2.1 Group actions

A 3-manifold is a topological space each point of which has a neighborhood homeomorphic to an open subset of $\mathbb R^3$ .

A (topological) action $\Gamma \curvearrowright M$ of a group $\Gamma $ on a topological space M is a homomorphism from $\Gamma $ into the group of homeomorphisms of M. Given such an action, the images of a point $x\in M$ under $\Gamma \curvearrowright M$ form the orbit of x.

An action $\Gamma \curvearrowright M$ is faithful, if for every two distinct $g,h \in \Gamma $ there exists an $x \in M$ such that $gx \neq hx$ ; or equivalently, if for each $g \neq e \in \Gamma $ there exists an $x \in M$ such that $gx \neq x$ . It is free if $gx \neq hx$ for every $g,h\in \Gamma $ and $x\in M$ . It is transitive if for every $x,y\in M$ there is $g\in \Gamma $ with $gx =y$ (we will only encounter transitive actions on discrete spaces M). Finally, $\Gamma \curvearrowright M$ is regular if it is free and transitive.

An action $\Gamma \curvearrowright M$ is properly discontinuous, if for every compact subspace K of M, the set $\{g\in \Gamma \mid g K \cap K \neq \emptyset \}$ is finite. It is cocompact, if the quotient space $M/\Gamma $ is compact. If M is locally compact, then an equivalent condition is that there is a compact subset K of M such that $\bigcup \Gamma K =M$ .

2.2 Graphs

A (simple) graph G is a pair $(V,E)$ of sets, where V is called the set of vertices, and E is a set of two-element subsets of V, called the set of edges. We will write $uv$ instead of $\{u,v\}$ to denote an edge. A multigraph is defined similarly, except that E is a multiset, and it can have elements consisting of just one vertex.

We let $V(G)$ denote the set of vertices of a graph G, and $E(G)$ denote the set of edges of G.

Every (multi-)graph $G\ =(V,E)$ gives rise to a $1$ -complex, by letting V be the set of 0-cells, and for each $uv\in E$ introducing an arc with its endpoints identified with u and v. Thus, we will sometimes interpret the word graph as a 1-complex. In particular, when discussing embeddings of graphs we will mean topological embeddings of 1-complexes.

A generalized Cayley graph of a group $\Gamma $ is a graph G endowed with an action $\Gamma \curvearrowright G$ by isomorphisms which action is regular on $V(G)$ . This is analogous to our definition of a generalized Cayley complex in the introduction. Again the difference to the standard notion of a Cayley graph is that we allow the action to fix edges.

2.3 2-complexes

A $2$ -complex is a topological space X obtained as follows. We start with a $1$ -complex $X^1$ as defined above, called the 1-skeleton of X. We then introduce a set $X^2$ of copies of the closed unit disc $\mathbb {D} \subseteq \mathbb R^2$ , called the 2-cells or faces of X, and for each $f\in X^2$ we attach f to $X^1$ via a map $\phi _f: \mathbb S^1 \to X^1$ , called the attachment map, where we think of $\mathbb S^1$ as the boundary of $\mathbb {D}$ . Attaching here means that we consider the quotient space where each point x of $\mathbb S^1\subset f$ is identified with $\phi _f(x)$ . We let $X^0:= V(X^1)$ be the set of vertices, or 0-cells, of X.

We say that X is regular, if $\phi _f$ is a homeomorphism onto its image for every $f\in X^2$ . We say that X is edge-regular, if each $\phi _f$ is injective on 1-cells, that is, $x\in X^0$ holds for every point $x\in X$ with more than one preimage under $\phi _f$ .

For $f\in X^2$ , we write $f =[x_1,\dots , x_k]$ if $x_1,\dots , x_k$ is the cyclic sequence of vertices appearing in the image of $\phi _f$ .

To each 2-cell $f=[x_1,\dots , x_k] \in X^2$ , we associate two distinct directed 2-cells $f_1,f_2$ , also denoted by $\langle x_1,\dots , x_k\rangle $ and $\langle x_k,\dots , x_1\rangle ,$ respectively. Their reverses are defined as $f_1^{-1}:= f_2$ and $f_2^{-1}:= f_1$ .

If X is not regular, then it is always possible to produce a regular complex $X'$ homeomorphic to X using the barycentric subdivision defined as follows. For each edge $e=uv\in X^1$ , we subdivide e by adding a new vertex m at its midpoint. For each occurrence of e in a 2-cell f of X, we replace that occurrence by the pair $um, mv$ or $vm, mu$ as appropriate. We then triangulate each 2-cell $h=x_1,\ldots ,x_k$ of the resulting $2$ -complex by adding a new vertex c in its interior, adding the edges $c x_1,\ldots , cx_k$ to the 1-skeleton, and replacing h by the 2-cells $[c, x_1, x_2], [c, x_2, x_3], \ldots , [c,x_k, x_1]$ .

Note that the barycentric subdivision $X'$ of X is a simplicial complex, in particular a regular one, and its 1-skeleton is a simple graph. Here, a 2-complex X is simplicial, if its 1-skeleton is a simple graph and each $F\in X^2$ is of the form $f=[x_1, x_2, x_3]$ where $x_1,x_2,x_3$ are distinct vertices.

For each $v\in X^0$ , the link graph $L_X(v)$ is the graph on the neighborhood of v in $X^1$ with $uw \in E(L_X(v))$ if and only if $u,v,w$ are consecutive in a 2-cell of X. Alternatively, we can define $L_X(v)$ so that its vertices are the edges incident with v, and two edges $vu,vw$ are joined by an edge of $L_X(v)$ whenever $u,v,w$ are consecutive in a 2-cell of X. These two definitions yield isomorphic graphs when $X^1$ is a simple graph, and it is a matter of convenience to use the one or the other. In general, link graphs are more naturally defined as multigraphs, as $u,v,w$ may be consecutive in more than one 2-cells of X.

2.4 Embeddings and Chambers

An embedding of a space X in a space Y is homeomorphism between X and a subspace of Y.

For an embedding $\phi :X\rightarrow M$ of a $2$ -complex X into a 3-manifold M, we call each connected component of $M \setminus \phi (X)$ a chamber. The boundary $\partial C$ of a chamber C is the set of points $x \in \phi (X)$ in the closure of C that are not in the interior of C. Indeed, as C is an open set, $\partial C$ is disjoint from C. The following basic fact helps to further explain the notion.

2.5 Local flatness

We recall the standard notion of local flatness. An embedding $\phi : \mathbb S^2 \to M$ , where M is a 3-manifold, is locally flat, if for each $x\in \phi (\mathbb S^2)$ there exists a neighborhood $U_x$ of x such that the topological pair $(U_x,U_x\cap \phi (X))$ is homeomorphic to $(\mathbb {R}^3, \mathbb {R}^2)$ , by which we mean that there is a homeomorphism from $U_x$ to $\mathbb {R}^3$ mapping $U_x\cap \phi (X)$ to $\mathbb {R}^2 \subset \mathbb {R}^3$ . (A topological pair $(X,A)$ consists of a topological space X and a subspace $A\subseteq X$ .)

We can extend the notion of local flatness to an embedding $\phi : X \to M$ of a $2$ -complex X instead of $\mathbb S^2$ : we say that $\phi $ is locally flat, if the restriction of $\phi $ to each homeomorphic image of $\mathbb S^2$ in X is locally flat, as defined above.

2.6 Rotation systems

A rotation system of a graph G is a family $(\sigma _v)_{v\in V(G)}$ of cyclic orderings of the edges incident with each vertex $v\in V(G)$ . Every embedding of G on an orientable surface defines a rotation system, by taking $\sigma _v$ to be the clockwise cyclic ordering in which the edges incident to v appear in the embedding. The rotation system $(\sigma _v)_{v\in V(G)}$ is said to be planar, if it can be defined by an embedding of G in the sphere $\mathbb S^2$ .

Let X be an edge-regular $2$ -complex, and let $\overleftrightarrow {E}(X)$ denote the set of directions of its 1-cells, that is, the set of directed pairs $\overrightarrow {xy}:= \left <x,y \right>$ such that $xy\in X^1$ . Thus, every 1-cell gives rise to two elements of $\overleftrightarrow {E}(X)$ . A rotation system of X is a family $(\sigma _e)_{e \in \overleftrightarrow {E}(X)}$ of cyclic orderings $\sigma _e$ of the 2-cells incident with each $e = \overrightarrow {xy} \in \overleftrightarrow {E}(X)$ , such that if $e'=\overrightarrow {yx}$ , then $\sigma _{e'}$ is the reverse of $\sigma _e$ . A rotation system $(\sigma _e)_{e \in \overleftrightarrow {E}(X)}$ of X induces a rotation system $\sigma ^v$ at each of its link graphs $L_X(v)$ by restricting to the directions of 1-cells emanating from v: for every $u\in V(L_X(v))$ we let $\sigma ^v_{u}$ be the cyclic order obtained from $\sigma _{\overrightarrow {vu}}$ by replacing each 2-cell f appearing in the latter by the edge $uw$ where w is the unique neighbor u in $V(L_X(v))$ such that $w,v,u$ appear consecutively in f.

A rotation system of a regular $2$ -complex X is planar, if it induces a planar rotation system on each of its link graphs. Note that once, we fix an orientation, every locally flat embedding $\phi $ of X into $\mathbb S^3$ or $\mathbb R^3$ defines a planar rotation system, by letting $\sigma _e$ be the cyclic order in which the images of the 2-cells incident with e appear in $U_x$ , where x is any interior point of $\phi (e)$ , and $U_x$ is as in the definition of local flatness (Section 2.5).

2.7 Invariant rotation systems

Suppose that a group $\Gamma $ acts on a $2$ -complex X by a faithful action $\Gamma \curvearrowright X$ . Let $\Sigma $ be the set of all rotation systems $\boldsymbol {\sigma }= (\sigma _e)_{e \in \overleftrightarrow {E}(X)}$ on X as defined in the previous subsection. Then we can let $\Gamma $ act on $\Sigma $ by elementwise multiplication as follows. Recall that $\sigma _e$ is formally a ternary “betweenness” relation on the set $F(e)$ of 2-cells containing e for every 1-cell e. For $g\in \Gamma $ , we define the product $g \cdot \sigma _e:= \{ [ga,gb,gc]\mid [a,b,c]\in \sigma _e\}$ , which is a cyclic ordering on $F(ge)$ . This defines our action $g \cdot \boldsymbol {\sigma }:= (g \cdot \sigma _e)_{e \in E(X)}$ of $\Gamma $ on $\Sigma $ . We will say that $\boldsymbol {\sigma }$ is $\Gamma $ -invariant, if $g \cdot \boldsymbol {\sigma }$ coincides with $ \boldsymbol {\sigma }$ up to a global change of orientation. To make this more precise, let $\eta : \Gamma \to \mathbb Z_2$ be a homomorphism from $\Gamma $ to the group $\mathbb Z_2$ ; we will use $\eta $ to carry the information of which $g\in \Gamma $ preserve/reverse the orientation. We say that ${\boldsymbol {\sigma }}$ is invariant with respect to $\eta $ , if

(1) $$ \begin{align} g \cdot \sigma_e =(-1)^{\eta(g)} \sigma_{ge}, \end{align} $$

holds for every $e \in \overleftrightarrow {E}(X)$ and $g\in \Gamma $ . We say that $\boldsymbol {\sigma }$ is $\Gamma $ -invariant if it is invariant with respect to some homomorphism $\eta $ . Note that $\eta $ is uniquely determined by $\boldsymbol {\sigma }$ if it exists.

5.1 Step 1: Constructing an embedded $2$ -complex with a regular action on its chambers

The following lemma performs the first step of our construction of a generalized Cayley complex of $\Gamma $ as mentioned above:

For the proof of this, we will use the following basic fact:

Proof of Lemma 5.3

We may assume without loss of generality that our action $\Gamma \curvearrowright M$ is smooth by Pardon’s theorem, A.1.

It is known that for every such action, the quotient space $M/\Gamma $ —which is a 3-orbifold, but the reader will not need to know what this means—admits a triangulation T [Reference Moerdijk and Pronk36, Proposition 1.2.1], which is adapted to the action in the sense that for each simplex $\sigma $ of T, the stabilizers under $\Gamma $ of all preimages of points in $\sigma $ are isomorphic to each other. Since $\Gamma \curvearrowright M$ is cocompact, $M/\Gamma $ is compact, and thus T is finite. Let $\pi : M \to M/\Gamma $ be the quotient projection. Its inverse $\pi ^{-1}$ lifts T to a triangulation $\tilde {T}$ of M, as proved in [Reference Moerdijk and Pronk36, Lemma 1.2.2], which is $\Gamma $ -invariant by construction. We think of the 2-skeleton $\tilde {T}^2$ of $\tilde {T}$ as an embedded 2-complex in M. It is straightforward to check that the chambers of $\tilde {T}$ are exactly its 3-cells. It is easy to show that $\pi _1(\tilde {T}^2)\cong \pi _1(M)$ by applying van Kampen’s theorem to the 3-cells of $\tilde {T}$ .

Notice that the action $\Gamma \curvearrowright M$ is free on the 3-cells of $\tilde {T}$ and therefore on the chambers of $\tilde {T}^2$ , because it is faithful. Indeed, if an element g of $\Gamma $ fixed a 3-cell C setwise, then g would have to fix C pointwise. This would force g to also fix the 3-cells incident with C, hence all of M by its connectedness, implying that g can only be the identity of $\Gamma $ .

If the action is not transitive on the chambers of $\tilde {T}^2$ , then we can find a subcomplex X of $\tilde {T}^2$ which maintains the other desired properties and such that $\Gamma $ acts transitively on the chambers of X, by finding an appropriate fundamental domain of 3-cells of $\tilde {T}^2$ and joining them into one chamber. To do so, we introduce the following notion.

Say that two chamber-boundaries $C,D$ of a 2-complex H are adjacent, if their boundaries share a 2-cell of H. Say that $C,D$ are tight-connected, if there is a sequence $C_1,\ldots C_k$ of chamber-boundaries such that $C_1=C, C_k=D$ , and $C_i$ is adjacent to $C_{i+1}$ for every $1\leq i<k$ . A tight-component is a maximal tight-connected set of chamber-boundaries of H. It is straightforward to check that

(3) $$ \begin{align} &\text{the boundaries of 3-cells of a triangulation of any connected 3-manifold}\nonumber\\ &\text{form a single tight-component. }\end{align} $$

Let F be a maximal tight-connected set of boundaries of 3-cells of $\tilde {T}^2$ that contains at most one representative from each $\Gamma $ -orbit of 3-cells of $\tilde {T}$ . The maximality of F, combined with (3), easily implies that F contains a representative from each $\Gamma $ -orbit of 3-cells, for otherwise we could add to F a 3-cell adjacent with one of its elements (this is a well-known idea, appearing, e.g., in [Reference Babai5]). Thus, F contains exactly one representative of each $\Gamma $ -orbit of 3-cells, in other words, the action of $\Gamma $ on the translates of F is regular. Moreover, F is finite since $\Gamma \curvearrowright M$ is cocompact.

We claim that there is a set D of 2-cells of $\bigcup F$ such that $\bigcup F \backslash D$ has only one chamber C, and moreover C is homeomorphic to $\mathbb S^3$ . Indeed, we can construct D recursively as follows. As long as $\bigcup F$ has more than one chamber (each homeomorphic to $\mathbb R^3$ ), we can find two of them $C_1,C_2$ sharing a 2-cell f by tight-connectedness. By removing f we join $C_1,C_2$ into one chamber, which is homeomorphic to $\mathbb R^3$ since both $C_1,C_2$ are. (The boundary of the new chamber need not be homeomorphic to $\mathbb S^2$ , however.) It is easy to see that the tight-connectedness of the chamber-boundaries of F is preserved. Since F is finite, this recursion terminates leaving a single chamber, proving our claim.

Let $X\subset M$ be the 2-complex obtained from $\tilde {T}^2$ by removing a set D as above along with all its $\Gamma $ -translates. Then $\bigcup F$ is contained in one chamber of X, and it follows that $\Gamma $ acts regularly on the chambers of X.

By construction, each chamber of X is still homeomorphic to $\mathbb R^3$ and finitary.

Notice that whenever we removed a 2-cell f of $\tilde {T}^2$ we joined two chambers $C_1,C_2$ into one, and so we did not change $\pi _1$ by Lemma 5.4. Thus, $\pi _1(X)\cong \pi _1(\tilde {T}^2)$ , which coincides with $\pi _1(M)$ as noticed above.

5.2 Step 2: From regularity of the action on the chambers to regularity on the vertices

Having constructed an embedded 2-complex $X\subset M$ such that the action $\Gamma \curvearrowright M$ of Theorem 5.1 or 5.2 is regular on the chambers of X, our aim now is to modify X locally so that the action becomes regular on the vertices. Most of the work will go into making the action free on the vertices, because having done so we will be able to use the standard trick of contracting a fundamental domain to achieve transitivity. To formulate this trick in our setup, given a graph G, and a subgroup $\Gamma $ of the automorphism group $Aut(G)$ of G, we call a subgraph $H\subseteq G$ a fundamental domain for $\Gamma $ , if H contains exactly one vertex from each $\Gamma $ -orbit.

The graph we will later apply Lemma 5.5 to is the 1-skeleton of our 2-complex.

Thus, it remains to transform the freeness of the action on the chambers arising from Lemma 5.3 into freeness on the vertices. This is carried out by the following result.

Our formal definition of the complex $F(X)$ that achieves this takes some time, but the idea is rather simple: given a vertex x of X stabilized by $\Gamma \curvearrowright M$ , we notice that we can pick a set $O_x$ of nearby points inside the chambers incident with x such that the action of $\Gamma $ on $O_x$ is regular, because $\Gamma $ acts freely on the chambers. The idea is to blow up each 2-cell, 1-cell, and 0-cell of X into a homeomorph of $\mathbb S^2$ , in order to modify X into a complex $F(X)$ with vertex set $\bigcup _{x\in X^0} O_x$ . An example is shown in Figure 2: if X is the standard cubic lattice embedded in $\mathbb R^3$ (top left), then a portion of $F(X)$ is displayed in the bottom right of the figure.

Figure 2:

An example $F(X)$ , when X is the cubic lattice (top left). Each link graph is an octahedron (top right), and so each pineapple of $F(X)$ is a truncated cuboctahedron (bottom left). The pineapples are arranged as in the bottom right figure, which shows four of them in the front.

The reader will lose nothing by assuming that $M= \mathbb S^3$ and $\Gamma $ is finite throughout this section; this is enough for proving Theorem 1.4, and this assumption makes no difference for any of the proofs in this section.

We now prepare for the formal definition of $F(X)$ . Given an embedded 2-complex $X\subset M$ , and a homeomorphic image S of $\mathbb S^2$ in M which is locally flat, we say that S is adapted to X if

1. (i) for every 1-cell $e\in X^1$ the intersection $S \cap e$ is either a single point, or all of e, or empty;

2. (ii) for every 2-cell $f\in X^2$ , the intersection $S \cap f$ is either an arc between two points of the boundary of f (either 0-cells, or interior points of 1-cells) or empty, and

3. (iii) S separates M into two components.

If S is adapted to X, and A is one of the two components into which S separates M, then we can obtain an embedded 2-complex $X_A$ from X by removing $X \cap A$ and adding S to X; to make this more precise, we define the A-truncation of X to be the embedded 2-complex $X_A$ obtained as follows.

1. (i) For every 1-cell $e\in X^1$ that intersects S at a point p, we declare p to be a 0-cell of $X_A$ , we declare the subarc of e lying outside A to be a 1-cell of $X_A$ and discard the subarc of e lying inside A.

2. (ii) For every 2-cell $f\in X^2$ intersecting S along an arc P between two points $x,y$ of the boundary of f, we declare P to be a 1-cell of $X_A$ —its end-points $x,y$ must be 0-cells of $X_A$ by i. Notice that $f \backslash (S \cup A)$ is homeomorphic to a disc $f'$ , and we declare $f'$ to be a 2-cell of $X_A$ , discarding f.

3. (iii) The points p and arcs P as in i–iisubdivide S into topological discs, which we declare to be 2-cells of $X_A$ .

4. (iv) For every cell C of X that does not intersect S, we keep C in $X_A$ if it lies outside A, and discard it if it is contained in A.

We now construct the 2-complex $F(X)$ featuring in Theorem 5.6 by a combination of such truncations.

1. (i) We blow each 2-cell $f\in X^2$ up like a mango; that is, we replace f by two “parallel” copies $f',f"$ with the same boundary and attachment map, and embed $f',f"$ into M so that one of the sides of the 2-sphere $S_f:= f' \cup f"$ contains f and is otherwise disjoint from X. Moreover, we ensure that $S_f$ is locally flat, and disjoint from $g' \cup g"$ for every $g\neq f\in X^2$ except possibly for intersections along $X^1$ ; in other words, our mangos do not cross each other. Let $X_1$ denote the resulting 2-complex. We call $f' \cup f"$ the mango of f and imagine its side containing f as one.

2. (ii) Next, we blow each 1-cell $e\in X_1^1$ up like a banana. To define this formally, let $S_e$ be a homeomorph of $\mathbb S^2$ in M such that the end-vertices of e lie on $S_e$ , one side $A_e$ of $S_e$ contains the interior of e and is otherwise disjoint from the 1-skeleton of $X_1$ , and $S_e$ is adapted to $X_1$ and locally flat. It is easy to find such $S_e$ , and to ensure that they are pairwise disjoint except possibly at their vertices. We apply the $A_e$ -truncation of $X_1$ for each $e\in X_1^1$ to obtain a new embedded 2-complex $X_2$ . We call $S_e$ the banana of e.

3. (iii) Finally, we blow each vertex $v\in X_2^0=X^0$ up like a pineapple; that is, we pick a homeomorph $S_v$ of $\mathbb S^2$ in M, such that one side $A_v$ of $S_v$ contains v but no other vertices of $X_2$ , and $S_v$ is adapted to $X_2$ and locally flat. Moreover, we choose the $S_v, v\in X_2^0$ small enough that they are pairwise disjoint. We apply the $A_v$ -truncation of $X_2$ for each $v\in X_2^0$ to obtain the desired 2-complex $F(X)$ . We call $S_v$ the pineapple of v.

Using van Kampen’s theorem, it will be easy to deduce that $F(X)$ preserves the fundamental group of X:

In order to be able to use $F(X)$ to prove Theorem 5.6, we need to construct it more carefully so that $\Gamma \curvearrowright M$ extends to an action on $F(X)$ . This would be easy if $\Gamma $ acted freely on X, but in general we need to take some care to ensure that the stabilizer of each 2-cell, 1-cell, or 0-cell fixes the corresponding mango, banana, or pineapple, respectively. We will be able to achieve this by choosing a chamber C of X and using its closure $\overline {C}$ as a fundamental domain. More precisely, we will prove

Here, $\Gamma A$ denotes the image of a set $A\subset M$ under the action $\Gamma \curvearrowright M$ , and $F(D)$ is given by Definition 5.7.

Before proving Lemma 5.9, let us see how it implies Theorem 5.6.

It remains to prove Lemma 5.9. To construct the desired copy F of $F(D)$ , we will first design the intersection of F with each 2-cell of $F(D)$ . To do so, we need to remember how the bananas and pineapples of $F(X)$ intersect each 2-cell of X (the mangos do not); these intersections are described in the following definition, but they are easier to see in Figure 3.

Figure 3:

A topological 5-gon with a slice pattern. The $E_i$ are depicted in red (if color is shown), and the $V_i$ in blue.

A topological n-gon is a regular 2-complex P containing exactly one 2-cell f, and such that $P^1$ is homeomorphic to $\mathbb S^1$ (and coincides with the boundary of f).

An automorphism of a topological n-gon P is a homeomorphism of P mapping each vertex to a vertex (and hence each edge to an edge). To prove Lemma 5.9, we will apply the following lemma to each 2-cell of D; this helps us by pushing the difficulty one dimension down.

We are now ready to complete the main result of this section.

Notice that when M is simply connected in Theorem 5.2, then it is a special 3-manifold by Theorem 1.1. Thus, we have proved the implication $(i)\rightarrow (iv)$ of Theorem 1.5 and its analogue for Theorem 1.4. In particular, we deduce the implication $(i)\rightarrow (iii)$ of Theorem 1.4, and assuming, as we may, that the action of (i) is on $\mathbb S^2$ , we avoid using Theorem 1.1. Combined with Section 4, we thus obtain a proof of the equivalence of $(i)$ and (iii) of Theorem 1.4 without using Perelman’s work.