Convergent Sequence in Set of Integers

Theorem
Let $\left \langle {x_n}\right \rangle_{n \in \N}$ be a sequence in the set $\Z$ of integers considered as a subspace of the real number line $\R$ under the Euclidean metric.

Then $\left \langle {x_n}\right \rangle_{n \in \N}$ converges in $\R$ to a limit iff:
 * $\exists k \in \N: \forall m \in \N: m > k: x_m = x_k$

That is, iff the sequence reaches some value of $\Z$ and "stays there".

Corollary
Let $\left \langle {x'_n}\right \rangle_{n \in \N}$ be a sequence of distinct terms in the set $\Z$.

Then $\left \langle {x'_n}\right \rangle_{n \in \N}$ is not convergent.

Proof
Suppose $\left \langle {x_n}\right \rangle_{n \in \N}$ converges to a limit $l$.

Consider the open set in $\R$:
 * $U := \left({l - \dfrac 1 2 .. l + \dfrac 1 2}\right)$

Then $\forall x \in \Z: x \in U \implies x = l$

It follows by definition of convergence that:
 * $\exists k \in \N: \forall m \in \N: m > k: x_m = l$

where $l = x_k$.

Now suppose that:
 * $\exists k \in \N: \forall m \in \N: m > k: x_m = x_k$

Then trivially $\left \langle {x_n}\right \rangle_{n \in \N}$ converges to the limit $x_k$.

Proof of Corollary
Trivially:
 * $\neg \exists k \in \N: \forall m \in \N: m > k: x'_m = x'_k$