Consider the set $X = \mathbb{N}$, and let $\tau$ be the collection of all subsets $A \subset \mathbb{N}$ for which $\mathbb{N}\setminus A$ is finite, along with the empty set. I want to show $\tau$ is a topology on $\mathbb{N}$.
I know that the requirements for a set to be a topology is:
$\emptyset$ and $X$ are in $\tau$
The union of the elements of any subcollection of $\tau$ is in $\tau$
The intersection of the elements of any finite subcollection of $\tau$ is in $\tau$.
For this problem, I know that the first condition holds.
Can someone please help me show that the other two conditions for a topology hold as well so that I can prove that $\tau$ is a topology on $\mathbb{N}$