Answer to Question #222241 in Abstract Algebra for SabriShalalfeh

Solution:

Proof.

Let D be any noncommutative division ring (e.g., Hamilton's ring of real quaternions), and let "R=\\mathbb{M}_{n}(D[x])" , where "n \\geqslant 2" . Since D[x] is a PRID (principal right ideal ring), all modules in "\\mathcal{P}(D[x])" are free. This implies that D[x] is stably IC, so R is IC. Since

"\\mathbb{M}_{r}(R)=\\mathbb{M}_{r}\\left(\\mathbb{M}_{n}(D[x])\\right) \\cong \\mathbb{M}_{r n}(D[x])"

it follows that R is in fact stably IC. But

"R[y]=\\mathbb{M}_{n}(D[x])[y] \\cong \\mathbb{M}_{n}(D[x, y])" ...(i)

and by a result of Ojanguren and Sridharan Lemma, the polynomial ring S:=D[x, y] has a non-principal right ideal P such that "P \\oplus S \\cong S \\oplus S\\ in\\ \\mathcal{P}(S)" . This implies that "S_{S}^{2}" is not internally cancellable. Since "n \\geqslant 2" , the isomorphism in (i) implies that the ring R[y] is not IC. (Of course, for n=1, R[y]=D[x, y] would have been IC, since it is a domain.)

Thus, There exists a stably IC ring R such that the polynomial ring R[y] is not IC.

Proved.