On the coloring of the annihilating-ideal graph of a commutative ring

Suppose that R is a commutative ring with identity. Let A(R) be the set of all ideals of R with non-zero annihilators. The annihilating-ideal graph of R is defined as the graph AG(R) with the vertex set A(R)∗=A(R)∖{(0)} and two distinct vertices I and J are adjacent if and only if IJ=(0). In Behbood...

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Bibliographic Details
Published in:Discrete mathematics 2012-09, Vol.312 (17), p.2620-2626
Main Authors: Aalipour, G., Akbari, S., Nikandish, R., Nikmehr, M.J., Shaveisi, F.
Format: Article
Language:English
Subjects:
Annihilating-ideal graph
Chromatic number
Clique number
Coloring
Graphs
Mathematical analysis
Minimal prime ideal
Rings (mathematics)
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Summary:Suppose that R is a commutative ring with identity. Let A(R) be the set of all ideals of R with non-zero annihilators. The annihilating-ideal graph of R is defined as the graph AG(R) with the vertex set A(R)∗=A(R)∖{(0)} and two distinct vertices I and J are adjacent if and only if IJ=(0). In Behboodi and Rakeei (2011) [8], it was conjectured that for a reduced ring R with more than two minimal prime ideals, girth(AG(R))=3. Here, we prove that for every (not necessarily reduced) ring R, ω(AG(R))≥|Min(R)|, which shows that the conjecture is true. Also in this paper, we present some results on the clique number and the chromatic number of the annihilating-ideal graph of a commutative ring. Among other results, it is shown that if the chromatic number of the zero-divisor graph is finite, then the chromatic number of the annihilating-ideal graph is finite too. We investigate commutative rings whose annihilating-ideal graphs are bipartite. It is proved that AG(R) is bipartite if and only if AG(R) is triangle-free.
ISSN:0012-365X
1872-681X
DOI:10.1016/j.disc.2011.10.020