Proof. Let $E_+$ denote the set of positive edges of ${\cal {S}}(H)$ (that is with labels in A). Suppose that $T \subseteq E_+$ is a spanning tree of ${\cal {S}}(H)$ (if we view it as an undirected graph). For every $u \in F_n$ , let $\alpha _{Hu}$ label the (unique) T-geodesic of the form $1 \xrightarrow {\alpha _{Hu}} Hu$ . Define

$$ \begin{align*}B = \{ \alpha_{Hu}a\alpha_{Hua}^{-1} \mid (Hu,a,Hua) \in E_+ \setminus T\}.\end{align*} $$

The same proof used for Stallings automata [Reference Bartholdi, Siva and Pin5, Proposition 3.6] shows that B is a basis of H. We show next how we can use the decidability of the membership problem of H to make the construction of B algorithmic.

Consider the geodesic distance in the Schreier automaton ${\cal {S}}(H)$ and let $D_m(1)$ denote the closed ball with centre 1 and radius $m \in \mathbb {N}$ . Let ${\cal {S}}_m(H)$ be the subautomaton of ${\cal {S}}(H)$ induced by $D_m(1)$ . Clearly, ${\cal {S}}_m(H)$ has less than $\sum _{i=0}^m (2n)^i$ vertices and $\sum _{i=0}^m (2n)^{i+1}$ edges. Since H has decidable membership problem, we can effectively construct ${\cal {S}}_m(H)$ for each $m \in \mathbb {N}$ .

Now we can construct a spanning tree $T_m$ of ${\cal {S}}_m(H)$ for each $m \in \mathbb {N}$ with ${T_0 \subset T_1 \subset T_2 \subset \cdots }$ . It is immediate that $T = \bigcup _{m\geq 0} T_m$ is a spanning tree for ${\cal {S}}(H)$ . Let

$$ \begin{align*}B_m = \{ \alpha_{Hu}a\alpha_{Hua}^{-1} \mid Hu,Hua \in D_m(1),\, (Hu,a,Hua) \in E_+ \setminus T_m\}.\end{align*} $$

Then $B = \bigcup _{m\geq 0} B_m$ is a basis of H and we can enumerate the elements of B as follows: we start by enumerating the elements of $B_0$ , then those of $B_1 \setminus B_0$ , then those of $B_2 \setminus B_1$ and so on. Since we can compute each $B_m$ , we can write B as a sequence $(b_1, b_2,\ldots )$ where each $b_k$ is effectively computable.

Since every $h \in H$ of length m labels a closed path in ${\cal {S}}_m(H)$ at the basepoint, we can now write it as a word on B.

Proof. By Theorem 2.4, we have part (ii) $\Leftrightarrow $ (iii), and part (ii) $\Rightarrow $ (i) is trivial. It remains to show that part (i) $\Rightarrow $ (ii).

Suppose that H is $\mathbf {V}$ -closed. By Theorem 2.5, H is an intersection of $\mathbf {V}$ -open subgroups. However, $[G:H] < \infty $ , so there exist only finitely many subgroups of G containing H. It follows that H is an intersection of finitely many $\mathbf {V}$ -open subgroups and is therefore $\mathbf {V}$ -open.

Proof. We write $F = F_n$ and fix a basis A of F. It is clear that condition (iii) implies both conditions (ii) and (i). Indeed, a subgroup H of F is $\mathbf {V}$ -dense if and only if $\mathrm {{Cl}}_{\mathbf {V}}(H) = F$ and is $\mathbf {V}$ -closed if and only if $\mathrm {{Cl}}_{\mathbf {V}}(H) = H$ .

Suppose that condition (ii) holds. We claim that condition (iii) holds. Let $H \leq _{f.g.} F$ . Since $\mathbf {V}$ is extension-closed, it follows from [Reference Margolis, Sapir and Weil14, Corollary 2.18] that $\mathrm {{Cl}}_{\mathbf {V}}(H)$ is an overgroup of H (that is its Stallings automaton is a quotient of ${\cal {A}}(H)$ – obtained through identification of vertices and complete folding). Now H admits only finitely many overgroups (with respect to A), which can be effectively computed. By condition (ii), we can compute all the $\mathbf {V}$ -closed overgroups of H. The smallest such overgroup (equivalently, their intersection) is $\mathrm {{Cl}}_{\mathbf {V}}(H)$ . Hence, condition (iii) holds.

Suppose finally that condition (i) holds. Let $H\leq _{f.g.} F$ . Let $H_0,H_1,\ldots ,H_m$ be the overgroups of H, and choose a labelling so that $H_i \not \subseteq H_j$ for all ${0 \leq i < j \leq m}$ . We show by induction on i that $\mathrm {{Cl}}_{\mathbf {V}}(H_i) \in \{ H_0,H_1,\ldots ,H_i\}$ is computable for ${i = 0,\ldots ,m}$ . Since $H_m = H$ , the theorem is proved.

We consider first the case $i = 0$ . Let

$$ \begin{align*}B = \{ a \in A \mid a\text{ labels some edge in }\mathcal{A}(H)\}.\end{align*} $$

Let $F_B$ be the free group over B. Since $F_B$ is the greatest overgroup of H, we have necessarily $H_0 = F_B$ . Hence, $H_0$ is a free factor of F, and note F is trivially $\mathbf {V}$ -closed. Since $\mathbf {V}$ is extension-closed, by [Reference Ribes and Zalesskiǐ20, Corollary 3.3], $H_0$ is $\mathbf {V}$ -closed and so ${\mathrm {{Cl}}_{\mathbf {V}}(H_0) = H_0}$ .

Assume now that $0 < i \leq m$ and $\mathrm {{Cl}}_{\mathbf {V}}(H_j) \in \{ H_0,H_1,\ldots ,H_j\}$ is computable for ${j = 0,\ldots ,i-1}$ . Let

$$ \begin{align*}J = \{ j \in \{ 0,\ldots,i-1\} \mid H_i \subset H_j\text{ and }H_j\text{ is }\mathbf{V}\text{-closed}\}.\end{align*} $$

Note that $0 \in J$ . By the Nielsen–Schreier theorem, each $H_j$ is a free group of finite rank. Thus, by condition (i), we can decide, for each $j \in J$ , whether or not $H_i$ is $\mathbf {V}$ -dense in $H_j$ . Suppose that $H_i$ is $\mathbf {V}$ -dense in $H_j$ for some $j \in J$ . Then $H_j = \mathrm {{Cl}}_{\mathbf {V}}^{H_j}(H_i)$ . However, since $\mathbf {V}$ is extension-closed and $H_j$ is $\mathbf {V}$ -closed, it follows from [Reference Ribes and Zalesskiǐ20, Corollary 3.3] that the pro- $\mathbf {V}$ topology on $H_j$ is the subspace topology with respect to the pro- $\mathbf {V}$ topology on F. Hence, $H_j = \mathrm {{Cl}}_{\mathbf {V}}(H_i)$ . It follows that $H_i$ is $\mathbf {V}$ -dense in $H_j$ for at most one $j \in J$ , and in that event, we can identify it and deduce that $\mathrm {{Cl}}_{\mathbf {V}}(H_i) = H_j$ . Assume now that there exists no such j. Since $\mathbf {V}$ is extension-closed, $\mathrm {{Cl}}_{\mathbf {V}}(H_i)$ is an overgroup of $H_i$ and so $ \mathrm {{Cl}}_{\mathbf {V}}(H_i) = H_k$ for some $k \in \{ 0,\ldots ,m\}$ . If $k> i$ , then we contradict the rule governing the enumeration of the overgroups considered. However, $k < i$ and $H_k$ being $\mathbf {V}$ -closed imply that $k \in J$ , which is again a contradiction. Thus, in this final case, we have necessarily $k = i$ and so $ \mathrm {{Cl}}_{\mathbf {V}}(H_i) = H_i$ . Therefore, our claim holds for i as required.

Proof. Indeed, let A be a basis of F and let

$$ \begin{align*}B = \{ a \in A \mid a \text{ or }a^{-1}\text{ occurs in the reduced form of some }h \in H\}.\end{align*} $$

Note that $F_B$ contains H. Since H is finitely generated, B is finite and $F_B$ is a retract of $F_A$ (that is $F_B \leq F_A$ and there is a homomorphism $\theta :F_A \to F_B$ such that $\theta |_{F_B} = 1_{F_B}$ ). As noted in the proof of [Reference Margolis, Sapir and Weil14, Proposition 2.17], $\mathbf {V}$ being extension-closed implies that $F_B$ is residually $\mathbf {V}$ and so it follows from [Reference Margolis, Sapir and Weil14, Corollary 1.8] that $F_B$ is a $\mathbf {V}$ -closed subgroup of F.

It follows that if A is infinite, then $H \leq _{f.g.} F$ cannot be $\mathbf {V}$ -dense. However, since $F_B$ is $\mathbf {V}$ -closed in F and $\mathbf {V}$ is extension-closed, we know that the pro- $\mathbf {V}$ topology on $F_B$ is the subspace topology with respect to the pro- $\mathbf {V}$ topology on F (see [Reference Ribes and Zalesskiǐ20, Corollary 3.3]). Thus, $\mathrm {{Cl}}_{\mathbf {V}}^F(H) = \mathrm {{Cl}}_{\mathbf {V}}^{F_B}(H)$ and H is $\mathbf {V}$ -closed in F if and only if it is $\mathbf {V}$ -closed in $F_B$ . This proves our claim.

Proof. Write $\mathbf {V} = {\cal {V}}^f$ , $F = F_A$ and $\pi = \pi _{\cal {V}}$ .

(i) Let $u \in \mathrm {Cl}_{\mathbf {V}}^{F}(H)$ . Assume that $N \unlhd F/F^{{\cal {V}}}$ has finite index and let ${K = \pi ^{-1}(N) \unlhd F}$ . Since $F/K \cong (F/F^{{\cal {V}}})/N \in \mathbf {V}$ and $u \in \mathrm {Cl}_{\mathbf { V}}^{F}(H)$ , we get $Ku \cap H \neq \emptyset $ . Hence, ${N\pi (u) \cap \pi (H) \neq \emptyset }$ and so $\pi (u) \in \mathrm {Cl}_{{\mathbf G}}^{F/F^{{\cal {V}}}}(\pi (H))$ . Thus, $u \in \pi ^{-1}(\mathrm {Cl}_{{\mathbf G}}^{F/F^{{\cal {V}}}}(\pi (H)))$ and so ${\mathrm {Cl}_{\mathbf {V}}^{F}(H) \leq \pi ^{-1}(\mathrm {Cl}_{{\mathbf G}}^{F/F^{{\cal {V}}}}(\pi (H)))}$ .

Conversely, let $u \in \pi ^{-1}(\mathrm {Cl}_{{\mathbf G}}^{F/F^{{\cal {V}}}}(\pi (H)))$ . Let ${N \unlhd F}$ be such that $F/N \in \mathbf {V}$ . Let $\varphi :F \to F/N$ be the canonical homomorphism. By the universal property, there exists a homomorphism $\psi :F/F^{{\cal {V}}}\to F/N$ such that $\psi \circ \pi = \varphi $ . If $v \in \pi ^{-1}(\pi (N))$ , then

$$ \begin{align*}\varphi(v) = \psi(\pi(v)) \in \psi(\pi(N)) = \varphi(N) = 1,\end{align*} $$

hence $v \in N$ and so $\pi ^{-1}(\pi (N)) = N$ . Now $\pi (N) \unlhd F/F^{{\cal {V}}}$ and

$$ \begin{align*}(F/F^{{\cal{V}}})/\pi(N) \cong F/\pi^{-1}(\pi(N)) = F/N \in \mathbf{V}.\end{align*} $$

Since ${\pi (u) \in \mathrm {Cl}_{{\mathbf G}}^{F/F^{{\cal {V}}}}(\pi (H))}$ , we get $\pi (N) \pi (u) \cap \pi (H) \neq \emptyset $ . Hence, there exist some ${x \in N}$ and $h \in H$ such that $\pi (xu) = \pi (h)$ . It follows that $hu^{-1} \in \pi ^{-1}(\pi (x)) \subseteq \pi ^{-1}(\pi (N)) = N$ and so $Nu \cap H \neq \emptyset $ . Thus, $u \in \mathrm {Cl}_{\mathbf { V}}^{F}(H)$ and so $\pi ^{-1}(\mathrm {Cl}_{{\mathbf G}}^{F/F^{{\cal {V}}}}(\pi (H))) \leq \mathrm {Cl}_{\mathbf {V}}^{F}(H)$ . This establishes the equality in part (i).

Clearly, $H \leq \mathrm {Cl}_{\mathbf {V}}^{F}(H)$ . Since $F^{{\cal {V}}} = \pi ^{-1}(1) \leq \pi ^{-1}(\mathrm {Cl}_{{\mathbf G}}^{F/F^{{\cal {V}}}}(\pi (H)))$ , we now get $HF^{{\cal {V}}} \leq \mathrm {Cl}_{\mathbf {V}}^{F}(H)$ .

(ii) If $\cal {V}$ is the variety of all groups, then $F^{{\cal {V}}} = \{1\}$ and $\pi $ is the identity, hence,

$$ \begin{align*}\mathrm{Cl}_{\mathbf{V}}^{F}(H) = \pi^{-1}(\mathrm{Cl}_{{\mathbf G}}^{F/F^{{\cal{V}}}}(\pi(H))) = \mathrm{Cl}_{{\mathbf G}}^{F}(H) = H\end{align*} $$

by part (i) and Theorem 2.3. Therefore, $\mathrm {Cl}_{\mathbf {V}}^{F}(H)$ is finitely generated.

Assume now that $\cal {V}$ is not the variety of all groups. By Birkhoff’s theorem, $\cal {V}$ satisfies a nontrivial identity. Thus, $F^{{\cal {V}}}$ is nontrivial and it follows from part (i) that $\mathrm {Cl}_{\mathbf {V}}^{F}(H)$ contains a nontrivial normal subgroup of F. Assume for a contradiction that $\mathrm {Cl}_{\mathbf {V}}^F(H)$ is finitely generated. By Theorem 2.2, $\mathrm {Cl}_{\mathbf {V}}^F(H)$ has finite index in F. Hence, F is finitely generated, which is a contradiction. Therefore, $\mathrm {Cl}_{\mathbf {V}}^{F}(H)$ is not finitely generated.

(iii) If $\mathcal {V}$ is the variety of all groups, then $\mathrm {Cl}_{\mathbf {V}}^{F}(H) = H$ by Theorem 2.3, and is therefore finitely generated. Suppose that $\mathcal {V}$ is not the variety of all groups. Then $F^{\mathcal {V}}$ is nontrivial. Since $F^{{\cal {V}}} \leq \mathrm {Cl}_{\mathbf {V}}^{F}(H)$ by part (i), then $\mathrm {Cl}_{\mathbf {V}}^{F}(H)$ contains a nontrivial normal subgroup of F. Since F has finite rank, then $\mathrm {Cl}_{\mathbf {V}}^{F}(H)$ is finitely generated if and only if $[F:\mathrm {Cl}_{\mathbf {V}}^{F}(H)]$ is finite in view of Theorem 2.2.

(iv) Clearly, H is $\mathbf {V}$ -closed if and only if $\mathrm {Cl}_{\mathbf {V}}^F(H) = H$ , so $\mathrm {Cl}_{\mathbf {V}}^F(H)$ being finitely generated is a necessary condition.

Suppose first that A is infinite. By part (ii), $\mathrm {Cl}_{\mathbf {V}}^F(H)$ being finitely generated can only happen if $\mathbf {V} = {\mathbf G}$ , and in that case, H is ${\mathbf G}$ -closed by Theorem 2.3.

Assume now that A is finite. In view of part (ii), this can only happen if $[F:H]$ is finite. This necessary condition can easily be checked with the help of the Stallings automaton ${\cal {A}}(H)$ (which must be complete by [Reference Bartholdi, Siva and Pin5, Proposition 3.8]). Thus, we may assume that $[F:H]$ is finite. Now, with the help of ${\cal {A}}(H)$ , it is easy to compute the Stallings automaton of $C = \textrm {Core}_F(H)$ : we consider the finitely many conjugates of H and intersect them using the direct product of their Stallings automata. Since $C \unlhd F$ , then the underlying graph of ${\cal {A}}(C)$ is indeed the Cayley graph of $F/C$ with respect to the alphabet of F, hence, $F/C$ is computable. Since $\mathbf {V}$ is a decidable pseudovariety, then we can decide whether or not $F/C \in \mathbf {V}$ . By Proposition 2.6, this is equivalent to H being $\mathbf {V}$ -closed and we are done.

Proof. Let A be an arbitrary alphabet and let $\alpha :F_A \to F_A/F_A^{{\cal {V}}}$ be the canonical homomorphism. Let $H \leq _{f.g.} F_A$ . As in the discussion of Remark 2.9, let B be the (finite) set of all letters of A occurring in the reduced form of some $u \in H$ . We noted then that $F_B$ is a retract of $F_A$ ; now we claim that $F_B/F_B^{{\cal {V}}}$ can be viewed as a retract of $F_A/F_A^{{\cal {V}}}$ .

Indeed, let $\theta :F_A \to F_B$ be the homomorphism fixing each $b \in B$ and sending each $a \in A\setminus B$ to 1. Let $\beta :F_B \to F_B/F_B^{{\cal {V}}}$ be the canonical homomorphism. Considering the composition $\beta \circ \theta : F_A \to F_B/F_B^{{\cal {V}}} \in {\cal {V}}$ , it follows from the universal property that there exists some homomorphism $\varphi :F_A/F_A^{{\cal {V}}} \to F_B/F_B^{{\cal {V}}}$ such that the diagram

commutes. Similarly, by considering the inclusion $\iota :F_B \to F_A$ , we show that there exists some homomorphism $\psi :F_B/F_B^{{\cal {V}}} \to F_A/F_A^{{\cal {V}}}$ such that the diagram

commutes.

Checking through letters, we get $\varphi \circ \psi = 1_{F_B/F_B^{{\cal {V}}}}$ , therefore, $\psi $ is injective and so $F_B/F_B^{{\cal {V}}} \cong \psi (F_B/F_B^{{\cal {V}}})$ . Moreover, they are homeomorphic when endowed with the profinite topology.

Now $\beta (H)$ is a finitely generated subgroup of $F_B/F_B^{{\cal {V}}}$ . Since $F_B/F_B^{{\cal {V}}}$ is LERF by hypothesis, then $\beta (H)$ is a ${\mathbf G}$ -closed subgroup of $F_B/F_B^{{\cal {V}}}$ . Hence, ${\alpha (H) = \alpha (\iota (H)) = \psi (\beta (H))}$ is a ${\mathbf G}$ -closed subgroup of ${\psi (F_B/F_B^{{\cal {V}}})}$ .

However, it follows from $\varphi \circ \psi = 1_{F_B/F_B^{{\cal {V}}}}$ that $\psi \circ \varphi \circ \psi = \psi $ ; thus $\psi (F_B/F_B^{{\cal {V}}})$ is a retract of $F_A/F_A^{{\cal {V}}}$ . By [Reference Margolis, Sapir and Weil14, Proposition 1.6], the profinite topology on $\psi (F_B/F_B^{{\cal {V}}})$ is the subspace topology with respect to the profinite topology on $F_A/F_A^{{\cal {V}}}$ . Thus, $\alpha (H) = C \cap \psi (F_B/F_B^{{\cal {V}}})$ for some ${\mathbf G}$ -closed subset C of $F_A/F_A^{{\cal {V}}}$ . Since $F_A/F_A^{{\cal {V}}}$ is residually finite by hypothesis, it follows from [Reference Margolis, Sapir and Weil14, Corollary 1.8] that $\psi (F_B/F_B^{{\cal {V}}})$ is a ${\mathbf G}$ -closed subgroup of $F_A/F_A^{{\cal {V}}}$ , so $\alpha (H)$ is itself a ${\mathbf G}$ -closed subgroup of $F_A/F_A^{{\cal {V}}}$ .

Now every finitely generated subgroup of $F_A/F_A^{{\cal {V}}}$ is of the form $\alpha (H)$ for some finitely generated subgroup H of $F_A$ (we can lift through $\alpha $ a finite set of generators). Therefore, $F_A/F_A^{{\cal {V}}}$ is LERF.

Proof. Write $F = F_A$ .

(i) Let ${\cal {V}} = [ x^{-1} y^{-1} xy,x^m]$ denote the variety of all abelian groups of exponent dividing m. Then,

$$ \begin{align*}F^{{\cal{V}}} = \langle\langle \varphi([x,y]), \varphi(x^m) \mid \varphi:F_X \to F\text{ homomorphism}\rangle\rangle_F = \langle\langle [u,v],u^m \mid u,v \in F\rangle\rangle_F.\end{align*} $$

Since $F'$ and $F^m = \langle u^m \mid u \in F\rangle $ are both normal subgroups of F, we get ${F^{{\cal {V}}} = F'F^m}$ . Hence, the free object of $\mathcal {V}$ over A is $F/(F'F^m)$ , and it is easy to see that ${F/(F'F^m) \cong C_m^A}$ . Note that $\mathbf {Ab}(m) = {\cal {V}}^f$ .

If A is finite, then $C_m^A$ is finite and therefore LERF. Since $C_m^A$ is residually finite for arbitrary A, it follows from Proposition 3.2 that $C_m^A$ is always LERF. Let $\pi :F \to C_m^A$ be the canonical homomorphism. It follows from Theorem 3.1(i) that

(5-1) $$ \begin{align} \text{Cl}_{\mathbf{Ab}(m)}(H) = \mathrm{Cl}_{{\cal{V}}^f}^{F}(H) = \pi^{-1}(\mathrm{Cl}_{{\mathbf G}}^{C_m^A}(\pi(H))) = \pi^{-1}(\pi(H)) = HF'F^{\prime}_m \end{align} $$

as claimed.

(ii) Suppose that $\mathrm {Cl}_{\mathbf {Ab}(m)}(H)$ is finitely generated. Then A is finite by Theorem 3.1(ii).

Conversely, assume that A is finite. By Theorem 3.1(iii), it suffices to show that $\mathrm {Cl}_{\mathbf {Ab}(m)}(H)$ has finite index in F. It follows from Equation (5-1) and the homomorphism theorems that

(5-2) $$ \begin{align} F/\mathrm{Cl}_{\mathbf{Ab}(m)}(H) = F/\pi^{-1}(\pi(H)) \cong (F/F'F^m)/\pi(H). \end{align} $$

Since $F/F'F^m$ is finite, we are done.

(iii) It follows immediately from part (ii).

(iv) If $\mathrm {Cl}_{\mathbf {Ab}(m)}(H)$ is finitely generated, then A is finite by part (ii). Then $\mathrm {Cl}_{\mathbf {Ab}(m)}(H)$ has finite index in F and we can effectively compute the finite group $(F/F'F^m)/\pi (H)$ , which is isomorphic to $F/\mathrm {Cl}_{\mathbf {Ab}(m)}(H)$ by Equation (5-2). Now we proceed as in the proof of Theorem 4.4(v).

(v) By Theorem 3.1(iv).

(vi) Suppose that H is $\mathbf {Ab}(m)$ -dense. Let p be any prime dividing m. Since $\mathbf {Ab}(p)\subseteq \mathbf {Ab}(m)$ , then H is $\mathbf {Ab}(p)$ -dense.

Suppose now that H is not $\mathbf {Ab}(m)$ -dense. Then there exists a normal subgroup N of F such that $F/N\in \mathbf {Ab}(m)$ and $HN < F$ . Note that $F/N$ is a finite abelian group and $HN$ is contained in a maximal subgroup M of F. Since $F/N$ is abelian, we have $F' \leq N \leq M$ and so $M \lhd F$ . Now $M/N$ is a maximal subgroup of $F/N \in \mathbf {Ab}(m)$ , so $[F/N : M/N] = p$ for some prime p dividing m. Thus, $[F : M] = p$ and so $F/M \cong C_p \in \mathbf {Ab}(p)$ . However, $HM=M < F$ and therefore H is not $ \mathbf {Ab}(p)$ -dense.

(vii) By the argument in the proof of Theorem 4.4(vii).

(viii) Since $\text {Cl}_{\mathbf {Ab}(m)}(H) = \pi ^{-1}(\pi (H))$ by Equation (5-1), it suffices to note that the membership problem is decidable for every finitely generated subgroup of the group

$$ \begin{align*}F/(F'F^m) \cong \bigoplus_{a\in A} C_m,\end{align*} $$

which is straightforward.

(ix) By part (viii) and Proposition 2.1.

Proof. Write $F = F_A$ .

(i) Suppose that there exist $r\geq 1$ , primes $p_1,\ldots ,p_r$ , positive integers $k_1,\ldots ,k_r$ and $\mathbf {Ab}(p_i^{k_i})$ -clopen subgroups $H_i$ of F for $1\leq i \leq r$ such that $H= \bigcap _{i=1}^r H_i$ . Let $1\leq i \leq r$ . Then $F/\textrm {Core}_F(H_i) \in \mathbf {Ab}(p_i^{k_i}) \subset \mathbf {Ab}$ and so $H_i$ is $\mathbf {Ab}$ -clopen. Hence, ${H=\bigcap _{i=1}^rH_i}$ is $\mathbf {Ab}$ -clopen.

Suppose now that H is $\mathbf {Ab}$ -clopen. If $H=F$ , the result is trivial: take $r=1$ , ${H_1=H}$ and $p_1$ any prime. Suppose $H\neq F$ . Let $M(H)=F/\textrm {Core}_F(H)$ and $\varphi : F\rightarrow M(H)$ be the canonical surjective homomorphism. Note that $H=\varphi ^{-1}(\varphi (H))$ .

Also, since H is $\mathbf {Ab}$ -clopen, $M(H)$ is a (nontrivial) finite abelian group, hence, $F' \unlhd \textrm {Core}_F(H) \leq H$ and so $H\lhd F$ and $\textrm {Core}_F(H)=H$ . In particular, $\varphi (H)$ is trivial.

Since $M(H)$ is a nontrivial finite abelian group, there exist $r\geq 1$ , primes $p_1,\ldots , p_r$ and positive integers $k_1,\ldots ,k_r$ , $a_1,\ldots ,a_r$ such that

$$ \begin{align*}M(H)=\times_{i=1}^r C_{p_i^{k_i}}^{a_i}.\end{align*} $$

For $1\leq i \leq r$ , let $G_i=C_{p_i^{k_i}}^{a_i}$ and $\gamma _i:M(H)\rightarrow G_i$ be the projection of $M(H)$ onto its i th component. Since $\bigcap _{i=1}^r\gamma _i^{-1}(1) = 1 = \varphi (H)$ ,

$$ \begin{align*} H =\varphi^{-1}(\varphi(H))=\varphi^{-1}\bigg( \bigcap_{i=1}^r\gamma_i^{-1}(1)\bigg) =\bigcap_{i=1}^r \varphi^{-1}(\gamma_i^{-1}(1)).\end{align*} $$

Since $\gamma _i^{-1}(1)= \textrm {Ker} \ \gamma _i \unlhd M(H)$ , we get $\varphi ^{-1}(\gamma _i^{-1}(1)) \unlhd F$ . Finally, $F/\varphi ^{-1}(\gamma _i^{-1}(1)) \cong G_i \in \mathbf {Ab}(p_i^{k_i})$ and we obtain that $\varphi ^{-1}(\gamma _i^{-1}(1))$ is $\mathbf {Ab}(p_i^{k_i})$ -clopen. Setting $H_i=\varphi ^{-1}(\gamma _i^{-1}(1))$ , we get the result.

(ii) Let p be a prime. Since $\mathbf {Ab}(p) \subseteq \textbf {Ab}$ , if H is $\textbf {Ab}$ -dense, then H is $\mathbf {Ab}(p)$ -dense.

We now prove the other direction. Suppose that H is not $\textbf {Ab}$ -dense. Then there is a proper $\textbf {Ab}$ -clopen subgroup K of F containing H. By part (i), there exist a positive integer r, primes $p_1,\ldots ,p_r$ , positive integers $k_1,\ldots ,k_r$ and subgroups $K_1,\ldots ,K_r$ of F such that for $1\leq i \leq r$ , $K_i$ is $\mathbf {Ab}(p_i^{k_i})$ -clopen and $K=\bigcap _{i=1}^r K_i$ . As K is proper, there exists $1\leq i\leq r$ such that $K_i$ is proper. Since H is contained in $K_i$ , H is not $\mathbf {Ab}(p_i^{k_i})$ -dense. Therefore, H is not $\mathbf {Ab}(p_i)$ -dense by Theorem 5.1(vi).

(iii) First note that as for every prime p and every positive integer k, we have $\langle C_{p^{k}} \rangle \subseteq \mathbf {Ab}$ , so we have

$$ \begin{align*}\mathrm{{Cl}}_{\mathbf{Ab}}(H)\leq \bigcap_{p\in \mathbb{P}} \bigcap_{k\in \mathbb{N}}\mathrm{{Cl}}_{\mathbf{Ab}(p^{k})}(H).\end{align*} $$

We consider the reverse inclusion. By Theorem 2.5, $\mathrm {{Cl}}_{\mathbf {Ab}}(H)$ is the intersection of all the $\mathbf {Ab}$ -(cl)open subgroups of F containing H. Let K be an $\textbf {Ab}$ -clopen subgroup of F containing H. By part (i), there exist $r\geq 1$ , primes $p_1,\ldots ,p_r$ , positive integers $k_1,\ldots ,k_r$ and $\mathbf {Ab}(p_i^{k_i})$ -clopen subgroups $K_i$ of F for $1\leq i \leq r$ such that $K=\bigcap _{i=1}^r K_i$ . In particular, for each $1\leq i \leq r$ , $\mathrm {{Cl}}_{\mathbf {Ab}(p_i^{k_i})}(H)\leq K_i$ . Hence,

$$ \begin{align*}\bigcap_{p\in \mathbb{P}}\bigcap_{k\in \mathbb{N}}\mathrm{{Cl}}_{\mathbf{ Ab}(p^{k})}(H)\leq K\end{align*} $$

for every $\textbf {Ab}$ -clopen subgroup K of F containing H, yielding

$$ \begin{align*}\bigcap_{p\in \mathbb{P}}\bigcap_{k\in \mathbb{N}}\mathrm{{Cl}}_{\mathbf{Ab}(p^{k})}(H) \leq\mathrm{{Cl}}_{\mathbf{Ab}}(H).\end{align*} $$

The second equality follows from Theorem 5.1(i).

Proof. Suppose that A is infinite. By the proof of Theorem 4.4(vii) (which adapts directly to prove Theorem 5.1(vii)), H is not $\mathbf {Ab}(p)$ -dense for any prime p. Since $\mathbf {Ab}(p)$ is contained in N, $\mathbf {G}_p$ and Ab, it follows that H is neither N-dense nor $\mathbf {G}_p$ -dense nor Ab-dense.

Thus, we may assume that A is finite. Now item (i) $\Leftrightarrow $ (ii) follows from [Reference Margolis, Sapir and Weil14, Corollary 4.2(1)], item (ii) $\Leftrightarrow $ (iii) follows from [Reference Margolis, Sapir and Weil14, Corollary 3.5] and item (iii)  $\Leftrightarrow $  (iv) follows from Proposition 5.2(ii).