The Annihilating-Ideal Graph of Commutative Rings II

Abstract

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 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 AG(R) that its vertices are A(R)* =A(R)-1mm\(0)\ in which for every distinct vertices I and J, I-0.6mm--1.7mm--1.7mm--0.5mmJ is an edge if and only if IJ=(0). First, we study the diameter of 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 (AG(R))≤ 2 or R is reduced and (AG(R))≤ ∞. Also it is shown that for each reduced ring R, (AG(R))= cl(AG(R)). Moreover, if (AG(R)) is finite, then R has a finite number of minimal primes, and if n is this number, then (AG(R))= cl(AG(R))= n. Finally, we show that for a Noetherian ring R, cl(AG(R)) is finite if and only if for every ideal I of R with I2=(0), I has finite number of R-submodules.