathrm{Out}(F_n)}$ and in identifying the Poisson boundary of ${\displaystyle \mathrm{Out}(F_n)}$.^[9]

There are several other models which produce graphs coarsely ${\displaystyle \mathrm{Out}(Fn)}$-equivariantly quasi-isometric to ${\displaystyle {{ℱ}}_n^{(1)}}$. These models include:

• The graph whose vertex set is ${\displaystyle {{ℱ}}_n^0}$ and where two distinct vertices ${\displaystyle v_0,v_1}$ are adjacent if and only if there exists a free product decomposition ${\displaystyle F_n=A\ast B\ast C}$ such that ${\displaystyle v_0=[A]}$ and ${\displaystyle v_1=[B]}$.
• The free bases graph whose vertex set is the set of ${\displaystyle F_n}$-conjugacy classes of free bases of ${\displaystyle F_n}$, and where two vertices ${\displaystyle v_0,v_1}$ are adjacent if and only if there exist free bases ${\displaystyle {𝒜},{ℬ}}$ of ${\displaystyle F_n}$ such that ${\displaystyle v_0=[{𝒜}],v_1=[{ℬ}]}$ and ${\displaystyle {𝒜}\cap {ℬ}\ne \varnothing }$.^[5]

• Mapping class group

0.00 (0 votes) Original source: https://en.wikipedia.org/wiki/Free factor complex. Read more