Proof. Let ${\mathcal D}={{\{\, D_n:n\in \omega \,\}}}\subseteq 2^{\mathbb G}$ be a collection of closed discrete subsets of ${\mathbb G}$. For brevity, call a point $g\in {\mathbb G}$ a vD-point of ${\mathcal D}$ if for every open $U\ni g$ there is a $D\in {\mathcal D}$ with the property $|U\cap D|=\omega $. The statement of the lemma is equivalent to claiming that there are no vD-points of ${\mathcal D}$. Suppose $g\in {\mathbb G}$ is a vD-point of ${\mathcal D}$. By translating each $D\in {\mathcal D}$ if necessary, we may assume that $g={1_{{\mathbb G}}} $.

Let ${\mathcal P}={{\{\,P_n:n\in \omega \,\}}} $ be a collection of closed scattered subsets of ${\mathbb G}$ such that for any $S\to {1_{{\mathbb G}}} $, there is a $P\in {\mathcal P}$ such that $|S\cap P|=\omega $. By requiring ${\mathcal P}$ to be closed under finite unions, we may assume that $S\subseteq ^* P$.

Pick a family ${{\{\,O_n:n\in \omega \,\}}}$ of open neighbourhoods of ${1_{{\mathbb G}}} $ such that $\overline {O_{n+1}}\subseteq O_n$ and $\bigcap _{n\in \omega }O_n=\{{1_{{\mathbb G}}} \}$. Put $P=\bigcup _{n\in \omega }P_n\cap \overline {O_n}$. One may verify that P is closed and scattered, and for any $S\to {1_{{\mathbb G}}} $, $S\subseteq ^* P$. Changing P if necessary, we may further require that $\alpha _P=\mathop{\mathrm{scl}}({1_{{\mathbb G}}} ,P)$ is the smallest one among all P with such properties.

Let $P'={{\{\,p\in P\setminus \{{1_{{\mathbb G}}} \}:\mathop{\mathrm{scl}}(p,P)\geq \alpha _P\,\}}} $. Note that ${1_{{\mathbb G}}} \not \in \overline {P'}$, and we may therefore assume (by taking an appropriate subset of P, if necessary) that $\mathop{\mathrm{scl}}({1_{{\mathbb G}}} ,P)=\mathop{\mathrm{scl}}(P)>\mathop{\mathrm{scl}}(p,P)$ for any $p\in P$ such that $p\not ={1_{{\mathbb G}}} $. Now

1. (1) P is a closed scattered subset of ${\mathbb G}$ such that $S\subseteq ^* P$ for every $S\to {1_{{\mathbb G}}} $; moreover, $\alpha _P=\mathop{\mathrm{scl}}(P)=\mathop{\mathrm{scl}}({1_{{\mathbb G}}} ,P)>\mathop{\mathrm{scl}}(p, P)$ for any $p\in P\setminus \{{1_{{\mathbb G}}} \}$, and $\alpha _P$ is the smallest possible.

Let $g\in {\mathbb G}$, and consider the family ${\mathcal D}_g={{\{\,D_n\cap (g\cdot P):n\in \omega \,\}}} $. Suppose g is not a vD-point of ${\mathcal D}_g$ for any $g\in {\mathbb G}$. For each $g_i\in {\mathbb G}$, pick an open neighbourhood $U_i\ni g_i$ such that $U_i\cap (g_i\cdot P)\cap D_n=F_i^n$ is finite for every $n\in \omega $. Put $D_n'=D_n\setminus \bigcup _{i\leq n}F_i^n$. Then ${1_{{\mathbb G}}} $ is a vD-point of ${\mathcal D}'={{\{\,D_n':n\in \omega \,\}}}$, and therefore, ${1_{{\mathbb G}}} \in \overline {\bigcup {\mathcal D}'}$.

Let $S\subseteq \bigcup {\mathcal D}'$ be an infinite sequence such that $S\to g_i$ for some $g_i\in {\mathbb G}$. Then by (1), $S\subseteq ^* U_i\cap (g_i\cdot P)$. Since every $D\in {\mathcal D}'$ is closed discrete, we may assume that $S={\langle s_n : n\in \omega \rangle }$ is such that $s_n\in D_{m(n)}'$ for some $m(n)\geq n$. Let $n>i$ be such that $s_n\in U_i\cap (g_i\cdot P)$. Then $s_n\in F_i^{m(n)}$, $i<n<m(n)$, contradicting $s_n\in D_{m(n)}'=D_{m(n)}\setminus \bigcup _{i\leq m(n)}F_i^{m(n)}$. Thus no such S exists, making $\bigcup {\mathcal D}'$ almost disjoint from every convergent sequence in ${\mathbb G}$, contradicting ${1_{{\mathbb G}}} \in \overline {\bigcup {\mathcal D}'}$ and the sequentiality of ${\mathbb G}$.

We may therefore assume that $D\subseteq P$ for every $D\in {\mathcal D}$ and some $g\in {\mathbb G}$ is a vD-point of ${\mathcal D}$. Note that $g\in P$, since P is closed. Let $p\in P$ be a vD-point of ${\mathcal D}$ such that $\mathop{\mathrm{scl}}(p,P)$ is the smallest. By picking a neighbourhood $U\ni p$ relatively open in P such that $\mathop{\mathrm{scl}}(x,P)<\mathop{\mathrm{scl}}(p,P)$ for any $x\in \overline {U}\setminus \{p\}$ and restricting ${\mathcal D}$ to U, if necessary, we may assume that p is the only vD-point of ${\mathcal D}$. Using an argument similar to the one in the previous paragraph, by possibly removing a finite subset from each $D\in {\mathcal D}$, we may assume that ${\mathbb D}=\bigcup {\mathcal D}\cup \{p\}$ is closed, p is the only nonisolated point of $\mathbb D$ and p is a vD-point of ${\mathcal D}$.

Consider the translation ${\mathcal D}''={{\{\,D\cdot p^{-1}:D\in {\mathcal D}\,\}}}$ of ${\mathcal D}$. Suppose ${1_{{\mathbb G}}} \in \overline {\bigcup {\mathcal D}''\setminus P}$. By the closedness of $\mathbb D$ and property (1), the set $\bigcup {\mathcal D}''\setminus P$ contains no infinite converging sequence, contradicting the sequentiality of ${\mathbb G}$.

1. (2) There exists a countable family $\mathcal D$ of closed discrete subsets of ${\mathbb G}$ such that $\bigcup {\mathcal D}\subseteq P$, ${1_{{\mathbb G}}} $ is the only nonisolated point of $\bigcup {\mathcal D}\cup \{{1_{{\mathbb G}}} \}$, which is closed in ${\mathbb G}$, and ${1_{{\mathbb G}}} $ is a vD-point of ${\mathcal D}$.

Suppose there exists an $S\to {1_{{\mathbb G}}} $ such that $(S\cdot p)\setminus P$ is infinite for every $p\in P\setminus \{{1_{{\mathbb G}}} \}$. We may then pick an infinite sequence $S'\subseteq S\cdot S$ so that $S'\to {1_{{\mathbb G}}} $ and $S'\subseteq {\mathbb G}\setminus P$, contradicting (1). Thus for every sequence $S\to {1_{{\mathbb G}}} $, there exists a $p\in P\setminus \{{1_{{\mathbb G}}} \}$ such that $(S\cdot p)\subseteq ^* P$.

Suppose $A\subseteq {\mathbb G}$ is such that for some ordinal $\beta $, $\mathop{\mathrm{scl}}(a,P)\leq \beta <\alpha _P$ for every $a\in A\cap P$. Then there exists a sequence $S\to {1_{{\mathbb G}}} $ such that $S\setminus \bigcup _{a\in F}(P\cdot a^{-1})$ is infinite for every $F\in [A]^{<\omega }$.

Indeed, suppose no such S exists, and let $A={{\{\,p_n:n\in \omega \,\}}} $ list all the points in A. For each $n\in \omega $, find a neighbourhood $U_n\ni p_n$ relatively open in P so that $\mathop{\mathrm{scl}}(\overline {U_n}\cap P)\leq \beta $ if $p_n\in P$, and put $P_n'=(\overline {U_n}\cap P)\cdot p_n^{-1}$. If $p_n\not \in P$, put $P_n'=\varnothing $. Note that ${\mathcal P}'={{\{\,P_n':n\in \omega .\,\}}}$ is a collection of closed scattered subsets of ${\mathbb G}$ with the property that $\mathop{\mathrm{scl}}(P_n)\leq \beta $ for every $n\in \omega $, and for every $S\to {1_{{\mathbb G}}} $, there exists an $F\in [\omega ]^{<\omega }$ such that $S\subseteq ^* \bigcup _{n\in F}P_n'$.

Repeating the construction used to build P out of $P_n$ at the beginning of this argument, we may construct a closed scattered $P'\subseteq {\mathbb G}$ such that $\mathop{\mathrm{scl}}(P')\leq \beta $ and $S\subseteq ^* P'$ for every $S\to {1_{{\mathbb G}}} $, contradicting the minimality of $\alpha _P$ in (1).

Let $P\setminus \{{1_{{\mathbb G}}} \}={{\{\,p_n:n\in \omega \,\}}}$ list all the points in P other than ${1_{{\mathbb G}}} $. For each $n\in \omega $, pick an open $O_n\ni {1_{{\mathbb G}}} $ such that $\beta =\mathop{\mathrm{scl}}(p_n, P)=\mathop{\mathrm{scl}}(\overline {O_n\cdot p_n}\cap P)<\alpha _P$, $\overline {O_{n+1}}\subseteq O_n$, and $\bigcap _{n\in \omega }O_n=\{{1_{{\mathbb G}}} \}$.

Restricting ${\mathcal D}$ to $O_0$ if necessary, assume that $\bigcup {\mathcal D}\subseteq O_0$. By induction, pick disjoint closed discrete $D_n'\subseteq \cup {\mathcal D}$ so that $D_n'\subseteq O_n$ and each $D_n$ is covered by finitely many $D_n'$. To see that this is possible, put $D_n'=(D_n\cap O_n)\cup ((O_n\setminus O_{n+1})\cap (\bigcup {\mathcal D}\setminus \bigcup _{i<n}D_i'))$ and observe that the intersection inside the second pair of parentheses is a closed and discrete subspace of ${\mathbb G}$, since ${1_{{\mathbb G}}}$ is the only nonisolated point of $\mathbb D$. Put ${\mathcal D}'={{\{\,D_n':n\in \omega \,\}}}$. Note that ${1_{{\mathbb G}}} $ is a vD-point of ${\mathcal D}'$. To simplify notation, we will assume that $D_n\subseteq O_n$ in what follows.

Let $n\in \omega $. By the choice of $O_n$, $D_n\subseteq O_n\subseteq O_i$, so $D_n\cdot p_i\subseteq O_i\cdot p_i$, whenever $i\leq n$. Thus there is a $\beta <\alpha _P$ such that $\mathop{\mathrm{scl}}(a,P)\leq \beta $ for every $a\in A_n=\bigcup _{i\leq n}D_n\cdot p_i$. Find a sequence $S_n\to {1_{{\mathbb G}}} $ such that $S_n\setminus \bigcup _{a\in F}(P\cdot a^{-1})$ is infinite for every $F\in [A_n]^{<\omega }$. Let $D_n={{\{\,d_i:i\in \omega \,\}}}$ and $S_n={{\{\,s_i:i\in \omega \,\}}}$ be 1-1 listings of $D_n$ and $S_n$. For each $i\in \omega $, pick an $m(i)>n$ so that $m(i)$ is strictly increasing, $s_{m(i)}\cdot d_i\cdot p_j\not \in P$ for every $i\in \omega $ and $j\leq n$, and $e_i^n=s_{m(i)}\cdot d_i\in O_n$. Note that the latter is possible, since $S\to {1_{{\mathbb G}}}$ and $d_i\in D_n\subseteq O_n$. Put $B_n={{\{\,e_i^n:i\in \omega \,\}}}$ and $B=\bigcup _{n\in \omega }B_n$, and note that each $B_n$ is a closed and discrete subspace of ${\mathbb G}$.

Now, ${1_{{\mathbb G}}} \in \overline {B}$. Indeed, let $U\ni {1_{{\mathbb G}}} $ be any open neighbourhood of ${1_{{\mathbb G}}} $. Find an open $V\ni {1_{{\mathbb G}}} $ such that $V\cdot V\subseteq U$. Then $V\cap D_n$ is infinite for some $n\in \omega $, since ${1_{{\mathbb G}}} $ is a vD-point of ${\mathcal D}$. Also, $S_n\subseteq ^* V$. Thus for some large enough $i\in \omega $, both $d_i\in V$ and $s_{m(i)}\in V$, showing that $e_i^n\in U$.

Let $C\subseteq B$ be an infinite sequence such that $C\to g$ for some $g\in {\mathbb G}$. Since each $B_n$ is closed and discrete, we may assume that $C={{\{\,e_{i(k)}^{n(k)}:k\in \omega \,\}}}$, where $n(k)$ is strictly increasing. Since $e_i^n\in O_n$, $C\to {1_{{\mathbb G}}} $. Thus, there exists a $j\in \omega $ such that $C\cdot p_j\subseteq ^* P$. Pick a $k\in \omega $ large enough so that $n(k)>j$ and $e_{i(k)}^{n(k)}\cdot p_j\in P$. At the same time, $e_{i(k)}^{n(k)}\cdot p_j=s_{m(i(k))}\cdot d_{i(k)}\cdot p_j\not \in P$ by the choice of $s_{m(i)}$, a contradiction.

Proof. Note that ${\mathbb G}$ is not Fréchet by Lemma 6 and thus does not contain a closed subspace homeomorphic to ${\mathbb D}(\omega )$ by Proposition 2.

Let ${\mathcal D}={{\{\,D_n:n\in \omega \,\}}}$ be a $\pi $-network at ${1_{{\mathbb G}}} $ such that each $D\in {\mathcal D}$ is dense in itself. By translating each element of ${\mathcal D}$ if necessary, we may assume that ${1_{{\mathbb G}}} \in D$ for every $D\in {\mathcal D}$.

Fix open $O_n\ni {1_{{\mathbb G}}} $ so that $\overline {O_{n+1}}\subseteq O_n$ and $\bigcap _{n\in \omega }O_n=\{{1_{{\mathbb G}}} \}$.

Let ${\mathcal P}={{\{\,P_n:n\in \omega \,\}}} \subseteq \mathop {\mathbf {nwd}}({\mathbb G})$ be such that for every $S\to {1_{{\mathbb G}}} $, there exists a $P\in {\mathcal P}$ such that $|S\cap P|=\omega $. Just as in the proof of Lemma 22, we may construct a $P\in \mathop {\mathbf {nwd}}({\mathbb G})$ such that for every $S\to {1_{{\mathbb G}}} $, $S\subseteq ^* P$. By taking the closure of P if necessary, we may assume that P is closed.

Let $g\in {\mathbb G}$. Define $d(g)=\mathop {\mathfrak {so}}(g,{\mathbb G}\setminus P)$. Let $\alpha _P=d({1_{{\mathbb G}}} )$. Note that $\alpha _P>1$ by the choice of P. We proceed to prove the following claim by induction on $\alpha $.

1. (3) Let $p\in P$ and $d(p)=\alpha $ for some $\alpha <\omega _1$. There exists a $T\subseteq {\mathbb G}\setminus P$ and a neighbourhood assignment $W:T\to \tau ({\mathbb G})$ such that the following properties hold:

   1. (a) $p\in [T]_{\alpha }$, if $p'\in \overline {T}$, then $d(p')=\mathop {\mathfrak {so}}(p',T)$;

   2. (b) $g\in W(g)\setminus P$ for every $g\in T$, the $W(g)$ are disjoint; if $s_i\in W(g_i)\setminus P$ is such that $s_i\to g$ for some $g\in {\mathbb G}$ and all $g_i$ are distinct, then $g_i\to g$;

Let $d(p)=\alpha $ for some $p\in P$. If $\alpha =1$, there exists an infinite sequence of $g_i\in {\mathbb G}\setminus P$ such that $g_i\to p$. Thinning out the sequence and reindexing, if necessary, pick disjoint open $W(g_i)\ni g_i$ so that $W(g_i)\subseteq O_i\cdot p$. Put $T={{\{\,g_i:i\in \omega \,\}}}$. Properties (a) and (b) are easy to check.

Thus we can assume $\alpha>1$. Let $p^n\to p$ and $\alpha _n<\alpha $ be such that $p^n\in O_n\cdot p$ and $p^n\in [{\mathbb G}\setminus P]_{\alpha _n}$ for every $n\in \omega $. Since $d(p^n)\leq \alpha _n<\alpha $, by the induction hypothesis there exist $T_n\subseteq {\mathbb G}\setminus P$ and $W_n:T_n\to \tau ({\mathbb G})$ that satisfy (3). Pick a sequence of open disjoint $V_n\ni p^n$ such that $V_n\subseteq O_n\cdot p$ after thinning out and reindexing if necessary. By passing to subsets and reindexing again, if necessary, we may assume that the $\overline {T_n}$ are disjoint, $T_n\subseteq O_n\cdot p\cap V_n$, and $W_n(g)\subseteq O_n\cdot p\cap V_n$ for every $n\in \omega $ and $g\in T_n$. Let $T=\bigcup _{n\in \omega }T_n$, and define $W:T\to \tau ({\mathbb G})$ by $W(g)=W_n(g)$ whenever $g\in T_n$.

By the choice of $T_n$ and $O_n$, $\overline {T}=\{p\}\cup \bigcup _{n\in \omega }\overline {T_n}$. If $p'\in \overline {T_n}$, then $d(p')=\mathop {\mathfrak {so}}(p', T_n)=\mathop {\mathfrak {so}}(p', T)$ by the inductive hypothesis and the choice of $T_n$. Since $d(p)=(\sup _n\alpha _n)+1$ and $d(p^n)\leq \alpha _n$, $d(p)=\mathop {\mathfrak {so}}(p,T)$.

Let $s_i\in W(g_i)\setminus P$ for some $g_i\in T$ be such that $s_i\to g$. By thinning out and reindexing, we may assume that either $g_i\in T_n$ for some fixed $n\in \omega $ or $g_i\in T_{n(i)}\subseteq O_{n(i)}\cdot p$ for some strictly increasing $n(i)$. In the first case, $g_i\to g\in P$ by the choice of $T_n$. Otherwise, $s_i\in W_{n(i)}(g_i)\subseteq O_{n(i)}\cdot p$, so $s_i\to p$ by the choice of $O_n$, contradicting $s_i\in {\mathbb G}\setminus P$ and $d(p)=\alpha>1$.

Pick T and W that satisfy (3) for $p={1_{{\mathbb G}}} $, and let $T={{\{\,t_n:n\in \omega \,\}}}$ be a 1-1 enumeration of the points of T. Pick $U_n\subseteq (W(t_n)\setminus P)\cdot t_n^{-1}$ so that $U_{n+1}\subseteq U_n$, $\bigcap _{n\in \omega }U_n=\{{1_{{\mathbb G}}} \}$, and ${1_{{\mathbb G}}}\in \overline {{{\{\,t_k:U_k\cdot t_k\subseteq O_n\,\}}}}$ for every $n\in \omega $. Note that each $U_n\cdot t_n\subseteq {\mathbb G}\setminus P$. Let $k\in \omega $, and show that

1. (4) there exists a closed discrete subset $E_k\subseteq D_k$ such that $E_k={{\{\,e_n^k:n\in \omega \,\}}}$ and $e_n^k\in U_n$ for every $n\in \omega $.

If no such $E_k$ exists, then $U_n\cap D_k$ form a countable base of neighbourhoods of ${1_{{\mathbb G}}} $ in $D_k$. Since ${1_{{\mathbb G}}} \in D_k$ and each $D_k$ is dense in itself, this implies the existence of a closed copy of $\mathbb D(\omega )$ in ${\mathbb G}$, contradicting the sequentiality of ${\mathbb G}$ as noted at the beginning of this proof.

Consider the set $D^k={{\{\,d^n:d^n=e_n^k\cdot t_n, U_n\cdot t_n\subseteq O_k, n\in \omega \,\}}}$. Then $D^k\subseteq O_k\setminus P$ for every $k\in \omega $ and $d^n\in W(t_n)$ for every $n\in \omega $ by $e_n^k\in U_n$ and the choice of $U_n$. Suppose $d^{n(i)}\to d$ for some $d\in {\mathbb G}$. By (3b) $t_{n(i)}\to d$ so $e_{n(i)}^k=d^{n(i)}\cdot t_{n(i)}^{-1}\to {1_{{\mathbb G}}} $, contradicting the choice of $e_n^k$. Thus each $D^k\subseteq O_k$ is closed and discrete in ${\mathbb G}$.

Suppose $S\to g$ for some $g\in {\mathbb G}$ is an infinite sequence such that $S\subseteq \bigcup _{k\in \omega }D^k$. Since each $D^k$ is closed discrete, we may assume that $S={{\{\,s_n:n\in \omega \,\}}}$, where $s_n\in D^{k(n)}$ for some strictly increasing $k(n)$. Then $s_n\in O_{k(n)}$ and $S\to {1_{{\mathbb G}}} $, contradicting $S\subseteq {\mathbb G}\setminus P$ and the choice of P.

Let $U\ni {1_{{\mathbb G}}} $ be open, and find an open $V\ni {1_{{\mathbb G}}} $ such that $V\cdot V\subseteq U$. Let $k\in \omega $ be such that $D_k\subseteq V$, and let $t_n$ be such that $U_n\cdot t_n\subseteq O_k$ and $t_n\in V$. Then $d^n=e_n^k\cdot t_n\in D^k\cap V\cdot V$. Thus ${1_{{\mathbb G}}} \in \overline {\bigcup _{k\in \omega }D^k}$, contradicting the sequentiality of ${\mathbb G}$.

Proof. The proof proceeds by induction on $\mathop {\mathfrak {so}}(x,S)$. The case $\mathop {\mathfrak {so}}(x,S)=0$ is trivial, so assume $\mathop {\mathfrak {so}}(x,S)=\alpha +1$, and the lemma is proved for all successor $\beta \leq \alpha $. Pick a sequence $T\subseteq X$ such that $T\to x$ and $\mathop {\mathfrak {so}}(y,S)=\beta _y\leq \alpha $ for every $y\in T$, and consider the two alternatives that follow from the inductive hypothesis.

First, suppose the set $T'={{\{\,y:y\in \overline {I_y\cap S}\text { for some }I_y\in {\mathcal I}\,\}}}$ is infinite. If the family ${\mathcal I}'={{\{\,I_y:y\in T'\,\}}}$ is finite, then there is an $I\in {\mathcal I}'$ such that $x\in \overline {S\cap I}$. Otherwise put ${\mathcal I}^*=\{{\mathcal I}'\}$.

Alternatively, assume for every $y\in T$, there is a countable ${\mathcal I}^*_y\subseteq [{\mathcal I}]^{\omega }$ such that $y\in \overline {S\cap \bigcup {\mathcal I}'}$ for any ${\mathcal I}'$ such that ${\mathcal I}'\cap {\mathcal I}''$ is infinite for every ${\mathcal I}''\in {\mathcal I}^*_y$. Put ${\mathcal I}^*=\bigcup _{y\in T}{\mathcal I}^*_y$.

Proof. Suppose ${\mathcal I}$ is not tame, and let $A\in {\mathcal I}^+$, $f:A\to \omega $ witness this. Using the property of ${\mathcal I}$ from the statement of the lemma, find $Y\subseteq A$, $Y\in {\mathcal I}^+$ such that $\overline {Y\setminus I}=\overline {Y}$ for any $I\in {\mathcal I}$. Let $y\in Y$. Since ${\mathcal I}$ contains $\{y\}$ and X is sequential, there exists a sequence $T\subseteq \overline {Y}\setminus \{y\}$ such that $T\to y$. Let $T={\langle y_i : i\in \omega \rangle }$, $I_i=f^{-1}(i)\in {\mathcal I}$, and for every $i\in \omega $, pick a subset $S_i\subseteq Y\setminus \bigcup _{j<i}I_j$ such that $y_i\in \overline {S_i}\not \ni y$.

Note that ${\mathcal I}_f={{\{\,I_i:i\in \omega \,\}}}$ is a cover of $S=\bigcup _{i\in \omega }S_i$ and $y\in \overline {S}$. Since $I_i\cap S\subseteq \bigcup _{j\leq i}S_i$ and $y\not \in \overline {\bigcup _{j\leq i}S_i}$, the first alternative of Lemma 24 fails, so there exists a countable ${\mathcal I}^*_y\subseteq [{\mathcal I}_f]^{\omega }$ such that $y\in \overline {S\cap \bigcup {\mathcal I}'}$ for any ${\mathcal I}'\subseteq {\mathcal I}$ with the property that ${\mathcal I}'\cap {\mathcal I}''$ is infinite for every ${\mathcal I}''\in {\mathcal I}^*_y$.

Let ${\mathcal J}={{\{\,f[\bigcup {\mathcal I}'']:{\mathcal I}''\in {\mathcal I}^*_y, y\in Y\,\}}} \subseteq 2^{\omega }$. Since $f[{{\mathcal I}}|_{A}]$ is $\omega $-hitting, there exists a $J\in f[{{\mathcal I}}|_{A}]$ such that $J\cap J'$ is infinite for every $J'\in {\mathcal J}$. Let ${\mathcal I}'={{\{\,f^{-1}(n):n\in J\,\}}}$. Then ${\mathcal I}'\cap {\mathcal I}''$ is infinite for every ${\mathcal I}''\in {\mathcal I}^*_y$, so $y\in \overline {f^{-1}[J]}$ for every $y\in Y$. Thus $Y\subseteq \overline {f^{-1}[J]}\in {\mathcal I}$, contradicting $Y\in {\mathcal I}^+$.

Proof. For $\mathop {\mathbf {cpt}}({\mathbb G})$, the statement can be proved directly. For $\mathop {\mathbf {nwd}}({\mathbb G})$ and $\mathop {\mathbf {csc}}({\mathbb G})$, it is sufficient to establish the properties listed in Lemma 25. In the case of $\mathop {\mathbf {nwd}}({\mathbb G})$, one may pick $Y=\mathop {\mathrm {Int}}(\overline {A})\cap A$, while for $\mathop {\mathbf {csc}}({\mathbb G})$, the choice of the full Cantor-Bendixson derivative of A as Y satisfies the conditions of Lemma 25.

Proof. That each of the ideals is tame follows from Lemma 26. The invariance is trivial.

Since $\mathop {\mathbf {nwd}}({\mathbb G})$ never satisfies 2 for a nonmetrizable ${\mathbb G}$ (see [Reference Hrušák and Ramos-García39], Proposition 5.2), we may assume that $\mathop {\mathbf { nwd}}({\mathbb G})$ satisfies 1. Suppose $\mathop {\mathbf {csc}}({\mathbb G})$ satisfies 2. Then there exists a countable ${\mathcal D}\subseteq \mathop {\mathbf {csc}}^+({\mathbb G})$ such that for any nonempty open $U\subseteq {\mathbb G}$, there exists a $D\in {\mathcal D}$ with the property $D\setminus U\in \mathop {\mathbf {csc}}({\mathbb G})$. By replacing each D with a full Cantor-Bendixson derivative of itself, we may assume that each D is dense in itself. Applying Lemma 23, we arrive at a contradiction. Thus $\mathop {\mathbf {csc}}({\mathbb G})$ does not satisfy 2.

Suppose $\mathop {\mathbf {csc}}({\mathbb G})$ satisfies 1. If $\mathop {\mathbf {cpt}}({\mathbb G})$ satisfies 2, there exists a countable family ${\mathcal D}$ of closed, noncompact subsets of ${\mathbb G}$ such that for any open $U\subseteq {\mathbb G}$, there exists a $D\in {\mathcal D}$ such that $D\setminus U$ is compact. By picking an infinite closed discrete subset in each $D\in {\mathcal D}$ and applying Lemma 22, we arrive at a contradiction. Thus either $\mathop {\mathbf {csc}}({\mathbb G})$ does not satisfy 1 or $\mathop {\mathbf {cpt}}({\mathbb G})$ does not satisfy 2.

Since ${\mathbb G}$ is not $k_{\omega }$, $\mathop {\mathbf {cpt}}({\mathbb G})$ cannot satisfy 1.

Proof. It suffices to note that

1. 1. ${\mathbb Q}_{\omega ^{\alpha }}\times {\mathbb Q}_{\omega ^{\beta }}\simeq {\mathbb Q}_{\omega ^{\beta }}$ if $\alpha <\beta <\omega _1$,

2. 2. ${\mathbb Q}_{\omega ^{\alpha }}\times {\mathbb Q}_{\omega _1}$ is not sequential if $0<\alpha <\omega _1$,

3. 3. ${\mathbb Q}_{0}\times {\mathbb Q}_{0}\simeq {\mathbb Q}_{0}$, and

4. 4. ${\mathbb Q}_{0}\times {\mathbb Q}_{\omega _1}\simeq {\mathbb Q}_{\omega _1}\times {\mathbb Q}_{\omega _1}\simeq {\mathbb Q}_{\omega _1}$.

Proof. Since $\mathbf {t}>\omega _1$ implies the existence of a separable nonmetrizable Fréchet group (see, for example [Reference Hrušák and Ramos-García38]), we may assume that $\mathbf { t}=\omega _1$.

Let $X=D\,\cup\, \omega _1$ be a countably compact $\gamma {\mathbb N}$ space (see [Reference Nyikos, van Mill and Reed48], Example 2.2) where D is the set of isolated points, disjoint from $\omega _1$, which has the usual topology. Let $X\cup \{\infty \}$ be the one-point compactification of X, which is also a subspace of some boolean group H that is (algebraically) generated by $X\cup \{\infty \}$. We shall assume that $X\cup \{\infty \}$ is linearly independent over H (in particular, this means $0_H\not \in X\cup \{\infty \}$). The free boolean group over $X\cup \{\infty \}$ (see [Reference Sipacheva73]) would have all the desired properties (in fact, it is not difficult to show that any group satisfying the properties above is naturally isomorphic to the free boolean group over $X\cup \{\infty \}$). Below we use the convention that the elements of such a group are finite sets of elements of $X\cup \{\infty \}$ with the symmetric difference as the group operation.

Let ${\mathbb G}$ be the subgroup of H generated by X, and let $A\subseteq {\mathbb G}$ be such that ${0_{{\mathbb G}}}\in \overline {A}\setminus A$ (here the closure is taken in the topology induced by H). We must show that there exists a sequence $S\subseteq A$ such that $S\to x\in {\mathbb G}\setminus A$. Suppose no such sequence exists.

Let $n\in \omega $ be the smallest number such that ${0_{{\mathbb G}}}\in \overline {A\cap \sum ^nX}$. Note that such an n exists by the definition of the topology on H. We will assume that $A\subseteq \sum ^nX$. By the minimality of n (truncating A if necessary), we may assume that $|a|=n$ for every $a\in A$. Write an arbitrary $a\in A$ as $a=d+w$, where $d\in {\langle {D}\rangle }$ and $w\in {\langle {\omega _1}\rangle }$, and put $\delta (a)=|d|$. Note that for every $k\leq n$ the set $A_k={{\{\,a\in A:\delta (a)\leq k\,\}}}$ is a sequentially closed subset of A.

Let $k\leq n$ be the smallest such that ${0_{{\mathbb G}}}\in \overline {A_k}$. Replacing A with $A_k$ and using the minimality of k, we may assume (again truncating A if necessary) that $\delta (a)=k$ for every $a\in A$. Let $D_A=\bigcup {{\{t\in D:t\in a\in A\}}}$, and suppose $D_A$ is infinite. Note that $\sum ^nX$ is sequentially compact. Using this and the property of $D_A$, we may pick a convergent sequence $S\subseteq A$ such that $S\to x$ for some $x\in \sum ^nX$ and for each $s\in S$, there is a $t_s\in s\cap D$ such that ${{\{\,t_s:s\in S\,\}}} \to \alpha \in \omega _1$. Then $\delta (x)<k$, so $x\not \in A$.

Thus we may assume that $D_A$ is finite. Note that this implies that $D_A$ is empty (otherwise ${0_{{\mathbb G}}}\not \in \overline {A}$). Therefore $A\in \sum ^n\omega _1$. Define $l\leq n$ to be the largest with the following property: for any $\alpha <\omega _1$, there exists an $a\in A$ such that $|a\setminus \alpha |\geq l$. Note that we may assume that $l\geq 1$; otherwise, A is countable with a metrizable closure.

Suppose $l\geq 2$. Recursively pick a sequence $a_i\in A$ such that for some distinct $\alpha _i,\beta _i\in a_i$, $\alpha _{i+1},\beta _{i+1}>\max \{\alpha _i,\beta _i\}$. By passing to a subsequence if necessary, we may assume that $a_i\to a\in \sum ^n\omega _1$. Since $\alpha _i,\beta _i\to \gamma $ for some $\gamma \in \omega _1$, $|a|<n$, showing that $a\not \in A$. We may thus assume that $l=1$.

This implies the existence of an $\alpha \in \omega _1$ such that every $a\in A$ can be written as $a=\{\beta _a\}+b_a$, where $\beta _a>\alpha +1$ and $b_a\in [\alpha +1]^{n-1}$. If $n>1$, the set $A'={{\{\,b_a:a\in A\,\}}} $ is a sequentially closed (and therefore compact) subset of H such that ${0_{{\mathbb G}}}\not \in A'$ (otherwise $A\cap \omega _1\not =\varnothing $, contradicting the choice of A and $n>1$). Now $U=H\setminus (A'+({{\{\,\beta :\beta>\alpha +1\,\}}}\cup \{\infty \}))$ is an open neighbourhood of ${0_{{\mathbb G}}}$ such that $U\cap A=\varnothing $, contradicting the choice of A. Hence $n=1$, implying ${0_{{\mathbb G}}}\not \in \overline {A}$, a contradiction.

Question 1. Does there exist a (separable, or even countable) sequential non-Fréchet group with a non-sequential square?

Question 2. Does there exist a Fréchet group with a non-Fréchet square?

Question 3. Does there exist a separable sequential group that is neither $c_{\omega }$ nor metrizable?

Question 4. Are sequential $c_{\omega }$-spaces preserved by finite products?