Abelian Group Factored by Prime

Theorem
Let $G$ be a finite abelian group.

Let $p$ be a prime.

Factor the order of $G$ as:
 * $\order G = m p^n$

such that $p$ does not divide $m$.

Then:
 * $G = H \times K$

where:
 * $H = \set{x \in G : x^{p^n} = e}$

and:
 * $K = \set {x \in G : x^m = e}$

Furthermore:
 * $\order H = p^n$

Proof
From Subgroup of Elements whose Order Divides Integer, both $H$ and $K$ are subgroups of $G$.

Also, because $G$ is abelian, $H$ and $K$ are normal by Subgroup of Abelian Group is Normal.

In order to prove $G = H \times K$, by the Internal Direct Product Theorem it suffices to show that $G = H K$ and $H \cap K = \set e$.

Since we have $\gcd \set {m, p^n} = 1$, there are integers $s$ and $t$ such that $1 = s m + t p^n$ by Bézout's Lemma.

Let $s$ and $t$ be two such integers.

So:
 * $\forall x \in G: x = x^{s m + t p^n} = x^{s m} x^{t p^n}$

From Element to Power of Group Order is Identity:
 * $x^{\order G} = e$

Therefore:
 * $\paren {x^{s m} }^{p^n} = \paren {x^{p^n m} }^s = e^s = e$

and:
 * $\paren {x^{t p^n} }^m = \paren {x^{p^n m} }^t = e^t = e$

By definition, $x^{s m} \in H$ and $x^{t p^n} \in K$.

We conclude that $G = H K$.

Now suppose that some $x \in H \cap K$.

Then $x^{p^n} = e = x^m$, so from Element to Power of Multiple of Order is Identity $\order x$ divides both $p^n$ and $m$.

Since $p$ does not divide $m$, it follows that $\order x = 1$.

Therefore, by Identity is Only Group Element of Order 1:
 * $x = e$

Thus:
 * $H \cap K = \set e$

It follows that $G = H \times K$.

Suppose that $p \divides \order K$.

From Cauchy's Group Theorem, this implies that there is some element (call it $k$) of $K$ with order $p$.

But we also have $k^m = e$ from the definition of $K$, so by Element to Power of Multiple of Order is Identity we must have $p \mathop \backslash m$, a contradiction.

We conclude that:
 * $p$ does not divide $\order K$

It follows that:
 * $p^n \divides \order H$

a prime $q$ (with $q \ne p$) divides $\order H$.

Again from Cauchy's Group Theorem, this implies that there is some element $h$ of $H$ with order $q$.

But since $h^{p^n} = e$ from the definition of $H$, Element to Power of Multiple of Order is Identity gives us $q \divides p^n$, a contradiction.

It follows by Proof by Contradiction that $q$ does not divide $\order H$.

We conclude $\order H = p^n$, as desired.