Countable Hypothesis Set has Finished Tableau

Lemma
Let $\mathbf H$ be a countable set of propositional WFFs.

Then there exists a finished tableau whose root node is $\mathbf H$.

Proof
The Tableau Extension Lemma shows that each finite hypothesis set $\mathbf H$ is the root of some finished tableau.

It remains, then, to show that the result still applies when $\mathbf H = \left\{{\mathbf A_1, \ldots, \mathbf A_n, \ldots}\right\}$ is countably infinite.

Let $\mathbf H_n = \left\{{\mathbf A_1, \ldots, \mathbf A_n}\right\} \subset \mathbf H$.

We will say that a finite tableau $T_n$ with root $\mathbf H$ is finished for $\mathbf H_n$ if the tableau $T'_n$ is finished where:
 * $T'_n$ is the same as $T_n$ except:


 * $T'_n$ has the root $\mathbf H_n$ instead of $\mathbf H$.

We can use the Tableau Extension Lemma countably many times, and get a sequence of finite tableaus $T_0, T_1, \ldots, T_n, \ldots$ such that:
 * $T_0$ has only a root node;


 * For each $n > 0$, $T_n$ is an extension of $T_{n-1}$ such that $T_n$ is finished for $\mathbf H_n$;


 * For each $n > 0$, $T_n$ has the property that no contradictory branch $\Gamma$ of $T_{n-1}$ gets extended when forming $T_n$.

Now, let $T$ be the union $\displaystyle T = \bigcup_{k \mathop = 0}^\infty T_k$.

Let $\Gamma$ be a branch of $T$.

Suppose $\Gamma$ is contradictory, with complementary pair $\mathbf A, \neg \mathbf A$.

Then $\exists n \in \N$ such that both $\mathbf A$ and $\neg \mathbf A$ are in $T_n$.

Then $\Gamma \cap T_n$ is already a contradictory branch of $T_n$.

So, by our method of construction of $T$, this branch $\Gamma \cap T_n$ is never extended past stage $n$, so $\Gamma = \Gamma \cap T_n$ and $\Gamma$ is finite.

On the other hand, suppose $\Gamma$ is not contradictory.

Then the construction ensures that $\Gamma$ is a finished branch.

So $T$ is a finished tableau whose root node is $\mathbf H$.