Let $\mathscr{C}\subset \mathscr{P}(\Omega)$ be a class of subsets of a nonempty set $\Omega$ containing $\Omega$ and $\varnothing$. Define $\mathscr{C}_0=\mathscr{C}$ and for each $n\geq 1$ define $$ \mathscr{C}_{n+1}=\mathscr{C}_n\cup \{A^c:~ A\in \mathscr{C}_n\}\cup \{\bigcup_{i=1}^\infty A_{i}: ~\{A_{i}\}_{i=1}^\infty\subset \mathscr{C}_n\}. $$
Question: I am looking for an example of $\Omega$ such that $\mathscr{A}(\mathscr{C})=\bigcup_{i=1}^\infty \mathscr{C}_n$ do not equal to $\sigma(\mathscr{C})$ the sigma álgebra generated by $\mathscr{C}$.
I first try to pick a $\Omega=\mathbb{R}$ and consider $\mathscr{C}$ the class given by the finite and cofinite sets, however applying the above procedure we get the the class of the contable and co-countable subsets, which is a sigma álgebra....
I know that must be examples that $\mathscr{A}(\mathscr{C})=\bigcup_{i=1}^\infty \mathscr{C}_n$ do not equal to $\sigma(\mathscr{C})$ because we need of an ordinal argument in the construction...
