The total torsion element graph of semimodules over commutative semirings

The total torsion element graph of semimodules over commutative semirings

We introduce and investigate the total torsion element graph of semimodules over a commutative semiring with non-zero identity. The main purpose of this paper is to extend the definition and results given in [2] to more general semimodule case.

Saved in:
Bibliographic Details
Date:2013
Main Authors: Ebrahimi Atani, S., Esmaeili Khalil Saraei, F.
Format: Article
Language:English
Published: Інститут прикладної математики і механіки НАН України 2013
Series:Algebra and Discrete Mathematics
Online Access:https://nasplib.isofts.kiev.ua/handle/123456789/152303
Tags: Add Tag
No Tags, Be the first to tag this record!
Journal Title:Digital Library of Periodicals of National Academy of Sciences of Ukraine
Cite this:The total torsion element graph of semimodules over commutative semirings / S. Ebrahimi Atani, F. Esmaeili Khalil Saraei // Algebra and Discrete Mathematics. — 2013. — Vol. 16, № 1. — С. 1–15. — Бібліогр.: 15 назв. — англ.

Institution

Digital Library of Periodicals of National Academy of Sciences of Ukraine
id nasplib_isofts_kiev_ua-123456789-152303
record_format dspace
spelling nasplib_isofts_kiev_ua-123456789-1523032025-02-09T09:49:25Z The total torsion element graph of semimodules over commutative semirings Ebrahimi Atani, S. Esmaeili Khalil Saraei, F. We introduce and investigate the total torsion element graph of semimodules over a commutative semiring with non-zero identity. The main purpose of this paper is to extend the definition and results given in [2] to more general semimodule case. 2013 Article The total torsion element graph of semimodules over commutative semirings / S. Ebrahimi Atani, F. Esmaeili Khalil Saraei // Algebra and Discrete Mathematics. — 2013. — Vol. 16, № 1. — С. 1–15. — Бібліогр.: 15 назв. — англ. 1726-3255 2010 MSC:16Y60, 05C75. https://nasplib.isofts.kiev.ua/handle/123456789/152303 en Algebra and Discrete Mathematics application/pdf Інститут прикладної математики і механіки НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description We introduce and investigate the total torsion element graph of semimodules over a commutative semiring with non-zero identity. The main purpose of this paper is to extend the definition and results given in [2] to more general semimodule case.
format Article
author Ebrahimi Atani, S.
Esmaeili Khalil Saraei, F.
spellingShingle Ebrahimi Atani, S.
Esmaeili Khalil Saraei, F.
The total torsion element graph of semimodules over commutative semirings
Algebra and Discrete Mathematics
author_facet Ebrahimi Atani, S.
Esmaeili Khalil Saraei, F.
author_sort Ebrahimi Atani, S.
title The total torsion element graph of semimodules over commutative semirings
title_short The total torsion element graph of semimodules over commutative semirings
title_full The total torsion element graph of semimodules over commutative semirings
title_fullStr The total torsion element graph of semimodules over commutative semirings
title_full_unstemmed The total torsion element graph of semimodules over commutative semirings
title_sort total torsion element graph of semimodules over commutative semirings
publisher Інститут прикладної математики і механіки НАН України
publishDate 2013
url https://nasplib.isofts.kiev.ua/handle/123456789/152303
citation_txt The total torsion element graph of semimodules over commutative semirings / S. Ebrahimi Atani, F. Esmaeili Khalil Saraei // Algebra and Discrete Mathematics. — 2013. — Vol. 16, № 1. — С. 1–15. — Бібліогр.: 15 назв. — англ.
series Algebra and Discrete Mathematics
work_keys_str_mv AT ebrahimiatanis thetotaltorsionelementgraphofsemimodulesovercommutativesemirings
AT esmaeilikhalilsaraeif thetotaltorsionelementgraphofsemimodulesovercommutativesemirings
AT ebrahimiatanis totaltorsionelementgraphofsemimodulesovercommutativesemirings
AT esmaeilikhalilsaraeif totaltorsionelementgraphofsemimodulesovercommutativesemirings
first_indexed 2025-11-25T12:53:57Z
last_indexed 2025-11-25T12:53:57Z
_version_ 1849766962472681472
fulltext Algebra and Discrete Mathematics RESEARCH ARTICLE Volume 16 (2013). Number 1. pp. 1 – 15 © Journal “Algebra and Discrete Mathematics” The total torsion element graph of semimodules over commutative semirings S. Ebrahimi Atani and F. Esmaeili Khalil Saraei Communicated by D. Simson Abstract. We introduce and investigate the total torsion element graph of semimodules over a commutative semiring with non-zero identity. The main purpose of this paper is to extend the definition and results given in [2] to more general semimodule case. 1. Introduction In [6], Beck associated to any commutative ring R its zero-divisor graph G(R) whose vertices are the zero-divisors of R (including 0), with two vertices a, b joined by an edge in case ab = 0. The problem Beck studied was how to color the vertices of G(R) with the smallest number of colors such that no two adjacent vertices in the graph had the same color. Beck conjectured this number is the clique number of G(R), but Beck’s question was settled in the negative in [1]. In [3], Anderson and Livingston introduced and studied the subgraph Γ(R) whose vertices are the nonzero zero-divisors of R. This graph turns out to best exhibit the properties of the set of zero-divisors of R, and the ideas and problems introduced in [3] were further studied in [15], [9] and [10]. Let R be a commutative ring with Z(R) its set of zero-divisors elements. The total graph of R, denoted by T (Γ(R)), is the (undirected) graph with all elements of R as vertices, and for distinct x, y ∈ R, the vertices x and y are adjacent if 2010 MSC: 16Y60, 05C75. Key words and phrases: Semiring, Torsion element graph, k-subsemimodules, QM -subsemimodules. 2 The total torsion element graph of semimodules and only if x + y ∈ Z(R). The total graph of a commutative ring have been introduced and studied by D. F. Anderson and A. Badawi in [2]. In [12], the notion of the total torsion element graph of a module over a commutative ring is introduced. Subsemimodules of semimodules over semirings play a central role in the structure theory and are useful for many purposes [13, 14]. How- ever, they do not in general coincide with the submodules over rings and, for this reason, their use is somewhat limited in trying to obtain analogues of ring theorems for semirings. Indeed, many results in rings apparently have no analogues in semirings using only subsemimodules. In order to overcome this deficiency, the authors defined a more restricted class of subsemimodules in semirings, which are called the class of "k- subsemimodules" and the class of "QM -subsemimodules" [5, 8, 7]. In the present paper we introduce a new class of graphs, called the total torsion element graph of a semimodule over a semiring, and we completely char- acterize the structure of this graph. The total torsion element graph of a module over a commutative ring and the total torsion element graph of a semimodule over a commutative semiring are different concepts. Some of our results are analogous to the results given in [2]. The correspond- ing results are obtained by modification and here we give a complete description of the total torsion element graph of a semimodule. The study of the total torsion element graph of a semimodule M breaks naturally into two cases depending on whether or not T (M), the set of torsion elements in M , is a subsemimodule of M . In the third section, we handle the case when T (M) is a subsemimodule (either k-subsemimodule or QM -subsemimodule) of M ; in the fourth section, we do the case when T (M) is not a subsemimodule of M (see Sections 3, 4). 2. Preliminaries For the sake of completeness, we state some definitions and notation used throughout. For a graph Γ, by E(Γ) and V (Γ), we denote the set of all edges and vertices, respectively. We recall that a graph is connected if there exists a path connecting any two distinct vertices. The distance between two distinct vertices a and b, denoted by d(a, b), is the length of a shortest path connecting them (if such a path does not exist, then d(a, a) = 0 and d(a, b) = ∞). The diameter of a graph Γ, denoted by diam(Γ), is equal to sup{d(a, b) : a, b ∈ V (Γ)}. A graph is complete if it is connected with diameter less than or equal to one. The girth of a graph Γ, denoted gr(Γ), is the length of a shortest cycle in Γ, provided Γ contains a cycle; S. Ebrahimi Atani, F. Esmaeili Khalil Saraei 3 otherwise; gr(Γ) = ∞. We denote the complete graph on n vertices by Kn and the complete bipartite graph on m and n vertices by Km,n (we allow m and n to be infinite cardinals). We will sometimes call a K1,m a star graph. We say that two (induced) subgraphs Γ1 and Γ2 of Γ are disjoint if Γ1 and Γ2 have no common vertices and no vertex of Γ1 (respectively, Γ2) is adjacent (in Γ) to any vertex not in Γ1 (respectively, Γ2). Throughout this paper R is a commutative semiring with identity. In order to make this paper easier to follow, we recall in this section various notions from semimodule theory which will be used in the sequel. For the definitions of monoid, semirings, semimodules and subsemimodules we refer [13, 14, 7, 8]. All semiring in this paper are commutative with non-zero identity. Let M be a semimodule over a semiring R. (1) A semiring R is said to be semidomain whenever a, b ∈ R with ab = 0 implies that either a = 0 or b = 0. (2) A subtractive subsemimodule (= k-subsemimodule) N is a sub- semimodule of M such that if x, x + y ∈ N , then y ∈ N (so {0M } is a k-subsemimodule of M). (3) An element x of M is called a zero-sum in M if x + y = 0 for some y ∈ M . We use S(M) to denote the set of all zero-sum elements of M . (4) A semimodule M over a semiring R is called a M -cancellative semimodule if whenever rm = rn for elements m, n ∈ M and r ∈ R, then n = m. (5) A subsemimodule N of a semimodule M over a semiring R is called a partitioning subsemimodule (= QM -subsemimodule) if there exists a subset QM of M such that M = ∪{q + N : q ∈ QM } and if q1, q2 ∈ QM then (q1 + N) ∩ (q2 + N) 6= ∅ if and only if q1 = q2. Let N be a QM -subsemimodule of M and let M/N = {q + N : q ∈ QM }. Then M/N forms an R-semimodule under the operations ⊕ and ⊙ defined as follows: (q1 + N) ⊕ (q2 + N) = q3 + N , where q3 ∈ QM is the unique element such that q1 + q2 + N ⊆ q3 + N and r ⊙ (q1 + N) = q4 + I, where r ∈ R and q4 ∈ QM is the unique element such that rq1 + N ⊆ q4 + N . This R-semimodule M/N is called the quotient semimodule of M by N [7]. By [7, Lemma 2.3], there exists a unique element q0 ∈ QM such that q0 + N = N . Thus q0 + N is the zero element of M/N . (6) A torsion element is an element m ∈ M for which there exists a non-zero element r of R such that rm = 0. The set of torsion elements in M will be denoted by T (M). Also, we use T (M)∗ to denote the set of non-zero torsion elements of M . (7) We define the total torsion element graph of a semimodule M , denoted by T (Γ(M)), as follows: V (T (Γ(M))) = M , E(T (Γ(M))) = 4 The total torsion element graph of semimodules {{x, y} : x + y ∈ T (M)}. We will use Tof(M) to denote the set of elements of M that are not torsion elements. Let Tof(Γ(M)) be the (induced) subgraph of T (Γ(M)) with vertices Tof(M), and let Tor(Γ(M)) be the (induced) subgraph of T (Γ(M)) with vertices T (M). 3. T (M) is a subsemimodule of M Let M be a semimodule over a semiring R. The structure of the torsion element graph T (Γ(M)) may be completely described in those cases when torsion elements form a subsemimodule. We begin this section with the extreme cases T (M) = M and T (M) = {0}. Theorem 3.1. Let M be a semimodule over a semiring R. (i) T (Γ(M)) is complete if and only if T (M) = M . (ii) T (Γ(M)) is totally disconnected if and only if T (M) = S(M) = {0}. Proof. (i) If T (M) = M , then for any two vertices x, y ∈ M , one has x + y ∈ T (M); hence they are adjacent in T (Γ(M)). Conversely, assume that T (Γ(M)) is complete and let m ∈ M . Then m is adjacent to 0. Thus m = m + 0 ∈ T (M), and hence we have equality. (ii) Let T (Γ(M)) be totally disconnected. Then 0 is not adjacent to any vertex; hence x = x + 0 /∈ T (M) for every non-zero element x of M . Thus T (M) = {0}. If there is a non-zero element m of S(M), then there exists 0 6= m′ ∈ M such that m + m′ = 0 ∈ T (M), which is a contradiction. Thus S(M) = {0}. Conversely, assume that there exist distinct a, b ∈ M such that a + b ∈ T (M) = {0}. Then a, b ∈ S(M), a contradiction. Hence T (Γ(M)) is totally disconnected. Proposition 3.2. Let M be a semimodule over a commutative semir- ing R. (i) If 2 = 1R + 1R ∈ Z(R) and x ∈ M , then 2x ∈ T (M). In particular, if T (M) = {0}, then M is an R-module. (ii) If x ∈ Tof(M), then 2 ∈ Z(R) if and only if 2x ∈ T (M). Proof. (i) By assumption, there exists 0 6= r ∈ R such that 2r = 0. Since r(2x) = (2r)x = 0, we have 2x ∈ T (M). Finally, by assumption, 2x = 0 for every x ∈ M , as required. (ii) By (i), it is enough to show that if 2x ∈ T (M), then 2 ∈ Z(R). There exists a non-zero element s of R such that (2s)x = s(2x) = 0; hence 2s = 0 since x /∈ T (M). Thus 2 ∈ Z(R). S. Ebrahimi Atani, F. Esmaeili Khalil Saraei 5 Example 3.3. (1) A subsemimodule of a semimodule over a semiring in general need not be a k-subsemimodule and QM -subsemimodule. Let M = R be the set of all real numbers x satisfying 0 < x ≤ 1, and define a + b = a.b = min{a, b} for all a, b ∈ R. Then (R, +, .) is easily checked to be a commutative semiring with 1 as identity. Each real number r such that 0 < r < 1 defines a subsemimodule N = {y ∈ M : y ≤ r} of M . However, r + 1 = 1 together r ∈ N and 1 /∈ N show that N is not a k- subsemimodule of M . In particular, N is not a QM -subsemimodule of M since every QM -subsemimodule is a k-subsemimodule by [7, Theorem 3.2]. (2) Let R = M denote the semiring of nonnegative integers with the usual operations of addition and multiplication. If m ∈ M − {0}, the subsemimodule N = {km : k ∈ R} is a QM -subsemimodule of M when QM = {0, 1, · · · , m−1}. In particular, N is a k-subsemimodule. (3) Assume that R is the semiring of nonnegative integers with the usual operations of addition and multiplication and let M = (R, gcd). It is easy to see that M is a commutative monoid in which every element is idempotent. Hence M is an R-semimodule in which N = {0, 2, 4, · · · } is a k-subsemomodule of M but not a QM -subsemimodule. Proposition 3.4. Let M be a semimodule over a semidomain R. (i) T (M) is a k-subsemimodule of M . (ii) If M is a M -cancellative semimodule, then T (M) is a QM -sub- semimodule of M . Proof. (i) Clearly, T (M) is a subsemimodule of M . Let x + y, x ∈ T (M) for some x, y ∈ M . Then rx = s(x + y) = 0 for some 0 6= r, s ∈ R (so rs 6= 0). Therefore, (rs)y = 0, and so y ∈ T (M). (ii) Set QM = (M − T (M)) ∪ {0}; we show that T (M) is a QM - subsemimodule of M . Let m ∈ M . If m ∈ T (M), then m ∈ 0M + T (M). If m /∈ T (M), then m ∈ m + T (M). So M = ∪{q + T (M) : q ∈ QM }. Let (q1 + T (M)) ∩ (q2 + T (M)) 6= ∅. So q1 + a = q2 + b for some a, b ∈ T (M). It follows that ra = sb = 0 for some 0 6= r, s ∈ R. Therefore, rsq1 = rsq2 with rs 6= 0 since R is a semidomain. Thus q1 = q2 since M is a M - cancellative semimodule, as needed. 6 The total torsion element graph of semimodules Proposition 3.5. Let M be a semimodule over a commutative semiring R such that T (M) is a subsemimodule of M . (i) Tor(Γ(M)) is a complete (induced) subgraph of T (Γ(M)). (ii) If N is a subsimimodule of M , then T (Γ(N)) is the induced subgraph of T (Γ(M)) if and only T (N) = N ∩ T (M). (iii) If (0 : M) 6= 0, then T (Γ(M)) is a complete graph. Proof. The proofs are straightforward. Example 3.6 shows that there are some semimodules over commutative semirings such that their torsion subsemimodules are not k-subsemimodues. Example 3.6. Assume that E+ be the set of all non-negative inte- gers and let M = R = {(a, b) : a, b ∈ E+}. Define (a, b) + (c, d) = (min{a, c}, max{b, d}) and (a, b) ∗ (c, d) = (ac, bd) for all (a, b), (c, d) ∈ R. Then (R, +, ∗) is easily checked to be a commutative semiring. An in- spection will show that T (M) = {(a, b) ∈ M : a = 0 or b = 0} is a subsemimodule of M . However, (0, 1) + (2, 5) = (0, 5) ∈ T (M) to- gether with (2, 5) /∈ T (M) and (0, 1) ∈ T (M) show that T (M) is not a k-subsemimodule of M . Also, T (Γ(M)) is a connected graph since every element is adjacent to (0, 0) in T (Γ(M)). Moreover, gr(T (Γ(M))) = 3 since there is a 3-cyclic (0, 0) − (0, 1) − (1, 0) − (0, 0) in T (Γ(M)). Example 3.7 shows that there are some semimodules over commutative semirings such that their torsion subsemimodules are k-subsemimodues but they are not QM -subsemimodules. Example 3.7. Assume that R = M is the set of all non-negative integers and let a, b, k ∈ R. Define a + b = gcd(a, b) and a ∗ b =      0 if gcd(a, b) = 2k, 1 if gcd(a, b) = 2k + 1, 0 a = 0 or b = 0. Then (R, +, ∗) is easily checked to be a commutative semiring. An in- spection will show that T (M) = {0, 2, 4, 6, · · · } is a k-subsemimodule of M but is not a QM -subsemimodule of M by Example 3.3 (3). Moreover, Tor(Γ(M)) is a complete graph and Tof(Γ(M)) is a totally disconnected graph. The main goal of this section is a general structure theorem (The- orem 3.10) for Tof(Γ(M)) when either T (M) is a k- subsemimodule S. Ebrahimi Atani, F. Esmaeili Khalil Saraei 7 of M or T (M) is a QM -subsemimodule. But first, we record the ba- sic observation that if T (M) is a k-subsemimodule of (resp. T (M) is not a k-subsemimodule), then the subgraph Tor(Γ(M)) is disjoint from Tof(Γ(M)) (resp. Tor(Γ(M)) is not disjoint from Tof(Γ(M)). Thus we will concentrate on the subgraph Tof(Γ(M)) throughout this section. Theorem 3.8. Let M be a semimodule over a commutative semiring R such that T (M) is a k-subsemimodule of M . If m and m′ are distinct elements of Tof(M) that are connected by a path with m + m′ /∈ T (M) (i.e., if m and m′ are not adjacent), then there is a path in Tof(Γ(M)) of length at most 2 between m and m′. Proof. Let T (M) be a k-subsemimodule of M . It is enough to show that if m1, m2, m3 and m4 are distinct vertices of Tof(M) and there is a path m1 −m2 −m3 −m4 from m1 to m4, then m1 and m4 are adjacent. Now we have m1 + m2 + m3 + m4 ∈ T (M). Then T (M) being k-subsemimodule of M gives m1+m4 ∈ T (M), and so m1 and m4 are adjacent, as required. Compare the next theorem with [12, Theorem 2.1 (1)]. Theorem 3.9. Let M be a semimodule over a commutative semiring R. (i) If T (M) is a k-subsemimodule of M , then Tor(Γ(M)) is disjoint from Tof(Γ(M)). (ii) If T (M) is not a k-subsemimodule of M , then Tor(Γ(M)) is not disjoint from Tof(Γ(M)). Proof. (i) Let T (M) is a k-subsemimodule of M . If Tor(Γ(M)) is not dis- joint from Tof(Γ(M)), then there exist a ∈ T (M) and b ∈ Tof(M) such that a + b ∈ T (M). Thus b ∈ T (M) since T (M) is a k-subsemimodule of M which is a contradiction. Thus Tor(Γ(M)) is disjoint from Tof(Γ(M)). (ii) Assume that T (M) is not a k-subsemimodule of M . So there exist a ∈ T (M) and b ∈ Tof(M) such that a + b ∈ T (M). Let x ∈ M . We define the subset PT (x) as follows: PT (x) = {m ∈ T (M) : there is a path of finite length between x and m}. Clearly, if x ∈ T (M), then T (M) ⊆ PT (x), and so PT (x) 6= ∅. Set N = {x ∈ M : PT (x) 6= ∅}. Therefore T (M) ⊂ N , since b ∈ N and b /∈ T (M). Now, we show that N is a subsemimodule of M . Let x1, y1 ∈ N . Therefore, there exist m1, m′ 1 ∈ T (M), x1, x2, · · · , xn ∈ M and y1, y2, · · · , yk ∈ M such that x1−x2−· · ·−xn−m1 and y1−y2−· · ·−yk−m′ 1 are paths of finite lengths between x1, m1 and y1, m′ 1, and so we have xi+xi+1, yj +yj+1, xn+ 8 The total torsion element graph of semimodules m1, yk + m′ 1, m1 + m′ 1 ∈ T (M) for each 1 ≤ i ≤ n − 1 and 1 ≤ j ≤ k − 1. We may assume that n ≤ k. So (xi + yi) + (xi+1 + yi+1) ∈ T (M) for each 1 ≤ i ≤ n − 1 and 1 ≤ j ≤ k − 1. Then (x1 + y1) − (x2 + y2) − · · · − (xn + yn)− (m1 + yn+1) − (m′ 1 + yn+2) − (m1 + yn+3) − · · · − m1 is a path of finite length between x1 + y1 and m1. Hence PT (x1 + y1) 6= ∅, and so x1 +y1 ∈ N . Now, let r ∈ R. Therefore, rx1 −rx2 −· · ·−rxn −rm1 is a path between rx1 and rm1 of finite length, and so PT (rx) 6= ∅. Thus N is a subsemimodule of M and T (M) ⊂ N . It is easy to see that T (Γ(N)) is a connected subgraph of T (Γ(M)) containing Tor(Γ(M)). Hence, Tor(Γ(M)) is not disjiont from Tof(Γ(M)). Compare the next theorem with [12, Theorem 2.5]. Theorem 3.10. Let M be a semimodule over a commutative semiring R, |T (M)| = α and |QM − T (M)| = β. (i) If T (M) is a k-subsemimodule of M and 2 ∈ Z(R), then Tof(Γ(M)) is the union of disjoint complete subgraphs. (ii) If T (M) is a k-subsemimodule of M and 2 /∈ Z(R), then Tof(Γ(M)) is the union of totally disconnected subgraphs and some connected sub- graphs. (iii) If T (M) is a QM -subsemimodule of M and 2 ∈ Z(R), then Tof(Γ(M)) is the union of β disjoint Kλ’s such that λ ≤ α. (iv) If T (M) is a QM -subsemimodule of M and 2 /∈ Z(R), then Tof(Γ(M)) is the union of totally disconnected subgraphs and complete bipartite subgraphs. Proof. (i) Let 2 ∈ Z(R). We set up an equivalence relation ∼ on Tof(M) as follows: for y, y′ ∈ Tof(M), we write y ∼ y′ if and only if y + y′ ∈ T (M). By Proposition 3.2 and T (M) being a k-subsemimodule of M , it is straightforward to check that ∼ is an equivalence relation on Tof(M): for y ∈ Tof(M), we denote the equivalence class which contains y by [y]. Now let y ∈ Tof(M). If [y] = {y}, then (y + a) + (y + b) = 2y + (a + b) ∈ T (M) for every a, b ∈ T (M) by Proposition 3.2. So y + T (M) is a complete subgraph with at most α vertices. If |[y]| = γ > 1, then for every y′ ∈ [y] we have (y + a) + (y′ + b) = (y + y′) + a + b ∈ T (M), where a, b ∈ T (M). Thus y + T (M) is a part of a complete graph Kν with ν ≤ αγ vertices. Therefore, Tof(Γ(M)) is the union of disjoint complete subgraphs. S. Ebrahimi Atani, F. Esmaeili Khalil Saraei 9 (ii) Let 2 /∈ Z(R) and y ∈ Tof(M). Set Ay = {y′ ∈ Tof(M) : y + y′ ∈ T (M)}. If Ay = ∅, then y + y′ /∈ T (M) for every y′ ∈ Tof(M). In this case, we show that y + T (M) is a totally disconnected subgraph of Tof(Γ(M)). If (y + a) + (y + b) ∈ T (M) for some a, b ∈ T (M), then 2y + a + b = (y + a) + (y + b) ∈ T (M); so 2y ∈ T (M), which is a contradiction by Proposition 3.2. Therefore, y+T (M) is a totally disconnected subgraph of Tof(Γ(M)). We may assume that Ay 6= ∅. Then y + y′ ∈ T (M) for some y′ ∈ Tof(M). Thus (y +a)+(y′ + b) = (y +y′)+(a+ b) ∈ T (M) for every a, b ∈ T (M); hence each element of y+T (M) is adjacent to each element of y′ + T (M). If |Ay| = ν, then we have a connected subgraph of Tof(Γ(M)) with at most αν vertices. Hence, If 2 /∈ Z(R), then Tof(Γ(M)) is the union of totally disconnected subgraphs and some connected subgraphs. (iii) First, we show that q+T (M) ⊆ Tof(M) for every q ∈ QM −T (M). If q + a /∈ Tof(M) for some a ∈ T (M), then q + a ∈ T (M); hence q ∈ T (M) since T (M) is a k-subsemimodule which is a contradiction. Let 2 ∈ Z(R) and q ∈ QM − T (M). Then each coset q + T (M) is a complete subgraph of Tof(M) with λ vertices such that λ ≤ α (note that (q1+T (M))∩(q2+T (M)) 6= ∅ if and only if q1 = q2) since (q+a)+(q+b) = 2q + (a + b) ∈ T (M) for all a, b ∈ T (M) by Proposition 3.2 and T (M) is a subsemimodule. Now we show that distinct cosets form disjoint subgraphs of Tof(Γ(M)). If q1 + a and q2 + b are adjacent for some q1, q2 ∈ QM − T (M) and a, b ∈ T (M), then (q1 + a) + (q2 + b) ∈ T (M) gives q1+q2 ∈ T (M) since T (M) is a k-subsemimodule of M . So q2+2q1 = q1 +(q1 + q2) ∈ q1 +T (M). Likewise, q2 +2q1 ∈ q2 +T (M) by Proposition 3.2. So q2 + 2q1 ∈ (q1 + T (M)) ∩ (q2 + T (M)); hence q1 = q2. Thus Tof(Γ(M)) is the union of β disjoint induced subgraphs q + T (M), each of which is a Kλ such that λ ≤ α. (iv) Next assume that 2 /∈ Z(R) and let q ∈ QM − T (M). If q + q′ /∈ T (M) for every q′ ∈ QM − T (M), then Aq = ∅. Then by (ii), q + T (M) is a totally disconnected subgraph of Tof(Γ(M)). So we may assume that q + q′ ∈ T (M) for some q′ ∈ QM − T (M). Then by (ii) each element of q + T (M) is adjacent to each element of q′ + T (M); we show that q′ is the unique element. Let q + q′′ ∈ T (M) for some q′′ ∈ QM − T (M). Therefore, q + q′ + q′′ = q′ + (q + q′′) ∈ q′ + T (M). Likewise, q + q′ + q′′ = q′′+(q+q′) ∈ q′′+T (M). Thus (q′+T (M))∩(q′′+T (M)) 6= ∅ gives q′ = q′′. Therefore (q + T (M)) ∪ (q′ + T (M)) is a complete bipartite subgraph of Tof(Γ(M)). So Tof(Γ(M)) is the union of totally disconnected subgraphs and complete bipartite subgraphs. 10 The total torsion element graph of semimodules Proposition 3.11. Let M be a semimodule over a commutative semir- ing R. (i) If T (M) is a k-subsemimodule of M and Tof(Γ(M)) is complete, then |Tof(M)| = 1 or |Tof(M)| = 2. (ii) If T (M) is a QM -subsemimodule of M and Tof(Γ(M)) is complete, then |M/T (M)| = 2 or |M/T (M)| = 3. (iii) If T (M) is a QM -subsemimodule of M , |M/T (M)| = 2 and 2 ∈ Z(R), then Tof(Γ(M)) is complete. Proof. (i) By Proposition 3.2, 2y ∈ T (M) for every y ∈ Tof(M). Then y + T (M) is a complete subgraph of Tof(Γ(M)); hence |Tof(M)| = 1 since Tof(Γ(M)) is complete. If 2 /∈ Z(R), then for each y ∈ Tof(M), there exists y′ ∈ Tof(M) such that y + y′ ∈ T (M). So |Tof(M)| = 2 since Tof(Γ(M)) is complete. In this case, Tof(Γ(M)) is a complete bipartite graph (see Theorem 3.10). (ii) Since every QM -subsemimodule is a k-subsemimodule, the part (i) gives |Tof(M)| = 1 or |Tof(M)| = 2. If |Tof(M)| = 1, then M = T (M) ∪ (q + T (M)) for q ∈ Tof(M) and hence |M/T (M)| = 2. SimilarIy, if |Tof(M)| = 2, then M = T (M) ∪ (q + T (M)) ∪ (q′ + T (M)) for q, q′ ∈ Tof(M) with q 6= q′, and hence |M/T (M)| = 3. (iii) Let |M/T (M)| = 2 and 2 ∈ Z(R). Then M = T (M)∪ (q +T (M)) for some q ∈ QM − T (M); so 2q ∈ T (M) by Proposition 3.2. Let m, m′ ∈ Tof(M). Then m, m′ ∈ q + T (M). So m + m′ = (q + a) + (q + b) = 2q + (a + b) ∈ T (M) for some a, b ∈ T (M). Thus Tof(Γ(M)) is complete. Proposition 3.12. Let M be a semimodule over a commutative semiring R such that T (M) is a QM -subsemimodule of M . Then: (i) If Tof(Γ(M)) is connected, then |M/T (M)| = 2 or |M/T (M)| = 3. (ii) If |M/T (M)| = 2 and 2 ∈ Z(R), then Tof(Γ(M)) is connected. Proof. (i) Let Tof(Γ(M)) be a connected graph. Then Tof(Γ(M)) is a single complete graph Kλ or a bipartite graph by Theorem 3.10. Hence Tof(Γ(M)) is a complete graph. Now the assertion follows from Proposi- tion 3.11. (ii) This follows directly from Proposition 3.11. Theorem 3.13. Let M be a semimodule over a commutative semiring R. (i) If T (M) is a k-subsemimodule of M , then diam(Tof(Γ(M))) = 0 if and only if T (M) = {0} and |M | = 2. (ii) Let T (M) be a QM -subsemimodule of M . Then the following hold: S. Ebrahimi Atani, F. Esmaeili Khalil Saraei 11 (a) diam(Tof(Γ(M))) = 1 if and only if 2 ∈ Z(R) and |M/T (M)| = 2. (b) diam(Tof(Γ(M))) = 2 if and only if |M/T (M)| = 3, 2 /∈ Z(R) and q + q′ ∈ T (M) for every q, q′ ∈ QM − T (M). (c) Otherwise diam(Tof(Γ(M))) = ∞. Proof. (i) If diam(Tof(Γ(M))) = 0, then Tof(Γ(M)) is a complete graph K1, and so |T (M)| = |Tof(M)| = 1 by Theorem 3.10. Hence T (M) = {0} and |M | = 2. The other implication is clear. (ii) (a) If diam(Tof(Γ(M))) = 1, then Tof(Γ(M)) is a complete graph Kλ with λ ≤ |T (M)| by Theorem 3.10. Therefore, 2 ∈ Z(R) and |QM −T (M)| = 1. Thus M = T (M)∪(q+T (M)) for some q ∈ QM −T (M); hence |M/T (M)| = 2. The converse follows from Theorem 3.10. (ii) (b) If diam(Tof(Γ(M))) = 2, then Tof(Γ(M)) is a complete bipartite graph K1,2 or K2,2; thus 2 /∈ Z(R) and |QM − T (M)| = 2 by Theorem 3.10. Since Tof(Γ(M)) has not any totally disconnected subgraph, we must have q + q′ ∈ T (M) for every q, q′ ∈ QM − T (M). Remark 3.14. Let R and M be as described in Example 3.7. So T (M) = {0, 2, 4, 6, · · · } is a k-subsemimodule of M but is not a Q-subsemimodule of M . Also, Tor(Γ(M)) is a complete graph and Tof(Γ(M)) is a totally disconnected graph. Since gcd(2, 4) = 2, we have 2∗4 = 0; hence 2 ∈ Z(R). Moreover, M = T (M) ∪ (1 + T (M)) and diam(Tof(Γ(M))) = ∞. Hence Theorem 3.13 (ii) is not true when T (M) is not a QM -subsemimodule of M . Proposition 3.15. Let M be a semimodule over a commutative semir- ing R such that T (M) is a k-subsemimodule of M . Then gr(Tof(Γ(M))) = 3, 4 or ∞. In particular, if Tof(Γ(M)) contains a cycle, gr(Tof(Γ(M))) ≤ 4. Proof. Let Tof(Γ(M)) contains a cycle. Then Tof(Γ(M)) is not a totally disconnected graph, so by the proof of Theorem 3.10, Tof(Γ(M)) has either a complete or a complete bipartite subgraph. Therefore, it must contain either a 3-cycle or a 4-cycle. Thus gr(Tof(Γ(M))) ≤ 4. Theorem 3.16. Let M be a semimodule over a commutative semiring R such that T (M) be a k-subsemimodule of M . (i) gr(Tof(Γ(M))) = 3 if and only if 2 ∈ Z(R) and |y + T (M)| ≥ 3 for some y ∈ Tof(M). (ii) gr(Tof(Γ(M))) = 4 if and only if 2 /∈ Z(R) and y + y′ ∈ T (M) for some y, y′ ∈ Tof(M). 12 The total torsion element graph of semimodules Proof. (i) Assume that gr(Tof(Γ(M))) = 3. Then by Theorem 3.10, Tof(Γ(M)) is a complete graph Kλ with 3 ≤ λ. Therefore, 2 ∈ Z(R) and |y + T (M)| ≥ 3 for some y ∈ Tof(M). (ii) If gr(Tof(Γ(M))) = 4, then by Theorem 3.10, Tof(Γ(M)) has a complete bipartite subgraph; hence 2 /∈ Z(R) and y + y′ ∈ T (M) for some y, y′ ∈ Tof(M) by Theorem 3.10. The other implications of (i) and (ii) follows directly from Theorem 3.10. Theorem 3.17. Let M be a semimodule over a commutative semiring R such that T (M) be a k-subsemimodule of M . (i) gr(T (Γ(M))) = 3 if and only if |T (M)| ≥ 3. (ii) gr(T (Γ(M))) = 4 if and only if 2 /∈ Z(R), |T (M)| < 3 and y + y′ ∈ T (M) for some y, y′ ∈ Tof(M). (iii) Otherwise, gr(T (Γ(M))) = ∞. Proof. (i) This follows from Proposition 3.5. (ii) Since gr(Tor(Γ(M)) = 3 or ∞, then gr(Tof(Γ(M))) = 4. There- fore, 2 /∈ Z(R) and y + y′ ∈ T (M) for some y, y′ ∈ Tof(M) by Theorem 3.16. On the other hand, gr(T (Γ(M)) 6= 3; so |T (M)| < 3. The converse implication follows from Theorem 3.10. 4. T (M) is not a subsemimodule of M We continue to use the notation already established, so M is a semi- module over a commutative semiring R. In this section , we study the torsion element graph T (Γ(M)) when T (M) is not a subsemimodule of M . Lemma 4.1. Let M be a semimodule over a semiring R such that T (M) is not a subsemimodule of M . Then there are distinct m, m′ ∈ T (M)∗ such that m + m′ ∈ Tof(M). Proof. It is enough to show that T (M) is always closed under scalar multiplication of its elements by elements of R. Let m ∈ T (M) and r ∈ R. There is a non-zero element s ∈ R with sm = 0; hence s(rm)) = r(sm) = 0. Thus rm ∈ T (M). This completes the proof. Theorem 4.2. Let M be a semimodule over a semiring R such that T (M) is not a subsemimodule of M . Then Tor(Γ(M)) is connected with diam(Tor(Γ(M))) = 2. Proof. Let x ∈ T (M)∗. Then x is adjacent to 0. Thus x − 0 − y is a path in Tor(Γ(M)) of length two between any two distinct x, y ∈ T (M)∗. S. Ebrahimi Atani, F. Esmaeili Khalil Saraei 13 Moreover, there exist nonadjacent x, y ∈ T (M)∗ by Lemma 4.1; thus diam(Tor(Γ(M))) = 2. Example 4.3. Let R = {0, 1, a} be the idempotent semiring in which 1 + a = a + 1 = a and let M = R ⊕ R. Then M is a semimod- ule over R with 9 elements. An inspection will show that T (M) = {(0, 0), (1, 0), (0, 1), (a, 0), (0, a)} is not a subsemimodule of M and M = 〈T (M)〉. Moreover, Tor(Γ(M)) is disjoint from Tof(Γ(M)) and Tof(Γ(M)) is a totally disconnected subgraph of T (Γ(M)). Hence T (Γ(M)) is dis- connected. So Theorem 3.1 (ii), (iii) and Theorem 3.2 in [12], in general, are not true when M is a semimodule over a semiring R. Definition 4.4. A semimodule M over a semiring R is called a subtractive semimodule if every cyclic subsemimodule of M is a k-subsemimodule. Example 4.5. Assume that E+ be the set of all non-negative integers and let M = R = E+ ∪{∞}. Define a+b = max{a, b} and ab = min{a, b} for all a, b ∈ R. Then R is a commutative semiring with 1R = ∞ and 0R = 0. An inspection will show that the list of subsemimodules of M are: M , E+ and for every non-negative integer n Nn = {0, 1, ..., n}. It is clear that every proper subsemimodule of M is a k-subsemimodule. So M is a subtractive semimodule. Lemma 4.6. Let R be a semiring which is not a ring, and let M be a subtractive R-semimodule. Then S(M) ⊆ T (M). Proof. If S(M) = {0}, we are done. Suppose that 0 6= x ∈ S(M). Then there is a y ∈ S(M) such that x + y = 0. Thus y ∈ Rx since Rx is a k-subsemimodule. Then there exists r ∈ R such that (1 + r)x = 0. It then follows from [11, Lemma 2.1] that 1 + r 6= 0. Thus x ∈ T (M), as required. Theorem 4.7. Let R be a semiring which is not a ring, and let M be a subtractive R-semimodule. If |S(M)| ≥ 3, then gr(Tor(Γ(M))) = 3. Proof. Let 0 6= x, y ∈ S(M). Then x, y ∈ T (M) by Lemma 4.6 and x + y = 0 ∈ T (M). Thus 0 − x − y − 0 is a 3-cycle in Tor(Γ(M)). Theorem 4.8. Let M be a semimodule over a commutative semiring R such that T (M) is not a subsemimodule of M . (i) If T (Γ(R)) is connected, then T (Γ(M)) is connected. (ii) Either gr(Tor(Γ(M))) = 3 or gr(Tor(Γ(M))) = ∞. 14 The total torsion element graph of semimodules Proof. (i) It is clear that if r ∈ Z(R) and x ∈ M , then rx ∈ T (M). Assume that y ∈ M and let 0 − a1 − a2 − · · · − ak − 1 be a path from 0 to 1 in T (Γ(R)). Then 0 − a1y − a2y − · · · − aky − y is a path from 0 to y in T (Γ(M)). Since all vertices may be connected via 0, T (Γ(M)) is connected. (ii) If x + y ∈ T (M) for some distinct x, y ∈ T (M)∗, then 0 − x − y − 0 is a 3-cycle in Tor(Γ(M)); so gr(Tor(Γ(M))) = 3. Otherwise, x + y ∈ Tof(M) for all distinct x, y ∈ T (M) by Lemma 4.1. Therefore, in this case, each x ∈ T (M)∗ is adjacent to 0, and no two distinct x, y ∈ T (M)∗ are adjacent. Thus Tor(Γ(M)) is a star graph with center 0; hence gr(Tor(Γ(M))) = ∞. Lemma 4.9. Let M be a semimodule over a commutative semiring R such that T (M) is not a subsemimodule of M . Then |Z(R)| ≥ 3. Proof. By Lemma 4.1, there are distinct x, y ∈ T (M) such that x + y ∈ Tof(M). Thus there exist 0 6= r, s ∈ R such that rx = sy = 0. Since rs(x + y) = 0 and x + y /∈ T (M), we have rs = 0, as needed. Theorem 4.10. Let M be a semimodule over a commutative semiring R such that T (M) is not a subsemimodule of M . (i) If Z(R) is an ideal of R, then gr(Tor(Γ(M))) = 3 (ii) If Z(R) is not an ideal of R, then gr(Tof(Γ(M))) = 3 or ∞. Proof. (i) Let Z(R) is an ideal of R. By Lemma 4.9, there are non- zero elements r, s of Z(R) with r + s ∈ Z(R) and rs = 0. Therefore, t(r + s) = 0 for some non-zero element t of R. Now let m, m′ ∈ Tof(M). Since t(r + s)m = t(r + s)m′ = 0, we have rm + sm, rm′ + sm′ ∈ T (M). On the other hand, rm + rm′, sm + sm′ ∈ T (M) since s(rm + rm′) = r(sm+sm′) = 0. Hence rm−rm′−sm′−sm−rm is a 4-cycle in T (Γ(M)). Then gr(Tor(Γ(M))) = 3 by Theorem 4.8 (ii). (ii) We may assume that Tof(Γ(M)) contains a cycle. So there is a path x − y − z in Tof(M). If x + z ∈ T (M), then we have a 3-cycle in Tof(Γ(M)). So we may assume that x + z /∈ T (M). There exist r1, r2 ∈ Z(R) such that r1 +r2 /∈ Z(R) since Z(R) is not an ideal of R. So there are 0 6= t1, t2 ∈ R such that r1t1 = r2t2 = 0 and then t1t2 = 0 since t1t2(r1 + r2) = 0. Therefore t1x + t1z ∈ T (M) since t2(t1x + t1z) = 0. Thus t1x − t1y − t1z − t1x is a 3-cycle in Tof(Γ(M)) and the proof is complete. S. Ebrahimi Atani, F. Esmaeili Khalil Saraei 15 References [1] D. D. Anderson and M. Naseer, Beck’s coloring of a commutative ring, J. Algebra 159 (1993), 500-514. [2] D. F. Anderson and A. Badawi, The total graph of a commutative ring, J. Algebra 320 (2008), 2706-2719. [3] D. F. Anderson and P. F. Livingston, The zero-divisor graph of a commutative ring, J. Algebra 217 (1999), 437-447. [4] D. F. Anderson, M. C. Axtell, and J. A. Stickles, Zero-divisor graphs in commuta- tive rings, in Commutative Algebra, Noetherian and non-Noetherian Perspectives (M. Fontana, S. E. Kabbaj, B. Olberding, I. Swanson, Eds), Springer-Verlag, New York, 2011, 23-45. [5] P. J. Allen, A fundamental theorem of homomorphisms for semirings, Proc. Amer. Math. Soc. 21 (1969), 412-416. [6] I. Beck, Coloring of a commutative ring, J. Algebra 116 (1988), 208-226. [7] J. N. Chaudhari and D. R. Bonde, On partitioning and subtractive subsemimodules of semimodules over semirings, Kyungpook Math. J. 50 (2010), 329-336. [8] R. Ebrahimi Atani and S. Ebrahimi Atani, On subsemimodules of semimodules, Bul. Acad. Stiinte Repub. Mold. Mat. 2 (63) (2010), 20-30. [9] S. Ebrahimi Atani, The zero-divisor graph with respect to ideals of a commutative semiring, Glasnik Math. 43 (2008), 309-320. [10] S. Ebrahimi Atani, An ideal-based zero-divisor graph of a commutative semiring, Glasnik Math. 44 (1) (2009), 141-153. [11] S. Ebrahimi Atani and R. Ebrahimi Atani, Some remarks on partitioning semirings, An. St. Univ. Ovidius Constanta 18(1) (2010), 49-62. [12] S. Ebrahimi Atani and S. Habibi, The total torsion element graph of a module over a commutative ring, An. St. Univ. Ovidius Constanta 19(1) (2011), 23-34. [13] J. S. Golan, The theory of semirings with applications in mathematics and theo- retical computer science, Pitman Monographs and Surveys in Pure and Applied Mathematics, Longman Scientific and Technical, Harlow UK, (1992). [14] J. S. Golan, Semirings and their Applications, Kluwer Academic Publishers, Dor- drecht, (1999). [15] S. B. Mulay, Cycles and symmetries of zero-divisors, Comm. Algebra 30(7) (2002), 3533-3558. Contact information S. Ebrahimi Atani, F. Esmaeili Khalil Saraei Faculty of Mathematical Sciences, University of Guilan, P.O. Box 1914, Rasht, Iran E-Mail: ebrahimiatani@gmail.com Received by the editors: 01.09.2011 and in final form 26.04.2012.

Similar Items