Let $R$ be a commutative Ring, $M$ an $R$-module, we define $\text{Ann} _R(M) := \{ r \in R : rm = 0 \text{ }\forall m \in M\} $. As an exercise we have to show:
"$M$ noetherian $\iff$ $M$ finitely generated, $R/\text{Ann}_R(M)$ noetherian "
I was able to prove the "=>" implication, however i am struggling with the other direction. I do not really know how I can use the condition "$R/\text{Ann}_R(M)$ noetherian ". What does this tell me about the submodules of $M$? I do not see the connection. My first guess was to consider finitely generated $R/\text{Ann}_R(M)$-modules, which would automatically be noetherian, maybe there could exist such a module that is isomorphic to $M$ (or a submodule of $M$?), however, my attempt didn't succeed.
My second guess was to use induction over the number of M-generating elements. Here, I was unable to go back to the inductive hypothesis. What else could I try here? Does somebody have some advice for me? Thanks in advance!
Let us put $R_M=R/\mathrm{Ann}_R(M)$. Note that
The lattices of $R$-submodules of $M$ and that of $R_M$-submodules of $M$ are equal. This is relevant because the noetherian property you are after is a property of the lattice of submodules: $M$ noetherian $R$-module means that every nonempty collection of submodules has a maximal element. Thus $M$ is noetherian as an $R$-module iff it is noetherian as an $R_M$-module.
Note furthermore that:
In particular, $M$ is finitely generated over $R$ if and only if it is finitely generated over $R_M$.
Proof of $(\!\!\impliedby\!\!)$ Suppose $M$ is finitely generated over $R$. By the preceding point it is finitely generated over $R_M$. If we furthermore assume $R_M$ to be noetherian, then so is the finitely generated $R_M$-module $M$. By the point in bold, $M$ is noetherian over $R$.