From the theorem of classification of finitely generated abelian groups, we can see that every finitely generated commutative group can be considered as the additive structure underlying (at least) one unitary and commutative ring. My question is about possible generalization of this result. Question: Is it true that with every abelian group G it is possible to build (at least) one ring(resp: unitary ring, commutative ring) whose additive structure is the group structure on G ? Gérard Lang

3$\begingroup$ The inductive limit of the cyclic groups ${\mathbb Z}/p^n$ cannot be the additive group of a unitary ring. There are tons of more sofisticated examples. $\endgroup$– Sasha Anan'inJan 18 '14 at 19:12
As Sasha Anan'in already mentioned, there are counterexamples like $\mathbb{Z}/p^\infty = \mathbb{Z}[\frac{1}{p}]/\mathbb{Z}$ and $\mathbb{Q}/\mathbb{Z}$. The common feature of these groups is that there are divisible and torsion and therefore $A\otimes_\mathbb{Z}A=0$. A ring $A$ has a surjective and hence nonzero map $A\otimes_\mathbb{Z}A\to A$ namely the multiplication. Therefore no additive group with $A\otimes_\mathbb{Z}A=0$ can be the additive group of a ring.
No, there are many abelian groups such that only zero multiplication can be defined over them. Even if you can define a nonzero multiplication on a group, the ring obtained may have no unit, also it may not be associative, and so on. A detailed discussion of this subject can be find in L. Fuchs: (Infinite abelian groups). Two former Ph.D students of our department have also some papers in the subject. You can find their works searching the names: "A. Najafizadeh, F. Karimi, A. M. Aghdam", and key words "torsion free groups, additive group of rings". One more interesting problem is to determine which subgroups of an abelina group $A$ can be realized as ideals in some ring with additive group $A$. You can find some good results concerning this problem.

$\begingroup$ One more point: I didn't see this problem before. Suppose $A$ is an abelian group such that it is possible to define an associative unitary ring structure on $A$. Then which elements of $A$ will be candidates for the identity element of such a ring? $\endgroup$– Sh.M1972Jan 18 '14 at 21:04