Proof Let $ U$ and $ V $ be the two sides of the bipartite graph $ K_{\omega , \omega _1} $ , where $ \left |U\right |=\omega $ and $ \left |V\right |=\omega _1 $ . We denote the subgraph of $ G $ induced by the edges Maker claimed before turn $ \alpha $ by $ G^{\alpha }_M $ and we write $ N_{G^{\alpha }_{M}}(v) $ for the set of the neighbours of v in this graph.

During the game Maker will choose a sequence $\langle v_{\alpha } \colon \alpha < \kappa \rangle \langle v_{\alpha } \colon \alpha < \omega _1 \rangle $ of distinct vertices from V and a sequence $\langle N_{\alpha } \colon \alpha < \kappa \rangle $ of subsets of U in such a way as to ensure that for any $\alpha < \kappa $ and a sequence $\langle N_{\alpha } \colon \alpha < \omega _1\rangle $ of subsets of U in such a way as to ensure that for any $\alpha < \omega _1$

1. (1) $N_{\alpha } \subseteq N_{G_M}^{\omega \cdot (\alpha + 1)}(v_{\alpha })$ ,

2. (2) the set $\{N_{\beta } \colon \beta \leq \alpha \}$ has the strong finite intersection property.

Assume that turn $ \alpha \cdot \omega $ has just begun for some $\alpha <\omega _1$ and that Maker has constructed suitable $v_{\beta }$ and $N_{\beta }$ for all $\beta < \alpha $ . She picks $ v_{\alpha }$ to be any fresh vertex in V. Using (2) for all $\beta < \alpha $ , we know that the set $\{N_{\beta } \colon \beta < \alpha \}$ has the strong finite intersection property. Let $P_\alpha $ be an infinite pseudo-intersection of this family. In each of the next $ \omega $ turns, Maker claims an edge $ \{ u, v_\alpha \} $ with $ u\in P_\alpha $ . Let $N_{\alpha }$ be the set of all the endpoints $u \in U$ of these edges. It is easy to check that this construction satisfies (1) and (2) for $\alpha $ .

At the end of the game $ \{N_{\alpha } \colon \alpha <\omega _1 \} $ has the strong finite intersection property and hence (by the assumption $ \omega _1<\mathfrak {p} $ ) admits an infinite pseudo-intersection $ P $ . By the definition of $ P $ , for each $ \alpha <\omega _1 $ , the set $ P\setminus N_\alpha $ is finite. Then there exists an uncountable $ O\subseteq \omega _1 $ and a finite $ F\subseteq P $ such that $ P\setminus N_\alpha =F $ for every $ \alpha \in O $ . Finally, $ (P\setminus F)\cup \{ v_\alpha : \alpha \in O \} $ induces a copy of $ K_{\omega , \omega _1} $ , all of whose edges have been claimed by Maker.

Proof Call the colours red and blue, and call the countable and uncountable sides of the original graph U and V respectively. We pick a free ultrafilter $ \mathcal {U} $ on $ U $ . Then for each $ v\in V $ either the set $ N_r(v) $ of the red neighbours of $ v $ is in $ \mathcal {U} $ or the set $N_b(v)$ of the blue neighbours. We may assume that there is an uncountable $ V'\subseteq V $ such that $ N_r(v)\in \mathcal {U} $ for each $ v\in V' $ . Since $ \mathcal {U} $ is a free ultrafilter, the family $ \{ N_r(v): v\in V' \} $ has the strong finite intersection property and therefore (by $ \omega _1<\mathfrak {p} $ ) admits an infinite pseudo-intersection $ P $ . This means that for every $ v\in V' $ the set $ P\setminus N_r(v) $ is finite. Then there exists an uncountable $ V"\subseteq V' $ and finite $ F\subseteq P $ such that $ P\setminus N_r(v)=F $ for each $ v\in V" $ and hence $ (P\setminus F)\cup V" $ induces a red copy of $ K_{\omega , \omega _1} $ .

Question 3.4. Is it consistent with ZFC $+\aleph _\omega <2^{\aleph _0}$ that Maker has a winning strategy in the game $\mathfrak {MB}(K_{\omega , \omega _\omega }, K_{\omega , \omega _\omega }) $ ?

Proof A sub-binary Hausdorff tree is a set theoretic tree $ T $ in which each vertex has at most two children and no two vertices at any limit level have the same set of predecessors.

During the game Maker builds a sequence $ \left \langle T_\alpha : \alpha \leq \kappa \right \rangle $ of sub-binary Hausdorff trees with root $ 0 $ and $ T_\alpha \subseteq \kappa $ of height at most $1+\alpha $ such that:

1. (a)

   1. (i) $ T_0=\{ 0 \} $ ,

   2. (ii) $ T_{\alpha +1} $ is obtained from $ T_\alpha $ by inserting a new maximal element,

   3. (iii) $ T_\alpha =\bigcup _{\beta <\alpha }T_\beta $ if $ \alpha $ is a limit ordinal,

2. (b) for every distinct $ <_{T_\alpha } $ -comparable $ u,v\in T_\alpha $ , the edge $ \{ u,v \} $ is claimed by Maker in the game.

Suppose that $ \alpha =\beta +1 $ and $ T_\beta $ is already defined. Maker picks the smallest ordinal $ v $ such that no edge incident with v is claimed and claims edge $ \{ 0, v \} $ . Then, for as long as she can, on each following turn she connects $ v $ to vertices in $ T_\beta $ in such a way that:

1. (1) she maintains that the current neighbourhood of $ v $ in her graph is a downward closed chain in $ T_\beta $ ,

2. (2) whenever she claims some $ \{ u,v \} $ , then Breaker has no edge between $ v $ and the subtree $ T_{\beta , u} $ of $ T_\beta $ rooted at $ u $ .

Note that, at any step at which v has a largest Maker-neighbour in $T_\beta $ and this neighbour has two children in $ T_\beta $ , she can proceed. Moreover, she can also proceed even if there is no such largest Maker-neighbour as long as there is some element of $T_{\beta }$ whose predecessors are precisely the Maker-neighbours of v in $T_{\beta }$ . Thus, if Maker is unable to continue this process with $ v $ , then either $ v $ has a largest Maker-neighbour in $ T_\beta $ which has at most one child or else there is no vertex in $T_{\beta }$ with precisely the Maker-neighbours of u as its predecessors. In either case we can define $ T_{\beta +1} $ by adding $ v $ to $ T_\beta $ with its current set of Maker-neighbours as its predecessors, and Maker starts a new phase with a new fresh vertex.

It is enough to show that there is a $ \kappa $ -branch $ B $ in $ T_\kappa $ , because then $ G_M[B] $ is a copy of $ K_{\kappa } $ by (b). Since $ \left |T_\kappa \right |=\kappa $ by (a), we can fix a $ \kappa $ -complete free ultrafilter $ \mathcal {U} $ on $ T_\kappa $ .

By transfinite recursion we build a $ \kappa $ -branch. Let $ v_0:=0 $ . Suppose that there is an $ \alpha <\kappa $ such that the $ <_{T_\kappa } $ -increasing sequence $ \left \langle v_\beta : \beta <\alpha \right \rangle $ is already defined and for each $ \beta <\alpha $ , $ T_{\kappa , v_\beta }\in \mathcal {U} $ . If $ \alpha $ is a limit ordinal, then since $\bigcap _{\beta <\alpha }T_{v_\beta }\in \mathcal {U} $ by the $ \kappa $ -completeness of $ \mathcal {U} $ , there is at least one vertex of T with all $v_{\beta }$ as predecessors. We define $ v_\alpha $ to be the unique minimal such vertex, so that $ T_{v_\alpha }=\bigcap _{\beta <\alpha }T_{v_\beta }\in \mathcal {U} $ . If $ \alpha =\beta +1 $ , then $ T_{\kappa , v_\beta }\in \mathcal {U} $ by assumption. Since $ T_\kappa $ is sub-binary, $ v_\beta $ has a unique child $ v $ satisfying $ T_{\kappa , v}\in \mathcal {U} $ and we let $ v_{\beta +1}:=v $ . The recursion is done and $\{ v_\alpha : \alpha <\kappa \} $ is clearly a $ \kappa $ -branch.

Proof First of all, the club filter on $ \omega _1 $ is a countably complete free ultrafilter under ZF+DC+AD (this is explicit in the proof of [Reference Kanamori9, Theorem 28.2]). Furthermore, it is normal [Reference Dorais and Hathaway6, Proposition 4.1]. Thus for any 2-colouring of $ [\omega _1]^{2} $ there exists a colour with a monochromatic $ K_{\mathsf {club}} $ (the standard proof of this for arbitrary normal ultrafilters uses only ZF, see [Reference Jech8, Theorem 10.22]). It follows that if Breaker successfully prevents Maker from building a $ K_{\mathsf {club}} $ , then he necessarily builds a $ K_{\mathsf {club}} $ himself.

Suppose for a contradiction that Breaker has a winning strategy. We shall show that Maker can “steal” this winning strategy. Indeed, Maker picks an arbitrary edge in turn $ 0 $ as well as in each limit turn while in successor turns she pretends to be Breaker and claims edges according to his winning strategy. This is a winning strategy for Maker, a contradiction.