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The Annihilating-Ideal Graph of Commutative Rings II

In this paper we continue our study of annihilating-ideal graph of commutative rings, that was introduced in Part I (see [5]). Let $R$ be a commutative ring with ${\Bbb{A}}(R)$ its set of ideals with nonzero annihilator and $Z(R)$ its set of zero divisors. The annihilating-ideal graph of $R$ is defined as the (undirected) graph ${\Bbb{AG}}(R)$ that its vertices are $\Bbb{A}(R)^* =\Bbb{A}(R)\hspace{-1mm}\setminus\{(0)\}$ in which for every distinct vertices $I$ and $J$, $I\hspace{-0.6mm}-\hspace{-1.7mm}-\hspace{-1.7mm}-\hspace{-0.5mm}J$ is an edge if and only if $IJ=(0)$. First, we study the diameter of ${\Bbb{AG}}(R)$. A complete characterization for the possible diameter is given exclusively in terms of the ideals of $R$ when either $R$ is a Noetherian ring or $Z(R)$ is not an ideal of $R$. Next, we study coloring of annihilating-ideal graphs. Among other results, we characterize when either $χ({\Bbb{AG}}(R))\leq 2$ or $R$ is reduced and $χ({\Bbb{AG}}(R))\leq \infty$. Also it is shown that for each reduced ring $R$, $χ(\Bbb{AG}(R))= cl(\Bbb{AG}(R))$. Moreover, if $χ(\Bbb{AG}(R))$ is finite, then $R$ has a finite number of minimal primes, and if $n$ is this number, then $χ(\Bbb{AG}(R))= cl(\Bbb{AG}(R))= n$. Finally, we show that for a Noetherian ring $R$, $cl(\Bbb{AG}(R))$ is finite if and only if for every ideal $I$ of $R$ with $I^2=(0)$, $I$ has finite number of $R$-submodules.