Proof The proof of (ii) is the same as (i). So here we only prove (i). Since C is uniform I-large, we pick a uniform idempotent $p \in I\cap U_C$ . Define ${C^\star = \{s \in C: s^{-1}C \in p \}}$ , so by [Reference Hindman and Strauss3, Lemma 4.14], for any $s \in C^\star $ , $s^{-1}C^\star \in p$ . For each $F \in \mathcal {P}_f(C^\star )$ , define $S_F = C^\star \cap \bigcap _{s \in F}s^{-1}C^\star $ . So $S_F \in p$ .

Let $V = \bigcap _{F \in \mathcal {P}_f(C^\star )}U_{S_F}$ . So $p \in V$ . Now let us show that V is a semigroup of $\beta S$ . Observe that for each $F \in \mathcal {P}_f(C^\star )$ and each $s \in S_F$ , if $H = \{ s \} \cup Fs$ , then $sS_H \subseteq S_F$ . Since for each $t \in S_H$ , we have $st \in C^\star $ , and since for each $r \in F$ , $rs \in H$ , so $rst \in C^\star $ . Hence $st \in S_F$ , which means $sS_H \subseteq S_F$ . Then by [Reference Hindman and Strauss3, Theorem 4.20], V is a semigroup of $\beta S$ .

Now well order $\mathcal {P}_f(C^\star )$ by $<$ as a $\kappa $ -sequence. Now we define $x_F$ for each ${F \in \mathcal {P}_f(C^\star )}$ such that $Fx_F \cap Hx_H = \emptyset $ and $x_F \neq x_H$ whenever F and H are distinct elements of $\mathcal {P}_f(C^\star )$ . Assume we have obtained $\{x_F: F < H \}$ . Since S is very weakly left cancellative, $|\{y \in S: Hy \cap \bigcup _{F < H}Fx_F \neq \emptyset \}| < \kappa $ , while $S_H \in p$ so $S_H$ has size $\kappa $ . Then we pick $x_H \in S_H \setminus (\{y \in S: Hy \cap \bigcup _{F < H}Fx_F \neq \emptyset \} \cup \{x_F: F < H \})$ .

By Lemma 2.1(i), there is a family $\{ \mathcal {A}_\alpha : \alpha < \delta \}$ of almost disjoint subsets of $\mathcal {P}_f(C^\star )$ such that for any $F \in \mathcal {P}_f(C^\star )$ and any $\alpha < \delta $ there is some $G \in \mathcal {A}_\alpha $ such that $F \subseteq G$ . Let $A_\alpha = \bigcup _{F \in \mathcal {A}_\alpha }Fx_F$ for each $\alpha \in \delta $ . Notice that $\{A_\alpha : \alpha < \delta \}$ is an almost disjoint family of subsets of C. Now let us show each $A_\alpha $ is uniform I-large.

Fix some $\alpha < \delta $ . Observe that $\{H: H \in \mathcal {A}_\alpha \wedge F \subseteq H \}$ has size $\kappa $ for each $F \in \mathcal {P}_f(C^\star )$ , so $X_F = \{x_H: H \in \mathcal {A}_\alpha \wedge F \subseteq H \}$ has size $\kappa $ and $\{X_F: F \in \mathcal {P}_f(C^\star ) \}$ has the $\kappa $ -uniform finite intersection property [Reference Hindman and Strauss3, Definition 3.60]. Then by [Reference Hindman and Strauss3, Theorem 3.62], we take a uniform ultrafilter $q \in \beta S$ such that $\{X_F: F \in \mathcal {P}_f(C^\star ) \} \subseteq q$ . For any $F \in \mathcal {P}_f(C^\star )$ , if $x_H \in X_F$ , then $H \in \mathcal {A}_\alpha $ and $F \subseteq H$ , so $S_H \subseteq S_F$ , while $x_H \in S_H$ , hence $X_F \subseteq S_F$ , which implies that $q \in V$ .

For each $s \in C^\star $ , and each $H \in \mathcal {A}_\alpha $ satisfying $s \in H$ , we have $sx_H \in Hx_H \subseteq A_\alpha $ , so $X_{\{ s \}} \subseteq s^{-1}A_\alpha $ . Hence $s^{-1}A_\alpha \in q$ , which means $sq \in U_{A_\alpha }$ . Since s is arbitrary in $C^\star $ , we have $C^\star q \subseteq U_{A_\alpha }$ , so $cl C^\star q \subseteq U_{A_\alpha }$ . Note that $V \subseteq U_{C^\star } = cl C^\star $ , so ${Vq \subseteq U_{A_\alpha }}$ . Also note that $Vq$ is a left ideal of V, so we can pick an idempotent $r \in Vq$ which is minimal in V, hence $r \in U_{A_\alpha } \cap K(V)$ . Observe that $V \cap I \neq \emptyset $ since $p \in V \cap I$ , so $V \cap I$ is an ideal of V, and thus $K(V) \subseteq V \cap I \subseteq I$ , so $r \in U_{A_\alpha } \cap I$ . By Lemma 2.2, U is a left ideal of $\beta S$ , then $r \in Vq \subseteq \beta S q \subseteq \beta S U \subseteq U$ , so r is uniform, therefore $A_\alpha $ is uniform I-large.

Proof Take a quasi-central set A in S. Then there is some idempotent ${p \in cl K(\beta S) \cap U_A}$ . Note that U is a closed ideal of $\beta S$ , so $cl K(\beta S) \subseteq U$ , which implies that p is uniform, so A is uniform $cl K(\beta S)$ -large. Then we can apply Theorem 2.3 to obtain the result.

Proof The sufficiency is immediate. For the necessity, let $L \in \mathcal {P}_f({^{\mathbb {N}}S})$ and pick $g \in L$ . Let $L^\prime = \{ g \} \cup \{ g + f: f \in L \}$ , pick $b \in S$ and $H \in \mathcal {P}_f(\mathbb {N})$ such that $S_{L^\prime }(b, H) \subseteq A$ , and let $a = b + \sum _{t \in H}g(t)$ . Then $a \in A$ and $S_L(a, H) \subseteq A$ .

Proof Assume that there is a J-set A such that $|A| < \kappa $ . Let us construct an injective sequence in A of length $\kappa $ , so that a contradiction appears.

Assume we have already obtained $\langle a_\xi \rangle _{\xi < \delta }$ for some $\delta < \kappa $ , which is an injective sequence in A, let us define $a_{\delta }$ . For each $(a, \xi ) \in A \times \delta $ , let $B_{a, \xi } = \{x \in S: a + x = a_\xi \}$ , which is a left solution set. Then let $B = \bigcup _{(a, \xi ) \in A \times \delta }B_{a, \xi }$ . Since S is very weakly cancellative, $|B| < \kappa $ . Now we need to build a sequence $\langle b_n \rangle _{n=1}^\infty $ which satisfies $\mathrm {FS}(\langle b_n \rangle _{n=1}^\infty ) \subseteq S \setminus B$ , and which will be used to define $a_\delta $ . First take $b_1 \in S \setminus B$ . Assume we have obtained $\langle b_i \rangle _{i=1}^n$ for some $n \in \mathbb {N}$ such that $\mathrm {FS}(\langle b_i \rangle _{i=1}^n) \subseteq S \setminus B$ . For each $y \in \mathrm {FS}(\langle b_i \rangle _{i=1}^n)$ , let $B_y = \bigcup _{(a, \xi ) \in A \times \delta }B_{y, a, \xi }$ , where $B_{y, a, \xi } = \{x \in S: a + y + x = a_\xi \}$ . Hence each $B_y$ has size less than $\kappa $ , so $|\bigcup _{y \in \mathrm {FS}(\langle b_i \rangle _{i=1}^n)}B_y| < \kappa $ . Then take $b_{n + 1} \in S \setminus (B \cup (\bigcup _{y \in \mathrm {FS}(\langle b_i \rangle _{i=1}^n)}B_y))$ .

Then for any $z = b_{i_1} + \dots + b_{i_m} \in \mathrm {FS}(\langle b_i \rangle _{i=1}^{n+1})$ , if $i_m \neq n + 1$ , then $z \in \mathrm {FS}(\langle b_i \rangle _{i=1}^n)$ so by hypothesis $z \in S \setminus B$ . Otherwise, $i_m = n + 1$ . If $m = 1$ , then $z = b_{n + 1} \in S \setminus B$ . Otherwise, $z = y + b_{n+1}$ for some $y \in \mathrm {FS}(\langle b_i \rangle _{i=1}^n)$ . Note that $b_{n+1} \notin B_y$ , so there is no $(a, \xi ) \in A \times \delta $ such that $a + y + b_{n+1} = a_\xi $ . That is, $z \notin B$ . Therefore, $\mathrm {FS}(\langle b_i \rangle _{i=1}^{n+1}) \subseteq S \setminus B$ .

Finally, we obtain $\langle b_n \rangle _{n=1}^\infty $ such that $\mathrm {FS}(\langle b_n \rangle _{n=1}^\infty ) \subseteq S \setminus B$ . Since A is a J-set, for $\langle b_n \rangle _{n=1}^\infty $ , by Lemma 3.1, there is some $a \in A$ and $H \in \mathcal {P}_f(\mathbb {N})$ such that ${a + \sum _{i \in H}b_i \in A}$ . Now let $z = \sum _{i \in H}b_i$ and $a_\delta = a + z$ , so $a_\delta \in A$ and $a_\delta $ is not equal to any $a_\xi $ , $\xi < \delta $ . (If there is some $\xi < \delta $ such that $a_\delta = a_\xi $ , then $a + z = a_\xi $ , so $z \in B$ while $z \in \mathrm {FS} (\langle b_n \rangle _{n=1}^\infty ) \subseteq S \setminus B$ , which is a contradiction.) Hence $\langle a_\xi \rangle _{\xi < \delta + 1}$ is an injective sequence in A.

By induction, we obtain an injective $\kappa $ -sequence in A; this is a contradiction.

Proof Since S is commutative very weakly cancellative, every C-set is uniform $J(S)$ -large. Then by Theorem 2.3 we deduce the result.

Proof Since the proofs of the two items are essentially the same, here we only provide the proof of the first item. Let A be a J-set. Since $\kappa ^\omega = \kappa $ , $|\mathcal {P}_f({^{\mathbb {N}}S})| = \kappa $ . Enumerate $\mathcal {P}_f({^{\mathbb {N}}S})$ as $\langle L_\sigma \rangle _{\sigma < \kappa }$ . We will inductively build two $\kappa $ -sequences $\langle a_\sigma \rangle _{\sigma < \kappa }$ and $\langle H_\sigma \rangle _{\sigma < \kappa }$ such that for each $\sigma < \kappa $ , $a_\sigma \in S$ , $H_\sigma \in \mathcal {P}_f(\mathbb {N})$ , $S_{L_\sigma }(a_\sigma , H_\sigma ) \subseteq A$ , and for $\alpha < \sigma < \kappa $ , $S_{L_\alpha }(a_\alpha , H_\alpha ) \cap S_{L_\sigma }(a_\sigma , H_\sigma ) = \emptyset $ .

Since A is a J-set, pick $a_0 \in S$ and $H_0 \in \mathcal {P}_f(\mathbb {N})$ such that $S_{L_0}(a_0, H_0) \subseteq A$ . Let $0 < \sigma < \kappa $ and assume that $\langle a_\alpha \rangle _{\alpha < \sigma }$ and $\langle H_\alpha \rangle _{\alpha < \sigma }$ have been chosen. Let $S_\sigma = \bigcup _{\alpha < \sigma }S_{L_\alpha }(a_\alpha , H_\alpha )$ and note that $|S_\sigma | < \kappa $ .

Proof Since $|D| \geq |\{ a \in S: (\exists H \in \mathcal {P}_f(\mathbb {N}))(S_{L_\sigma }(a, H) \subseteq A) \}|$ , it suffices by Theorem 3.2 to show that

$$\begin{align*}\{ a \in S: (\exists H \in \mathcal{P}_f(\mathbb{N}))(S_{L_\sigma}(a, H) \subseteq A) \} \end{align*}$$

is a J-set.

So let $L \in \mathcal {P}_f({^{\mathbb {N}}S})$ and let $L^\prime = \{ f + g: f \in L$ and $g \in L_\sigma \}$ . Since A is a J-set, pick $b \in S$ and $K \in \mathcal {P}_f(\mathbb {N})$ such that

$$\begin{align*}\{ b + \sum_{t \in K}f(t) + \sum_{t \in K}g(t): f \in L \ \mathrm{and}\ g \in L_{\sigma} \} \subseteq A. \end{align*}$$

Then $S_L(b ,K) \subseteq \{ a \in S: (\exists H \in \mathcal {P}_f(\mathbb {N}))(S_{L_\sigma }(a, H) \subseteq A) \}$ .

Then we take $(a_\sigma , H_\sigma ) \in D \setminus C$ , which is as desired.

By Lemma 2.1(i), we obtain a family $\{ \mathcal {A}_\alpha : \alpha < \delta \}$ of almost disjoint subsets of $\mathcal {P}_f(\kappa )$ such that for any $F \in \mathcal {P}_f(\kappa )$ and any $\alpha < \delta $ there is some $G \in \mathcal {A}_\alpha $ such that $F \subseteq G$ . For any $\xi < \delta $ , let $D_\xi = \bigcup \{S_{L_\sigma }(a_\sigma , H_\sigma ): \sigma < \kappa $ and $L_\sigma \in \mathcal {A}_\xi \}$ ; since $|\mathcal {A}_\xi | = \kappa $ , $|D_\xi | = \kappa $ . For any $\alpha < \beta < \delta $ , $D_\alpha \cap D_\beta = \bigcup \{S_{L_\sigma }(a_\sigma , H_\sigma ): \sigma < \kappa $ and $L_\sigma \in \mathcal {A}_\alpha \cap \mathcal {A}_\beta \}$ so $|D_\alpha \cap D_\beta | < \kappa $ . Finally we let $\xi < \delta $ and show that $D_\xi $ is a J-set. Let $L \in \mathcal {P}_f({^{\mathbb {N}}S})$ and pick $M \in \mathcal {P}_f({^{\mathbb {N}}S})$ such that $M \in \mathcal {A}_\xi $ and $L \subseteq M$ . Then $M = L_\beta $ for some $\beta < \kappa $ so $S_L(a_\beta , H_\beta ) \subseteq S_{L_\beta }(a_\beta , H_\beta ) \subseteq D_\xi $ .