Proving that surjective endomorphisms of Noetherian modules are isomorphisms and a semi-simple and noetherian module is artinian.

$1.$ Let $M$ be a Noetherian $R$ - module. We prove that if $f : M \longrightarrow M$ is a surjective $R$ - module homomorphism from $M$ to itself, then $f$ is an isomorphism. It is easy to see that it suffices to prove that $f$ is injective. Now the kernel of any $R$ - module homomorphism is always a submodule, so we can consider the following ascending chain of kernels

$$\ker f \subset \ker f^2 \subset \ker f^3 \subset ....$$

that must eventually become constant by the Noetherian condition so we may suppose that there is $ n \in \Bbb{N}$ such that

$$\ker f^n = \ker f^{n+1} = \ker f^{n+2} = \ldots = \ker f^{2n} = \ldots .$$

Now we claim that

$$\ker f^n \cap \operatorname{Im} f^n = \{0\}.$$

Clearly $0$ is in the left hand side so we just need to show the reverse inclusion. Take $x \in \ker f^n \cap \operatorname{Im} f^n$. Then $f^n(x) = 0$ and there exists $y \in M$ such that $x = f^n(y)$. Putting this expression found for $x$ into $f^n(x) = 0$ we get that

$$f^{2n}(y) = 0$$

and hence that $y \in \ker f^{2n}$. But then as noted above $\ker f^{2n} = \ker f^n$ and hence that $f^n(y) = 0$. But $x = f^n(y)$ and so $x$ itself is zero proving our claim that $\ker f^n \cap \operatorname{Im} f^n = \{0\}$. Now because $f$ is surjective it follows that $\operatorname{Im} f^n = M$. However $\ker f^n \subset M$ so that $\{0\} = \ker f \cap M = \ker f$ so that $f$ is injective, and hence an isomorphism.

$\hspace{6in} \square$

Edit: Supplementary problems:

(1) Prove that any injective $R$ - module endomorphism $\phi : M \rightarrow M$ for $M$ an Artinian module is surjective (and hence an isomorphism). Hint: Consider the descending chain

$$\operatorname{Coker} \phi \supset \operatorname{Coker} \phi^2 \supset \operatorname{Coker} \phi^3 \supset \ldots $$

(2) Considering an Artinian ring $R$ as a module over itself, prove that if $R$ is an Artinian integral domain then it must be a field (Hint: Consider a suitable $R$ - module endomorphism and apply (1) above).

(3) Let $R$ be an Artinian local ring with maximal ideal $\mathfrak{m}$. Prove that $\mathfrak{m}$ of $R$ is nilpotent. Hint: By the Artinian condition we have the descending chain $$\mathfrak{m} \supset \mathfrak{m}^2 \supset \ldots \supset \mathfrak{m}^k = \mathfrak{m}^{k+1} = \ldots $$

for some $k \in \Bbb{N}$. Suppose that $\mathfrak{m}^k \neq 0$ (Yes we are using the same $k$). By Zorn's Lemma one can choose an ideal $I$ in $R$ minimal with respect to the property that $I\cdot \mathfrak{m}^k \neq 0$. This is saying that there exists an element $x \in I$ such that $x \mathfrak{m}^k \neq 0$ and hence by minimality of $I$, $(x) = I$. Considering $(x)$ as an $R$ - module and noting it is finitely generated, conclude that

$$(x)\mathfrak{m}^k = (x)$$

and apply Nakayama's Lemma to get a contradiction.


$1.$ Let me give you a proof of the following astonishing result due to Vasconcelos:

Theorem:
Let $M$ be a finitely generated $R$-module, Noetherian or not, and let $ \ f : M \rightarrow M \ $ be a surjective homomorphism. Then $f : M \rightarrow M $ is injective (hence is an isomorphism).

Proof:
We use the standard trick of converting $M$ into an $R[X]$-module by defining $X\cdot m=f(m)$.
For the ideal $I=XR[X]$ we have $M=IM$ since for any $m\in M$ we can write by surjectivity of $f$ : $m=f(n)=X\cdot n$ and $X\in I$.
Since Nakayama says that $$M=IM\implies m=im$$ there exists $i=P(X)X\in I$ with $m=P(X)X\cdot m=P(f)(f(m))$ for all $m\in M$.
So that finally $f(m)=0\implies m=P(f)(f(m))=P(f)(0)=0 \:$: injectivity of $f$ has been proved.


$2.$ A semisimple module $M$ is a direct sum of simple modules. If it is noetherian, there are finitely many summands in that decomposition, and then $M$ has finite length. It is therefore artinian.