Proof We use induction on the number of vertices of the graph. Obviously, the lemma is true if the graph is just a vertex. We assume the lemma is true for any graph with less than $N+1$ vertices. Let $\Gamma $ be a finite simplicial graph with $N+1$ vertices.

If the graph is disconnected the lemma follows by the inductive hypothesis and the fact that the clique twins of the components of the graph forms a clique twin of $\Gamma $ .

So we assume that the graph is connected. We choose an arbitrary vertex say v and we consider the graph $\Gamma _v = \Gamma \setminus v$ . By inductive hypothesis, there exists a clique twin $\mathcal {C}_{\Gamma _v}$ of $\Gamma _v$ . Since the graph is connected the link of v in $\Gamma $ is non-empty ( $lk_{\Gamma} (v) \neq \varnothing $ ). We enumerate the vertices of the link, $lk_{\Gamma} (v)=\lbrace v_1, v_2 , \ldots ,v_k \rbrace $ . For every C in $\mathcal {C}_{\Gamma _v}$ , we set:

$$ \begin{align*} \overline{C}= \textrm{ either } C\textrm{ (if }C \cup v&\textrm{ doesn't define a clique of }\Gamma),\textrm{ or the clique defined }\\ &\textrm{by }C\textrm{ and }v\textrm{ (otherwise)}. \end{align*} $$

For every $v_i$ in $lk_{\Gamma} (v)$ , we define:

$$ \begin{align*} \mathcal{C}_i \textrm{ to be the collection of all maximal cliques in }\Gamma\textrm{ containing both }v\textrm{ and }v_i. \end{align*} $$

Observe then that the union $\mathcal {C}_{\Gamma} = (\cup _i \mathcal {C}_i ) \cup \lbrace \overline {C} \vert C \in \mathcal {C}_{\Gamma _v} \rbrace $ satisfies the conditions of Definition 2.1, so it is a clique twin of $\Gamma $ .

Proof We assume that $\Gamma $ is a clique, then obviously, there is no vertex cut of $\Gamma $ . So by Definition 2.3 we have that $CC(\Gamma )=0$ .

We now prove the other direction, so we assume that $CC(\Gamma )=0$ . If $\Gamma $ is not a clique there exist two vertices $a,b$ such that they are not connected by an edge, then $V(\Gamma )\setminus \lbrace a,b \rbrace $ separate the graph. Obviously, then we may find a vertex cut S of $\Gamma $ , so by Lemma 3.1 $CC(\Gamma )>0.$

Proof It follows from the observation that if a clique twin exists, then it is equal to the set of the maximal cliques of the graph.

Proof Since G is a full subgraph of $\Gamma $ we have that every full subgraph of G is also a full subgraph of $\Gamma $ . The lemma follows by the definition of $\mathrm{dim}_{CC}$ .

Proof Suppose that $CC(G) \leq 1$ , for every G, proper full subgraph of $\Gamma $ . Let S be a vertex cut of $\Gamma $ such that $m_C(FS^{\Gamma} (S)) \geq 2$ , and let $\mathcal {C}_S= \lbrace C_1, \ldots , C_k \rbrace $ be the clique twin of $FS^{\Gamma} (S)$ .

Let $E_1 , E_2$ be two of the components of $\Gamma \setminus FS^{\Gamma }(S)$ . Observe that there are vertices $v_1 , v_2 \in FS^{\Gamma }(S)$ such that they are not connected by an edge in $\Gamma $ . Obviously, they belong to distinct cliques. We may assume that $v_1 \in C_1 \setminus C_2$ and $v_2 \in C_2 \setminus C_1$ . We note that for every $s\in S$ and every component $E_i$ , there exists an edge connecting s with $E_i$ (it follows from the fact that S is a vertex cut of the graph). Thus, there exist edge paths $p_i \subseteq E_i \cup C_1 \cup C_2$ connecting $v_1$ with $v_2$ such that $p_i \cap (C_1 \cup C_2) = \lbrace v_1, v_2 \rbrace $ . We may assume that these paths have the minimum possible length.

Observe that the length of these edge paths is at least two. Trivially, the union $p_1 \cup p_2$ is k-cycle, where $k \geq 4$ .

It remains to show that $p_1 \cup p_2$ is a full subgraph of $\Gamma $ . Indeed, it follows from the choice of $v_1$ and $v_2$ , the fact that $p_1$ , $p_2$ are of minimum length and that $p_1 \setminus (C_1 \cup C_2) $ , $p_2 \setminus (C_1 \cup C_2)$ belong to distinct components of $\Gamma \setminus FS^{\Gamma }(S)$ .

Obviously, $CC(p_1 \cup p_2)=2$ . By the hypothesis of lemma, we conclude that $\Gamma = p_1 \cup p_2$ .

We assume that $\Gamma $ is a k-cycle ( $k \geq 4$ ). Let G be a proper full subgraph of $\Gamma $ . Then there is a vertex v of $\Gamma $ such that G is a full subgraph of $\Gamma \setminus v$ . We observe that if we remove a vertex from $\Gamma $ , then the resulting graph $\Gamma ^\prime $ is a concatenation of edges. Trivially, $CC(\Gamma ^\prime )=1$ and $CC(G) \leq 1$ for every G full subgraph of $\Gamma ^\prime $ .

Proof By Lemma 3.3, there exists unique clique twins $\mathcal {C}_G$ of G and $\mathcal {C}_{\Gamma} $ of $\Gamma $ . By condition (ii) of definition of clique twins, we observe that for every $C_G \in \mathcal {C}_G$ , there exists a $C_{\Gamma } \in \mathcal {C}_{\Gamma }$ containing $C_G$ . Since G is a full subgraph of $\Gamma $ , this correspondence is 1–1 meaning there are no two distinct cliques of $\mathcal {C}_G$ contained in the same clique of $\mathcal {C}_{\Gamma }$ . Thus, $m_C (G) =\sharp \mathcal {C}_G \leq \sharp \mathcal {C}_{\Gamma} = m_C (\Gamma )$ .

Proof It is suffices to show the proposition for connected graphs. If $\Gamma $ is a clique, then the proposition holds. We assume that the graph is not a clique. We denote by $\mathcal {C}_{\Gamma} $ the unique clique twin of $\Gamma $ .

Since $\Gamma $ is connected, there exists at least two cliques of $\mathcal {C}_{\Gamma} $ intersecting each other. Let $C_1$ be a clique of $\mathcal {C}_{\Gamma} $ such that there exists another element of $\mathcal {C}_{\Gamma} $ intersecting $C_1$ . Let F be a subclique of $C_1$ of maximal cardinality such that there exists $C_2 \in \mathcal {C}_{\Gamma} $ and $C_1 \cap C_2=F$ .

We set $C_i^c=C_i \setminus F$ ( $i=1,2$ ) and $\Gamma ^\prime = \Gamma \setminus (C_1^c \cup C_2^c)$ . Obviously, all of them are full subgraphs of $\Gamma $ .

Claim 1: $\Gamma ^\prime $ separates $\Gamma $ .

If not, then there exists an edge $e=[v_1,v_2]$ , where $v_i \in C_i^c$ . But then the clique $F^\prime =FS^{\Gamma} (F \cup v_1) \subseteq C_1$ has strictly larger cardinality from F, and the clique $C_3=FS^{\Gamma} (F^\prime \cup v_2) $ intersects $\Gamma $ on $F^\prime $ , which is a contradiction by the choice of F.

Claim 2: $m_C(\Gamma ^\prime ) < m_C(\Gamma )$ .

We denote by $\mathcal {C}_{\Gamma ^\prime }$ , the unique clique twin of $\Gamma ^\prime $ . Observe that distinct elements of $\mathcal {C}_{\Gamma ^\prime }$ belong to distinct elements of $\mathcal {C}_{\Gamma }$ . Thus, if the claim is not true (i.e., $\mid \mathcal {C}_{\Gamma ^\prime } \mid =\mid \mathcal {C}_{\Gamma } \mid $ ), there are distinct elements $B_1, B_2 \in \mathcal {C}_{\Gamma ^\prime }$ such that $B_i \subseteq C_i$ ( $i=1,2$ ). By the definition of $\Gamma ^{\prime }$ , we have that $B_i \subseteq F$ , but both $B_1$ and $B_2$ are maximal in $\Gamma ^\prime $ , thus $B_1=F=B_2$ , which is a contradiction.

By Claim 1 and the fact that $\Gamma $ is finite, there exists a vertex cut $S \subseteq \Gamma ^\prime $ . Then $CC(\Gamma ) \leq m_C(FS^{\Gamma} (S)) \leq m_C(\Gamma ^\prime ) < m_C(\Gamma ).$

Proof By Proposition 4.2, we have that $CC(FS^{\Gamma} (S))< m_C(FS^{\Gamma} (S)) = CC(\Gamma )$ .

Proof Let H be a full subgraph of G, observe that H is a full subgraph of $\Gamma $ as well. By Proposition 4.2 and Lemma 4.1, we have that $CC(H)< m_C (H) \leq m_C(G) \leq m_C(FS^{\Gamma} (S))=CC (\Gamma ) $ . Thus $CC(H)<CC(\Gamma )$ .

Proof We will use induction on $\sharp V(\Gamma )$ . If $\sharp V(\Gamma )=1$ , the theorem is obviously true. We assume that for any graph with $\sharp V(\Gamma )< N+1$ , the theorem holds. Let $\Gamma $ be a graph such that $\sharp V(\Gamma )= N+1$ .

By Theorem 2.3, it is enough to prove the inequality only for RACGs with connected defining graphs. So we assume that the graph is connected. If the graph $\Gamma $ is a clique, then by Lemma 3.2, the theorem holds. So we further assume that the graph is not a clique. Since the graph is not a clique, there is a subset of its vertices separating it, thus, there is at least one vertex cut of $\Gamma $ . Let S be a minimal vertex cut of the graph, and let $E_1, \ldots , E_k$ be the connected components of $\Gamma \setminus FS^{\Gamma} (S)$ . Observe that since S is a vertex cut, we have that for every vertex s of S and every component $E_i$ , there exists at least one edge connecting them. We set $\overline {E_i}=FS^{\Gamma} (E_i \cup S)$ , observe that $\overline {E_i}$ is a connected full subgraph of $\Gamma $ ; and thus, by lemma 3.4, $\mathrm{dim}_{CC}(\overline {E}_i) \leq \mathrm{dim}_{CC}(\Gamma )$ . By the inductive hypothesis $\mathrm{asdim} W_{\overline {E}_i} \leq \mathrm{dim}_{CC}(\overline {E}_i)$ , so

(1) $$ \begin{align} \mathrm{asdim} W_{\overline{E}_i} \leq \mathrm{dim}_{CC}(\Gamma), \end{align} $$

where $ W_{\overline {E}_i} $ is the parabolic subgroup of $W_{\Gamma} $ defined by $\overline {E}_i$ (of course, $W_{\overline {E}_i}$ is RACG). Using Theorem 4.4, we have $\mathrm{dim}_{CC}(FS^{\Gamma} (S)) < \mathrm{dim}_{CC}(\Gamma )$ . We distinguish two cases.

Case 1: $FS^{\Gamma} (S)$ is connected.

By the inductive hypothesis $\mathrm{asdim} W_{FS^{\Gamma} (S)} \leq \mathrm{dim}_{CC}(FS^{\Gamma} (S))$ , then

(2) $$ \begin{align} \mathrm{asdim} W_{FS^{\Gamma} (S)} < \mathrm{dim}_{CC}(\Gamma), \end{align} $$

where $ W_{FS^{\Gamma} (S)} $ is the parabolic subgroup of $W_{\Gamma} $ defined by $FS^{\Gamma} (S)$ (of course, $W_{FS^{\Gamma} (S)}$ is RACG).

Finally, observe that $W_{\Gamma} $ can be obtained from $W_{\overline {E}_i}$ after a finite sequence of amalgamated product over $W_{FS^{\Gamma} (S)} $ . To be more precise,

(3) $$ \begin{align} W_{\Gamma} = (W_{\overline{E}_1 } \underset{W_{FS^{\Gamma} (S)}}{\ast} W_{\overline{E}_2}) \underset{W_{FS^{\Gamma} (S)}}{\ast} \ldots W_{\overline{E}_k}. \end{align} $$

In other words, $W_{\Gamma }$ is the fundamental group of a graph of groups with vertex groups $W_{\overline {E}_i }$ and $W_{FS^{\Gamma} (S)}$ , and edge groups isomorphic to $W_{FS^{\Gamma} (S)}$ . Applying Theorems 2.1 or 2.2, we conclude that $\mathrm{asdim} W_{\Gamma} \leq \mathrm{dim}_{CC} (\Gamma ).$

Case 2: $FS^{\Gamma} (S)$ is not connected.

By equality (3), we observe that to complete the proof of the theorem, it’s enough to show that $\mathrm{asdim} W_{FS^{\Gamma} (S)}< \mathrm{dim}_{CC} (\Gamma )$ .

Let $C_1,\ldots ,C_\lambda $ be the connected components of $FS^{\Gamma} (S)$ ( $\lambda \geq 2$ ). Without loss of generality, we may assume that the $\mathrm{dim}_{CC}(C_i) \leq \mathrm{dim}_{CC}(C_\lambda )$ , for any i. By the inductive hypothesis $\mathrm{asdim} W_{C_i} \leq \mathrm{dim}_{CC}(C_\lambda )$ . So, by Theorem 2.3,

(4) $$ \begin{align} \mathrm{asdim} W_{FS^{\Gamma} (S)}= \max \lbrace 1, \mathrm{dim}_{CC}(C_\lambda) \rbrace. \end{align} $$

We distinguish two subcases.

Case 2(a): $\mathrm{dim}_{CC}(C_\lambda ) \geq 1$ .

Then $\mathrm{asdim} W_{FS^{\Gamma} (S)}= \mathrm{dim}_{CC}(C_\lambda ) $ . Since $\mathrm{dim}_{CC}(C_\lambda ) \leq \mathrm{dim}_{CC}({FS^{\Gamma} (S)}) < \mathrm{dim}_{CC}(\Gamma )$ , we conclude that $\mathrm{asdim} W_{FS^{\Gamma} (S)}< \mathrm{dim}_{CC}(\Gamma )$ .

Case 2(b): $\mathrm{dim}_{CC}(C_\lambda ) =0$ .

Then $\mathrm{asdim} W_{FS^{\Gamma} (S)}= 1$ . Since S is a minimal vertex cut, and $FS^{\Gamma} (S)$ is not connected, we obtain that $\mathrm{dim}_{CC}(\Gamma ) \geq 2$ . Thus, $\mathrm{asdim} W_{FS^{\Gamma} (S)}< \mathrm{dim}_{CC}(\Gamma )$ .

Proof $\Gamma $ contains a full subgraph G such that $CC(G) \geq 2$ . We assume that G is a minimal full subgraph of $\Gamma $ such that $CC(G) \geq 2$ . Trivially, G is connected. Since G is minimal, we have that $CC(G^\prime ) \leq 1$ for every $G^\prime $ proper full subgraph of G, so by Lemma 3.5, G is a k-cycle ( $k \geq 4$ ).

By Theorem 8.7.2 of [Reference Davis3], we have that the parabolic subgroup $W_G$ of $W_{\Gamma} $ defined by G is one-ended.

Proof If $\mathrm{dim}_{CC}(\Gamma )=0$ , then $\Gamma $ is a clique, so $W_{\Gamma} $ is finite. Then $\mathrm{asdim} W_{\Gamma} =0$ .

If $\mathrm{dim}_{CC}(\Gamma )=1$ , then by Theorem 5.1, we have $\mathrm{asdim} W_{\Gamma} \leq 1$ . By Lemma 3.2, $\Gamma $ is not a clique; and thus, there are two vertices $a,b$ which are not connected by an edge. This means that $W_{\Gamma} $ contains $\mathbb {Z}_2 \ast \mathbb {Z}_2$ as a parabolic subgroup, so $\mathrm{asdim} W_{\Gamma} = 1$ .

If $\mathrm{dim}_{CC}(\Gamma )=2$ , then by Theorem 5.1, we have $\mathrm{asdim} W_{\Gamma} \leq 2$ . By Proposition 6.1, we have that there exists an one-ended parabolic subgroup $W_G$ of $W_{\Gamma} $ . Then, by the main theorem of [Reference Gentimis8], we obtain that $2 \leq \mathrm{asdim} W_G$ . So $\mathrm{asdim} W_{\Gamma} = 2$ .

Proof Suppose that $W_{\Gamma} $ is finite. Then $\Gamma $ is a clique, indeed, otherwise $W_{\Gamma} $ contains $\mathbb {Z}_2 \ast \mathbb {Z}_2$ as a parabolic subgroup, so $\mathrm{asdim}W_{\Gamma}>0$ . Which is a contradiction. Since $\Gamma $ is not a clique, by Lemma 3.2, we obtain $\mathrm{dim}_{CC}(\Gamma )=0$ .

The other direction follows by the previous proposition.

Proof We assume that $W_{\Gamma} $ is virtually free. If $\mathrm{dim}_{CC}(\Gamma ) \geq 2$ , then, by Proposition 6.1, $W_{\Gamma} $ contains an one-ended parabolic subgroup. Since one-ended groups have asymptotic dimension at least two (see [Reference Gentimis8]), we have that $\mathrm{asdim}W_{\Gamma} \geq 2$ . By the fact that the asymptotic dimension of virtually free groups is one (see [Reference Gentimis8]), we have a contradiction.

If $\mathrm{dim}_{CC}(\Gamma ) =0$ , then $\Gamma $ is a clique. In that case, $W_{\Gamma} $ is finite, which is a contradiction.

Suppose that $\mathrm{dim}_{CC}(\Gamma )=1$ , then, by Proposition 6.2, we have $\mathrm{asdim} W_{\Gamma} = 1$ . Applying Gentimis’ theorem for virtually free groups (see [Reference Gentimis8]), we conclude that $W_{\Gamma} $ is virtually free.

Proof We suppose that $\mathrm{asdim}(W_{\Gamma} ) \geq 2$ , then, by Theorem 5.1, we have that $\mathrm{dim}_{CC}(\Gamma )\geq 2$ .

Conversely, we assume that $\mathrm{dim}_{CC}(\Gamma ) \geq 2$ , then, by the previous proposition and the fact that the only groups having asymptotic dimension one are the virtually free groups (see [Reference Gentimis8]), we have that $\mathrm{asdim}(W_{\Gamma} ) \neq 1$ . Obviously, $\mathrm{asdim}(W_{\Gamma} ) \neq 0$ , otherwise we have a contradiction by Corollary 1.

Question Is there any connected graph such that the RACG defined by the graph has asymptotic dimension two while the clique-connected dimension of the graph is greater than two?

Proof By Theorem 5.1, $\mathrm{dim}_{CC}(\Gamma )\geq 2$ . By the proof of Proposition 6.1, $\Gamma $ contains a k-cycle G as a full subgraph ( $k \geq 4 $ ). Trivially, $\mathrm{dim}_{CC}(G)=2$ .