Proof Suppose $\mathcal E$ is tight but not maximal and let $h \notin \mathcal E$ be eventually different from every element of $\mathcal E$ . Consider now the tree $T_h = \{h \upharpoonright n \;| \; n < \omega \}$ . This tree is in $\mathcal I_T(\mathcal E)^+$ since if we could cover it by finitely many functions from $\mathcal E$ then there would be an $f \in \mathcal E$ so that for infinitely many $n \ f(n) = (h\upharpoonright n+1)(n)$ , i.e., $f =^{\infty } h$ . But then by tightness there is a $g \in \mathcal E$ which densely diagonalizes $T_h$ . But this just means that $g =^{\infty } h$ , contradiction.

Proof Let $(s, E)$ be a condition. We will kill three birds with one stone and show that there is a stronger condition in all three dense sets at once. First, by the explanation of $\sigma $ -centeredness given above, $(s, E \cup \{f\}) \leq (s, E)$ and is in the last dense set. Now, fix $T \in \mathcal I_T(\mathcal E)^+$ and $t \in T$ . By assumption we know that $T_t$ cannot be almost covered by $\bigcup E \cup \{f\}$ . It follows that there is a node $t' \supsetneq t$ in T and an $l_t \in \mathrm {dom}(t') \setminus \mathrm {dom}(t)$ so that $t'(l_t) \neq f'(l_t)$ for all $f' \in E \cup \{f\}$ . Moreover since $\mathrm {dom}(s)$ is finite we can ensure that $l_t \notin \mathrm {dom}(s)$ . Let $s' = s \cup \{(l_t, t'(l_t) )\}$ . Now, fix $k \in \omega $ . If $k \notin \mathrm {dom}(s')$ then let $s" = s' \cup \{(k, l_k)\}$ where $l_k$ is the minimal element not in the (finite) set $\{f(k) \; | \; f \in E\}$ . Finally we get that $(s", E \cup \{f\} ) \leq (s, E)$ , which is what we needed to show.

Proof of Theorem 2.4

Assume $\mathsf {MA}(\sigma \mathrm {-centered})$ . Enumerate all $\omega $ -sequences of subtrees of $\omega ^{<\omega }$ as $\{\vec {T}_{\alpha } \; | \; \alpha < 2^{\aleph _0}\}$ . For each $\alpha < 2^{\aleph _0}$ and $n < \omega $ denote by $T_{\alpha }(n)$ the $n{\mathrm {th}}$ tree in $\vec {T}_{\alpha }$ . Fix an eventually different family $\mathcal E_0$ of size ${<}2^{\aleph _0}$ . We will recursively build a continuous $\subseteq $ -increasing sequence of eventually different families $\{\mathcal E_{\alpha } \; | \; \alpha < 2^{\aleph _0}\}$ so that for each $\alpha < 2^{\aleph _0} \ {\mathcal E}_{\alpha }$ has cardinality ${<}2^{\aleph _0}$ and if $\vec {T}_{\alpha } \in \mathcal I_T(\mathcal E_{\alpha })^+$ then there is a real in $\mathcal E_{\alpha +1}$ densely diagonalizing $T_{\alpha }(n)$ for each $n < \omega $ . If such a sequence can be constructed then clearly $\mathcal E = \bigcup _{\alpha < 2^{\aleph _0}} \mathcal E_{\alpha }$ will be the desired tight eventually different family.

We already have $\mathcal E_0$ . Now suppose that we have constructed $\mathcal E_{\alpha }$ . If $\vec {T}_{\alpha } \nsubseteq \mathcal I_T(\mathcal E_{\alpha })^+$ then let $g_{\alpha }$ be any function eventually different from every element of $\mathcal E_{\alpha }$ . That such an element exists is guaranteed by $\mathsf {MA}(\sigma \mathrm {-centered})$ (using eventually different forcing). If $\vec {T}_{\alpha } \subseteq \mathcal I_T(\mathcal E_{\alpha })^+$ then, by applying $\mathsf {MA} (\sigma \mathrm {-centered})$ to ${\mathord {\mathbb P}}_{\mathcal E_{\alpha }}$ and noting that we only need to meet $|\mathcal E_{\alpha }| + \aleph _0$ dense sets, find a $g_{\alpha }$ eventually different from each element of $\mathcal E_{\alpha }$ and densely diagonalizing every $T_{\alpha }(n)$ for $n < \omega $ . In either case let $\mathcal E_{\alpha +1} = \mathcal E_{\alpha } \cup \{g_{\alpha }\}$ . Either way it’s clear that we have fulfilled the requisite conditions.

Question 1. Is it consistent with $\mathsf {ZFC} $ that there are no tight maximal eventually different families?

Proof Since every new real in the Cohen extension is added by a single Cohen real, it suffices to prove the theorem in the case $\kappa = 1$ . Denote $\mathbb C_1$ by $\mathbb C$ . Let $\mathcal E$ be tight and let $\{\dot {T}_n \; | \; n < \omega \}$ be a countable set of $\mathbb C$ -names for subtrees of $\omega ^{<\omega }$ . We will show that for each $p \in \mathbb C$ either there is a $q \leq p$ , an $n < \omega $ so that $q \Vdash \dot {T}_n \in \mathcal I_T(\mathcal E)\check {}$ or there is a $g \in \mathcal E$ so that $p \Vdash $ “For each $n < \omega $ , $\check {g}$ densely diagonalizes $\dot {T}_n$ ”. Clearly the theorem will follow from this.

Fix $p \in \mathbb C$ and enumerate the set of conditions below p as $\{p_j \; | \; j < \omega \}$ . For each $n, j < \omega $ let $T_{n, j} = \{t \in \omega ^{<\omega } \; |\; \exists q \leq p_j \, q \Vdash \check {t} \in \dot {T}_n \}$ . For each $n, j < \omega $ the set $T_{n, j}$ is a tree since if some $t \in T_{n, j}$ as witnessed by some q then the same q witnesses that $s \in T_{n, j}$ for each $s \subseteq t$ . There are two cases.

Case 1: There are $n, j< \omega $ and $t\in T_{n, j}$ so that $(T_{n, j})_t$ is almost covered by finitely many functions from $\mathcal E$ , i.e., $T_{n, j} \in \mathcal I_T(\mathcal E)$ . Fix $q \leq p_j$ so that q witnesses that $t \in T_{n, j}$ and suppose that $f_0, \dots , f_{n-1} \in \mathcal E$ are such that $\bigcup (T_{n, j})_t \subseteq ^* \bigcup \{f_0, \dots , f_{n-1}\}$ . Unwinding the definition of $T_{n, j}$ we get that in this case q forces $\emptyset \neq (\dot {T}_n)_{\check {t}} \subseteq (T_{n, j})_t$ since if $t'$ is compatible with t and some $r \leq q$ forces $\check {t}' \in \dot {T}_n$ then r witnesses that $t' \in (T_{n, j})_t$ and since q forces that $t \in \dot {T}_n$ then q forces in particular that $(\dot {T}_n)_t$ is non empty. It follows that q forces that $\bigcup (\dot {T}_n)_t \subseteq ^* \bigcup \{\check {f}_0, \dots , \check {f}_{n-1}\}$ . In other words, q must force that $\dot {T}_n$ is in $\mathcal I_T(\mathcal E)$ .

Case 2: Case 1 fails. In other words this means that each $T_{n, j}$ is not in $\mathcal I_T(\mathcal E)$ . By the assumption that $\mathcal E$ is tight, this means that there is a single $g \in \mathcal E$ which densely diagonalizes all of the $T_{n, j}$ ’s. We claim that $p \Vdash $ “For all $n < \omega \ g$ densely diagonalizes $\dot {T}_n$ ”. To see this, fix $n < \omega $ and let $q = p_m < p$ for some m. Suppose $\dot {t}$ is a name for an element of $\dot {T}_n$ . By strengthening q if necessary we can assume that $\dot {t}$ is decided by q to be some $t \in T_{n, m}$ . Moreover, since g densely diagonalizes $T_{n, m}$ there is an $s \supseteq t$ which is in $T_{n, m}$ as witnessed by some $r\leq q$ and an $l \in \mathrm {dom}(s) \setminus \mathrm {dom}(t)$ and $s(l) = g(l)$ . It follows that r forces there to be a node of $\dot {T}_n$ strengthening $\dot {t}$ and agreeing with g above the domain of $\dot {t}$ . Since q was arbitrary it follows that p actually forces this for each $\dot {t}$ and n and hence p forces g to densely diagonalize each $\dot {T}_n$ as needed.

Proof of Theorem 3.3

Let $\mathcal A$ be an analytic, maximal eventually different family. Note that $\mathcal A$ is uncountable and therefore, by the perfect set property for analytic sets, it contains a perfect set $P \subseteq \mathcal A$ . Moreover, since every perfect set contains a copy of Cantor space, we can find a continuous injection $f:2^{\omega } \to \mathcal A$ . Fix such an f.

Observe that “ $\mathcal A$ is an eventually different family” is $\Pi ^1_1$ : namely we have $\forall x, y [ x \notin \mathcal A \lor y \notin \mathcal A \lor x \neq ^* y]$ . Since $\mathcal A$ is analytic, and hence its complement is co-analytic the observation follows. In particular, the interpretation of $\mathcal A$ remains an eventually different family in any forcing extension. Now let ${\mathord {\mathbb P}}$ be a forcing notion adding a real, x. Working in $V^{\mathord {\mathbb P}}$ we consider the real $f(x) \in \mathcal A^{V^{\mathord {\mathbb P}}}$ . This real is eventually different from every element of $\mathcal A \cap V$ and hence $\mathcal A \cap V$ is no longer maximal.

Proof Suppose p is $(M, {\mathord {\mathbb P}}, \mathcal E, g)$ -generic and forces $\dot {q}$ to be $(M[\dot {G}], \dot {{\mathord {\mathbb Q}}}, \mathcal E, g)$ -generic. Then obviously $(p, \dot {q})$ is $(M, {\mathord {\mathbb P}} * \dot {\mathbb Q})$ -generic. Moreover, by definition it forces that for every ${\mathord {\mathbb P}}$ -name for a $\dot {\mathbb Q}$ -name for an element of $\mathcal I_T(\mathcal E)^+$ in $M \ g$ densely diagonalizes it. But therefore $(p, \dot {q})$ forces that for every ${\mathord {\mathbb P}} * \dot {\mathbb Q}$ -name for an element of $\mathcal I_T(\mathcal E)^+$ in M is densely diagonalized by g as needed.

Proof The proof is by induction on $\gamma $ . The case where $\gamma $ is a successor ordinal follows from Lemma 4.3 so we focus on the limit case. Fix $\alpha , p, M$ , etc. as in the statement of the lemma and let $\{\alpha _n \; | \; n <\omega \}$ be a strictly increasing sequence in $M\cap \gamma $ with supremum $\gamma $ so that $\alpha _0 = \alpha $ . Fix a bijection $\varphi :\omega \to \omega ^2$ with coordinate functions $\varphi _0$ and $\varphi _1$ . Enumerate the dense open subsets of $\mathbb P_{\gamma }$ in M as $\{D_n\; | \; n < \omega \}$ . Enumerate the ${\mathord {\mathbb P}}_{\gamma }$ -names for $\mathcal I_T(\mathcal E)^+$ trees in M as $\{\dot {T}_n \; | \; n < \omega \}$ . We will recursively define sequences $\{p_n \; | \; n < \omega \}$ , $\{\dot {q}_n \; | \; n < \omega \}$ , $\{\dot {t}_n \; | \; n < \omega \}$ , and $\{\dot {k}_n \; | \; n < \omega \}$ as follows:

1. (1) $p_0 = p$ and $\dot {q}_0 = \dot {q}$ .

2. (2) $p_n$ is an $(M, {\mathord {\mathbb P}}_{\alpha _n}, \mathcal E, g)$ -generic condition.

3. (3) $p_{n+1} \upharpoonright \alpha _n = p_n$ .

4. (4) $\dot {q}_n$ is a ${\mathord {\mathbb P}}_{\alpha _n}$ name so that $p_n \Vdash _{\alpha _n} \dot {q}_n \in {\mathord {\mathbb P}}_{\gamma } \cap M$ and $p_n \Vdash _{\alpha _n} \dot {q}_n \upharpoonright \alpha _n \in \dot {G}_{\alpha _n}$ .

5. (5) $p_{n+1} \Vdash _{\alpha _{n+1}} \dot {q}_{n+1} \leq \dot {q}_n$ and $p_{n+1} \Vdash _{\alpha _{n+1}} \dot {q}_{n+1} \in D_n$ .

6. (6) $\dot {t}_n$ is a ${\mathord {\mathbb P}}_{\gamma }$ name for a node in $\dot {T}_{\varphi _0(n)}$ strictly above the $\varphi _1(n){\mathrm {th}}$ node in $\dot {T}_{\varphi _0(n)}$ .

7. (7) $\dot {k}_n$ is a name for an element of $\omega $ forced to be in the domain of $\dot {t}_n$ above the domain of the $\varphi _1(n){\mathrm {th}}$ node in $\dot {T}_{\varphi _0(n)}$ and $p_n \Vdash _{\alpha _n}$ “ $\dot {q}_n \Vdash _{\gamma } \check {g}(\dot {k}_n) = \dot {t}_n(\dot {k}_n)$ ”.

Assuming that such a sequence can be constructed we let $\bar {p} = \bigcup _{n < \omega } p_n$ . Clearly this condition is as required. Therefore it remains to see that we can construct such a quadruple of sequences. This is done by induction. The base case is given. Suppose that we have constructed for some $n < \omega $ sequences $\{p_m \; | \; m < n+1\}$ , $\{\dot {q}_m \; | \; m < n+1\}$ , $\{\dot {t}_m \; | \; m < n+1 \}$ and $\{\dot {k}_m \; | \; m < n+1 \}$ satisfying the above conditions and we construct $p_{n+1}$ , $\dot {q}_{n+1}$ , $\dot {t}_{n+1}$ , and $\dot {k}_{n+1}$ .

Let $p_n \in G_{\alpha _n}$ be generic and work in $V[G_{\alpha _n}]$ . Let $q_n \in {\mathord {\mathbb P}}_{\gamma } \cap M$ be the evaluation of the name $\dot {q}_n$ by $G_{\alpha _n}$ so that $q_n \upharpoonright \alpha _n \in G_{\alpha _n}$ . Since $p_n$ is $(M, {\mathord {\mathbb P}}_{\alpha _n})$ generic there is an $r \in D_n \cap M$ so that $r\leq q_n$ and $r \upharpoonright \alpha _n \in G_{\alpha _n}$ . Without loss we may assume that r decides that the $\varphi _1(n){\mathrm {th}}$ node in $\dot {T}_{\varphi _0(n)}$ to be some $s_n \in \omega ^{<\omega }$ . Now let W be the set of all $t \in {\omega }^{<\omega }$ so that there is an $\bar {r} \leq r$ so that $\bar {r} \in {\mathord {\mathbb P}}_{\gamma }$ and the following hold:

1. (1) $\bar {r} \upharpoonright \alpha _n \in G_{\alpha _n}$ .

2. (2) $\bar {r} \Vdash _{\gamma }$ “ $\check {t} \in \dot {T}_{\varphi _0(n)}$ and $\check {t} \supsetneq \check {s}_n$ ”.

Observe that, by appending $s_n$ and its predecessors to W we have a tree with stem (including) $s_n$ . This is because if some $\bar {r}$ forces $t \in \dot {T}_{\varphi _0(n)}$ to be strictly above $s_n$ and $s_n \supsetneq t' \supsetneq t$ then trivially the same $\bar {r}$ forces the same of $t'$ so W is closed downwards under sequences extending $s_n$ . Moreover $W \in M[G_{\alpha }]$ by construction (since $\dot {T}_{\varphi _0(n)}$ and r are) and, crucially $W \in \mathcal I_T(\mathcal E)^+$ . To see this last point observe that if $r \in G$ is ${\mathord {\mathbb P}}_{\gamma }$ generic then, in $V[G]$ we must have that the evaluation of $\dot {T}_{\varphi _0(n)}$ is contained in W so if W could be covered by finitely many functions from $\mathcal E$ then so could $\dot {T}_{\varphi _0(n)}$ contradicting the fact that it was forced to be a tree in $\mathcal I_T(\mathcal E)^+$ .

We can therefore apply assumption (2) for $p_n$ and conclude that g densely diagonalizes W. It follows that there is a node $t\in W$ so that $t \supsetneq s_n$ and there is a $k \in \mathrm {dom}(t) \setminus \mathrm { dom}(s_n)$ so that $g(k) = t(k)$ . Let $\dot {q}_{n+1}$ be a name for the $\bar {r}$ witnessing that $t \in W$ and let $\dot {t}_n$ and $\dot {k}_n$ be names for t and k back in V. Finally, by our inductive hypothesis we can find a $(M, {\mathord {\mathbb P}}_{\alpha _{n+1}}, \mathcal E, g)$ -generic condition $p_{n+1} \leq p_n$ as needed.

Proof The proof is almost the same as that of Theorem 2.4. We just indicate what the right poset is and the necessary modifications. Let $\mathcal {P}$ be an eventually different set of permutations (not necessarily maximal). Define the forcing notion ${\mathord {\mathbb Q}}_{\mathcal {P}}$ to be the set of all pairs $(s, E)$ so that the following hold:

1. (1) s is an injective finite partial function from $\omega $ to $\omega $ .

2. (2) $E \in [\mathcal {P}]^{<\omega }$ .

The order on ${\mathord {\mathbb Q}}_{\mathcal {P}}$ is defined exactly the same as for ${\mathord {\mathbb P}}_{\mathcal E}$ . Mimicking the proof of Theorem 2.4, it’s enough to show that the following sets are dense:

1. (1) For each $k < \omega $ the set of conditions $(s, E)$ so that $k \in \mathrm {dom}(s)$ .

2. (2) For each $k < \omega $ the set of conditions $(s, E)$ so that $k \in \mathrm {range}(s)$ .

3. (3) For each $T \in \mathcal I_T(\mathcal P)^+$ , and $t \in T$ the set of conditions $(s, E)$ so that there is an $t' \in T$ which extends t and a $k \in \mathrm {dom}(t') \setminus \mathrm {dom}(t)$ so that $s(k) = t'(k)$ .

4. (4) For each $f \in \mathcal E$ the set of conditions $(s, E)$ so that $f \in E$ .

This is shown exactly as for eventually different families, the one caveat being that we need to be able ensure that when we strengthen some $(s, E)$ we can guarantee that if $T \in \mathcal I_T(\mathcal {P})^+$ then we can find an $t' \supsetneq t$ so that $t' \in T$ and a $k \in \mathrm {dom}(t') \setminus \mathrm {dom} (t) \cap \mathrm { dom}(s)$ so that we can add $(k, t'(k))$ to s without wrecking injectivity. This is where we use that fact that T is injective. Namely, we can find a level in T above which no element of any sequence is in the range of s (since s is finite) and therefore we can find the needed k. Everything else in the proof is exactly as in the case of eventually different families of functions.

Proof Let $p\in \mathbb {PT}$ be a condition, let $M\prec H_{\theta }$ countable with $\theta $ sufficiently large, $p, \mathbb {PT}, \mathcal E \in M$ . Let $g \in \mathcal E$ densely diagonalize every $T \in M \cap \mathcal I_T(\mathcal E)^+$ . Let $\{T_n \; | \; n < \omega \}$ be an enumeration of all $\mathbb {PT}$ names in M for trees in $\mathcal I_T(\mathcal E)^+$ . Let $\{D_n \; | \; n < \omega \}$ enumerate all dense open subsets of $\mathbb {PT}$ in M. Let $\varphi :\omega \to \omega ^2$ be a bijection with coordinate maps $\varphi _0$ and $\varphi _1$ . Inductively we will construct sequences $\{p_n \; | \; n < \omega \}$ , $\{\dot {t}_n \; | \; n < \omega \}$ , $\{\dot {k}_n \; | \; n < \omega \}$ so that the following hold:

1. (1) $p_0 = p$ .

2. (2) $\{p_n \; |\; n < \omega \} \subseteq M$ and for all $n <\omega $ , $p_{n+1} \leq _{n+1} p_n$ .

3. (3) For each $n< \omega $ , $\dot {t}_n$ is a $\mathbb {PT}$ name in M for a node in $\dot {T}_{\varphi _0(n)}$ extending the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ .

4. (4) For each $n < \omega $ , $\dot {k}_n$ is a name for an element of $\omega $ in M.

5. (5) For each ${n+1}{\mathrm {st}}$ -splitting node t of $p_{n+1}$ we have that $(p_{n+1})_t \in D_n$ , and forces for some $s_n \in \omega ^{<\omega }$ that the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ is $\check {s}_n$ and $(p_{n+1})_t \Vdash \dot {k}_n \in \mathrm {dom}(\dot {t}_n) \setminus \mathrm {dom}(\check {s}_n) \land \dot {t}_n(\dot {k}_n) = \check {g} (k)$ .

Suppose first that we can construct such a sequence. Let $q = \bigcap _{n < \omega } p_n$ . It follows almost immediately that q is $(M, \mathbb {PT}, \mathcal E, g)$ -generic as needed.

Therefore it remains to construct the requisite sequence. This is done by induction. Let $p_0 = p$ . Now assume that $\{p_j \; | \; j < n+1\}$ , $\{\dot {t}_j \; | \; j < n\}$ and $\{\dot {k}_j \; | \; j < n\}$ have been defined. We will define $p_{n+1}$ , $\dot {t}_n$ and $\dot {k}_n$ . For each ${n+1}{\mathrm {st}}$ -splitting node t of $p_n$ , let $q_t \leq (p_n)_t$ be an element of $M \cap D_n$ which forces for some $s_n \in \omega ^{<\omega }$ that the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ is $\check {s}_n$ . Let $W_t = \{u \supsetneq s_n \; | \; q_t \nVdash u \notin \dot {T}_{\varphi _0(n)}\}$ . As in the proof of Lemma 4.2 $W_t$ alongside $s_n$ and its predecessors is a tree in $\mathcal I_T(\mathcal E)^+ \cap M$ hence it is densely diagonalized by g. Therefore we can find a $u_t \in W_t$ and a $k_t \in \mathrm {dom}(u_t) \setminus \mathrm {dom}(s_n)$ so that $u_t(k_t) = g(k_t)$ . Let $r_t \leq q_t$ force that $\check {u_t} \in \dot {T}_{\varphi _0(n)}$ . Now let $p_{n+1} = \bigcup _{t \in \mathrm {Split}_{n+1}(p_n)} r_t$ . Let $\dot {t}_n = \{(\check {u}_t, r_t) \; | \; t \in \mathrm { Split}_{n+1}(p_n)\}$ and $\dot {k}_n =\{(\check {k}_t, r_t) \; | \; t \in \mathrm {Split}_{n+1}(p_n)\}$ . Clearly these suffice.

Proof Let $p\in {\mathord {\mathbb P}}(\mathcal K)$ be a condition, let $M\prec H_{\theta }$ countable with $\theta $ sufficiently large, $p, {\mathord {\mathbb P}}(\mathcal K), \mathcal K, \mathcal E \in M$ . Let $g \in \mathcal E$ densely diagonalize every $T \in M \cap \mathcal I_T(\mathcal E)^+$ . Let $\{T_n \; | \; n < \omega \}$ be an enumeration of all ${\mathord {\mathbb P}}(\mathcal K)$ names in M for trees in $\mathcal I_T(\mathcal E)^+$ . Let $\{D_n \; | \; n < \omega \}$ enumerate all dense open subsets of ${\mathord {\mathbb P}}(\mathcal K)$ in M. Let $\varphi :\omega \to \omega ^2$ be a bijection with coordinate maps $\varphi _0$ and $\varphi _1$ . Inductively we will construct sequences $\{p_n \; | \; n < \omega \}$ , $\{\dot {t}_n \; | \; n < \omega \}$ , $\{\dot {k}_n \; | \; n < \omega \}$ and a set $X = \{x_s \; | \; s \in \omega ^{<\omega }\}$ so that the following hold:

1. (1) $p_0 = p$ .

2. (2) $\{p_n \; |\; n < \omega \} \subseteq M \cap {\mathord {\mathbb P}}(\mathcal K)$ and for all $n <\omega \ p_{n+1} \leq p_n$ .

3. (3) $X \subseteq 2^{\omega } \cap M$ is nice for $\mathcal K$ .

4. (4) $X \subseteq [p_n]$ for every $n < \omega $ .

5. (5) For each $n \ \dot {t}_n$ is a ${\mathord {\mathbb P}}(\mathcal K)$ name for a node in $\dot {T}_{\varphi _0(n)}$ extending the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ .

6. (6) For each $n < \omega \ \dot {k}_n$ is a name for an element of $\omega $ in M.

7. (7) For each $s \in \omega ^n$ and $i, m \in \omega $ if $m = \Delta (x_s, x_{s^{\frown } i})$ and $t = (x_{s^{\frown } i}) \upharpoonright m$ then $(p_{n+1})_t \in D_n$ , forces for some $s_n \in \omega ^{<\omega }$ that the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ is $\check {s}_n$ and $(p_{n+1})_t \Vdash \dot {k}_n \in \mathrm {dom}(\dot {t}_n) \setminus \mathrm {dom}(\check {s}_n) \land \dot {t}_n(\dot {k}_n) = \check {g} (k)$ .

Suppose first that we can construct such a sequence. Let $q = \bigcap _{n < \omega } p_n$ . Clearly q is a condition since it’s a perfect tree in which X is dense. From this it follows almost immediately that it is $(M, {\mathord {\mathbb P}}(\mathcal K), \mathcal E, g)$ -generic as needed.

Therefore it remains to construct the sequence described above. This is done by induction. Let $p_0 = p$ , $x_{\emptyset }$ be any element of $[p_0] \cap M$ . Now assume that $\{p_j \; | \; j < n+1\}$ , $\{x_s \; | \; s \in \omega ^{\leq n}\}$ , $\{\dot {t}_j \; | \; j < n\}$ , and $\{\dot {k}_j \; | \; j < n\}$ have been defined. We will define $p_{n+1}$ , $\{x_s \; | \; s \in \omega ^{n+1}\}$ , $\dot {t}_n$ , and $\dot {k}_n$ . For each $s \in \omega ^n$ let $l \in \omega $ be so that $l> \Delta (x_s, x_{s'})$ for all $s ' \subsetneq s$ . Define $Y_s$ to be the set of all $m> l$ so that $x_s \upharpoonright m \in p_n$ is a splitting node. For each $m \in Y_s$ let $t_m = (x_s \upharpoonright m)^{\frown } (1 - x_s (m))$ (which is a node of $p_n$ since $x_s \upharpoonright m$ is splitting). Let $p^s_m = (p_n)_{t_m}$ . Note that $p^s_m \in M$ . By strengthening if necessary we may also assume that there is an $u^s_m \in {\omega }^{\omega }$ so that $p^s_m \Vdash $ “ $\check {u}^s_m$ is the $\varphi _1(n){\mathrm {th}}$ node in $T_{\varphi _0(n)}$ ”. Now let $W^s_m = \{t \in \omega ^{<\omega } \; | \; t \supsetneq u^s_m \; \mathrm {and} \; p^s_m \nVdash t \notin \dot {T}_{\varphi _0(n)}\}$ . As in the proof of Theorem 4.2, $W^s_m$ , alongside $u^s_m$ and its predecessors is a tree in $\mathcal I_T(\mathcal E)^+$ (in M) so g densely diagonalizes it. Let $r^s_m \leq p^s_m$ so that $r^s_m \in D_n$ , $[r^s_m] \cap C_{\alpha _z} = \emptyset $ for every $z \subseteq s$ and there is a $t^s_m \in W^s_m$ and a $k^s_m < \omega $ so that $k^s_m \in \mathrm {dom}(t) \setminus \mathrm { dom}(u^s_m)$ and $r^s_m \Vdash \check {t}^s_m \in \dot {T}_{\varphi _0(n)}$ and $t^s_m(k^s_m) = g(k^s_m)$ . Enumerate $Y_s$ as $\{m^s_i \; | \; i < \omega \}$ . For each $i < \omega $ choose $x_{s^{\frown } i}$ to be any branch in $r^s_{m^s_i}$ and let $p_{n+1} = \bigcup \{r^s_{m^s_i} \; | \; s \in \omega ^n \land i \in \omega \}$ . Finally let $\dot {t}_n = \{(\check {t}^s_{m^s_i}, r^s_{m^s_i}) \; | \; s \in \omega ^n \land i \in \omega \}$ and $\dot {k}_n = \{(\check {k}^s_{m^s_i}, r^s_{m^s_i}) \; | \; s \in \omega ^n \land i \in \omega \}$ . Clearly these suffice.

Proof Using a bookkeeping device to keep track with the partitions, let ${\mathord {\mathbb P}}$ be the $\omega _2$ length countable support of partition forcing. Let $G\subseteq {\mathord {\mathbb P}}$ be generic. In $V[G]$ we have $\mathfrak {a}_e = \aleph _1$ by Theorem 7.3 and $\mathfrak {a}_p = \aleph _1$ by Theorem 7.5. Moreover this forcing is known to be $\omega ^{\omega }$ -bounding (see [Reference Spinas25]) so $\mathfrak {d} = \aleph _1$ . Finally that $\mathfrak {a}_T = \aleph _2$ in this model is by [Reference Miller, Barwise, Keisler and Kunen18, Theorem 6] (indeed this is what it was designed to do).

Fact 8.1 [Reference Goldstern, Judah and Shelah12]

Denote by $\mathbb {PT}_{2^n}$ the forcing notion $\mathbb {PT}_h$ for $h(n) = 2^n$ for all $n < \omega $ . The following hold:

1. (1) $\mathbb {PT}_{2^n}$ is proper, and in fact satisfies Axiom A.

2. (2) $\mathbb {PT}_{2^n}$ is $\omega ^{\omega }$ -bounding.

3. (3) $\mathbb {PT}_{2^n}$ preserves P-points.

4. (4) $\mathbb {PT}_{2^n}$ makes the ground model reals measure zero.

Proof Let $p\in \mathbb {PT}_{2^n}$ be a condition, let $M\prec H_{\theta }$ countable with $\theta $ sufficiently large, $p, \mathbb {PT}_{2^n}, \mathcal E \in M$ . Let $g \in \mathcal E$ densely diagonalize every $T \in M \cap \mathcal I_T(\mathcal E)^+$ . Let $\{T_n \; | \; n < \omega \}$ be an enumeration of all $\mathbb {PT}_{2^n}$ names in M for trees in $\mathcal I_T(\mathcal E)^+$ . Let $\{D_n \; | \; n < \omega \}$ enumerate all dense open subsets of $\mathbb {PT}_{2^n}$ in M. Let $\varphi :\omega \to \omega ^2$ be a bijection with coordinate maps $\varphi _0$ and $\varphi _1$ . Inductively we will construct sequences $\{p_n \; | \; n < \omega \}$ , $\{\dot {t}_n \; | \; n < \omega \}$ , $\{\dot {k}_n \; | \; n < \omega \}$ so that the following hold:

1. (1) $p_0 = p$ .

2. (2) $\{p_n \; |\; n < \omega \} \subseteq M$ and for all $n <\omega \ p_{n+1} \leq _{n+1} p_n$ .

3. (3) For each $n \ \dot {t}_n$ is a $\mathbb {PT}_{2^n}$ name in M for a node in $\dot {T}_{\varphi _0(n)}$ extending the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ .

4. (4) For each $n < \omega \ \dot {k}_n$ is a name for an element of $\omega $ in M.

5. (5) For each ${n+1}{\mathrm {st}}$ -splitting node t of $p_{n+1}$ we have that $(p_{n+1})_t \in D_n$ , and forces for some $s_n \in \omega ^{<\omega }$ that the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ is $\check {s}_n$ and $(p_{n+1})_t \Vdash \dot {k}_n \in \mathrm {dom}(\dot {t}_n) \setminus \mathrm {dom}(\check {s}_n) \land \dot {t}_n(\dot {k}_n) = \check {g} (k)$ .

Obviously if such a family of sequences can be constructed then, letting $q = \bigcap _{n < \omega } p_n$ , it is clear that q is $(M, \mathbb {PT}, \mathcal E, g)$ -generic as needed.

Therefore it remains to construct the requisite sequence. This is done by induction. Let $p_0 = p$ . Now assume that $\{p_j \; | \; j < n+1\}$ , $\{\dot {t}_j \; | \; j < n\}$ and $\{\dot {k}_j \; | \; j < n\}$ have been defined. We will define $p_{n+1}$ , $\dot {t}_n$ and $\dot {k}_n$ . For each ${n+1}{\mathrm {st}}$ -splitting node t of $p_n$ , let $q_t \leq (p_n)_t$ be an element of $M \cap D_n$ which forces for some $s_n \in \omega ^{<\omega }$ that the $\varphi _1(n){\mathrm {th}}$ -node in $\dot {T}_{\varphi _0(n)}$ is $\check {s}_n$ . Let $W_t = \{u \supsetneq s_n \; | \; q_t \nVdash u \notin \dot {T}_{\varphi _0(n)}\}$ . As in the proof of Lemma 4.2 $W_t$ alongside $s_n$ and its predecessors is a tree in $\mathcal I_T(\mathcal E)^+ \cap M$ hence it is densely diagonalized by g. Therefore we can find a $u_t \in W_t$ and a $k_t \in \mathrm {dom}(u_t) \setminus \mathrm {dom}(s_n)$ so that $u_t(k_t) = g(k_t)$ . Let $r_t \leq q_t$ force that $\check {u_t} \in \dot {T}_{\varphi _0(n)}$ . Now let $p_{n+1} = \bigcup _{t \in \mathrm {Split}_{n+1}(p_n)} r_t$ . Let $\dot {t}_n = \{(\check {u}_t, r_t) \; | \; t \in \mathrm { Split}_{n+1}(p_n)\}$ and $\dot {k}_n =\{(\check {k}_t, r_t) \; | \; t \in \mathrm {Split}_{n+1}(p_n)\}$ . Clearly these suffice.

Proof Let $p\in {\mathord {\mathbb Q}}_{\mathcal I}$ , M a countable elementary submodel of $H_{\theta }$ for $\theta $ sufficiently large such that $\mathcal I, \mathcal E, p\in M$ and let $g\in \mathcal E$ densely diagonalize every $T\in \mathcal I_T(\mathcal E)^+\cap M$ . We fix an enumeration $\{D_n \; | \; n\in \omega \}$ of all open dense subsets of ${\mathord {\mathbb Q}}_{\mathcal I}$ that are in M, and an enumeration $\{\dot {T}_n \; | \; n\in \omega \}$ of all ${\mathord {\mathbb Q}}_{\mathcal I}$ -names for elements of $\mathcal I_T(\mathcal E)^+$ that are in M. Let $\varphi :\omega \to \omega ^2$ with coordinate functions $\varphi _0$ and $\varphi _1$ .

We define a strategy for the first player in the game $\mathsf {GM}_{\mathcal I}(E)$ , which cannot be winning in all rounds.

We set $p_0=q_0=p$ and $u_0=\emptyset $ . We assume that the first player has chosen $E^1_n$ , $q_n$ , $p_n$ , $u_n$ , and the second one an $E^2_n$ . We give instructions to choose $E^1_{n+1}$ , $q_{n+1}$ , $p_{n+1}$ , $u_{n+1}$ . We begin with $q_{n+1}$ :

1. (1) $\mathrm {dom} (E^{q_{n+1}})=\mathrm {dom} (E^{p_n})$ .

2. (2) $xE^{q_{n+1}}y$ if and only if one of the following holds:

   1. (a) $xE^2_ny$ .

   2. (b) There is $k\in u_n$ with $x,y\in [k]_{E^{p_n}}$ and $x,y\not \in \mathrm {dom} (E^2_n)$ .

   3. (c) There are $k_0,k_1\not \in \bigcup \{[i]_{E^{p_n}} \; |\; i\in u_n\}$ with $x\in [k_0]_{E^{p_n}}$ , $y\in [k_1]_{E^{p_n}}$ , and $k_0,k_1\not \in \mathrm {dom} (E^2_n)$ .

3. (3) $H^{q_{n+1}}$ is chosen such that:

   1. (a) If $l\in \omega \setminus \mathrm {dom} E^{p_n}$ then $H^{q_{n+1}}(l)=^{**}H^{p_n}(l)$ .

   2. (b) If $l\in \mathrm {dom} (E^{p_n})\setminus A^{q_{n+1}}$ , $H^{p_n}(l)=g_i$ then $H^{q_{n+1}}(l)=H^{q_{n+1}}(i)$ .

   3. (c) If $l\in \mathrm {dom} (E^{p_n})\setminus A^{q_{n+1}}$ , $H^{p_n}(l)=1-g_i$ then $H^{q_{n+1}}(l)=1-H^{q_{n+1}}(i)$ .

   4. (d) If $l\in A^{p_n}\setminus A^{q_{n+1}}$ then $H^{q_{n+1}}(l)=^{**}H^{p_n}(\mathrm { min}[l]_{E^{q_{n+1}}})$ .

Note that for the already defined condition $q_{n+1}$ we have $q_{n+1}\leq _n p_n$ . Take $u_{n+1}=u_n\cup \{\min (A^{q_{n+1}}\setminus u_n)\}$ . Let $D^{\prime }_n$ be the set of all $r \leq p$ so that:

1. (1) r decides the $\varphi _1(n){\mathrm {th}}$ -node of $\dot {T}_{\varphi _0(n)}$ to be some $\check {s}_n$ .

2. (2) There is a $k < \omega $ and a $t \supseteq s_n$ so that $k \in \mathrm {dom}(t) \setminus \mathrm {dom}(s_n)$ and $r \Vdash \check {t} \in \dot {T}_{\varphi _0(n)}$ and $g(k) = t(k)$ .

As in the previous proofs, the set $D^{\prime }_n$ is open dense below p (and also below $q_{n+1}$ ). Then $D^{\prime }_n\cap D_n$ is dense below $q_{n+1}$ . Therefore we can apply Lemma 9.3 to obtain $p_{n+1}\leq _{n+1} q_{n+1}$ such that for each $h\in {}^{u_{n+1}}\{0,1\}$ , the condition $p^{[h]}_{n+1} \in D^{\prime }_n\cap D_n\cap M$ . In particular, if $h\in 2^{u_{n+1}}$ then $p_{n+1}^{[h]}$ decides the $\varphi _1(n){\mathrm {th}}$ node of $\dot {T}_{\varphi _0(n)}$ to be some $s_n$ , forces that there is a $k < \omega $ and a $t \supseteq s_n$ so that $k \in \mathrm {dom}(t) \setminus \mathrm {dom}(s_n)$ and $g(k) = t(k)$ and $p_{n+1}^{[h]}\in D_n\cap M$ . It follows that $p_{n+1}\Vdash $ “there is a t in $\dot {T}_{\varphi _0(n)}$ extending the $\varphi _1(n){\mathrm {th}}$ node and a $k \in \mathrm {dom}(t)$ above the domain of the $\varphi _1(n){\mathrm {th}}$ node of $\dot {T}_{\varphi _0(n)}$ so that $t(k) = g(k)$ ”. Finally, we set

$$ \begin{align*} E^1_{n+1}=E^{p_{n+1}}\upharpoonright(\mathrm{dom} (E^{p_{n+1}})\setminus\bigcup\{[i]_{E^{p_{n+1}}}\; | \; i\in u_{n+1}\}). \end{align*} $$