Localization and containment in commutative ring

Question

Let $R$ be a commutative ring with identity and $x, y $ be fixed elements of $R$ such that for each maximal ideal $m$ of $R$ we have $\langle \frac{x}{1_m}\rangle\subseteq\langle \frac{y}{1_m}\rangle$ or $\langle \frac{y}{1_m}\rangle\subseteq\langle \frac{x}{1_m}\rangle$ in the ring $R_m$, (that is, $\langle \frac{x}{1_m}\rangle\subseteq\langle \frac{y}{1_m}\rangle$ for a maximal ideal $m$ of $R$ and $\langle \frac{y}{1_n}\rangle\subseteq\langle \frac{x}{1_n}\rangle$ for another maximal ideal $n$ of $R$) where $R_m$ is the localization of $R$ at $m$. I am looking for conditions under which that property implies $\langle x\rangle\subseteq\langle y\rangle$ or $\langle y\rangle\subseteq\langle x\rangle$ in the ring $R$.

Answer 1

The conclusion is true if and only if $R$ has at most 1 maximal ideal, i.e., $R$ is either itself a local ring, or the zero ring. The "if" part is trivial: for the case of local ring see the comment above, and the zero ring is even more trivial. and we now show the "only if" part by contrapositive.

Suppose $R$ has at least 2 maximal ideals $m$ and $n$. Since $m+n=(1)$, by the Chinese Remainder Theorem, there is $x\in R$ such that $x=-1\pmod m$ and $x=0\pmod n$. Set $y=x+1$. Then there is no maximal ideal containing both $x$ and $y$. In other words, for any maximal ideal $p$, either $x\notin (p)$ or $y\notin (p)$. Then either $(x)_{(p)}$ or $(y)_{(p)}=(1)$ in $R_{(p)}$, which then contains every other ideal. On the other hand, $(x)$ and $(y)$ does not contain each other, for otherwise either $(x)$ or $(y)$ would contain 1, that is, either $x$ or $y$ would be a unit, but both $x\in (n)$ and $y\in (m)$ cannot be units, contradiction.