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Some Serial Rings and Modules 1 Introduction 2 Preliminaries

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Some Serial Rings and Modules 1 Introduction 2 Preliminaries International Journal of Algebra, Vol. 6, 2012, no. 2, 81 - 84 Some Serial Rings and Modules Supunnee Sompong Department of Mathematics and Statistics Faculty of Science and Technology Sakon Nakhon Rajabhat University Sakon Nakhon 47000, Thailand s [email protected] Abstract The purpose of this paper is to show the properties of serial Artinian right R−module M, which is a projective generator in σ[M]. Keywords: Serial Module, Artinian Module, Quasi-projective Module 1 Introduction Throughout this paper, R is an associative ring with identity. Mod-R is the category of unitary right R-modules and the notations MR or M will be a unitary right R-module. The aim of this paper to give some properties that can imply the right R-module M to be serial. In general, we known that every epimorphic image of a serial module needs not to be serial, in this paper we gave some conditions for an epimorphic image of serial module to be serial. Next we was shown the properties of serial Artinian right R−module M, which is a projective generator in σ[M]. As a corollary we can get some results of serial Artinian ring R. 2 Preliminaries Throughout this paper, R is an associative ring with identity. Mod-R is the category of unitary right R-modules and the notations MR or M will be a unitary right R-module. A right R-module P is called M-generated if there exists an epimorphism M (I) −→ P for some index set I. P is called finitely M-generated if I is finite. We denote σ[M], a full subcategory of Mod-R, whose objects are submodules of M-generated modules. M is a generator of σ[M] if it generates all N ∈ σ[M], and a self-generator if it generates all its submodules. 82 S. Sompong A right R-module M is called uniserial if its submodules are linearly ordered by inclusion, i.e., for any submodules A and B of M, either A ⊆ B or B ⊆ A. A ring R is right uniserial if it is uniserial as a right R-module. A right R- module M is called a serial module if it is a direct sum of uniserial modules. A ring R is right serial if it is serial as a right R-module and R is serial if R is left and right serial. A right R-module M is called indecomposable if M = 0 and it cannot be written as a direct sum of a non-zero submodules. A right R-module P is said to be M-projective if for every epimorphism β : M → N and every homomorphism ϕ : P → N, there exists a homomorphism ϕ : P → M such that βϕ = ϕ. If P is P -projective, then P is called quasi-projective. A right R-module X is called an injective right R-module if for any monomor- phism α : A → B of right R-modules and any homomorphism ϕ : A → X, we can find a homomorphism ϕ : B → X such that ϕ ◦ α = ϕ. A right R-module X is called quasi-injective if it is X-injective. A ring R is called right self-injective if RR is R-injective. 3 Serial Rings and Modules Now we will give a results of serial rings and modules. Lemma 3.1. ([4], page 294) Let M be a right R-module and E(M), its injec- tive hull. Then, M is uniform if and only if E(M) is indecomposable. Lemma 3.2. ([5], Theorem 2.17) Let M be a right R-module. Then, M is uniserial if and only if every factor module of M is uniform. The following Theorem gives some properties that can imply M to be serial. Theorem 3.3. Let M be an Artinian right R-module which is a projective generator in σ[M]. If every factor module of local in σ[M] is quasi-injective, then M is serial. n Proof. Since M is projective in σ[M] and Artinian, we have M = Mi, where i=1 each Mi is a local module. By assumption, every factor module of Mi is quasi- injective. Then we can see that every factor module of Mi is uniform. That is each Mi is uniserial, proving that M is serial. In general, it is well-known that every epimorphic image of a serial module needs not to be serial. The following Theorem gives some conditions for an epimorphic image of serial module to be serial. Some serial rings and modules 83 Theorem 3.4. Let M be an Artinian right R-module which is a projective generator in σ[M], N ∈ σ[M] and f ∈ HomR(M,N).IfM is serial and every indecomposable quasi-injective module in σ[M] is uniserial, then f(M) is serial. Proof. Since M is Artinian projective generator in σ[M],Mhas finite length. n By the property of serial modules, we have M = Mi, where each Mi is i=1 uniserial. It follows that each Mi is cyclic and therefore f(Mi) is cyclic and n n uniserial. From f(M)=f( Mi)= f(Mi) and the fact that the injective i=1 i=1 n hull of f(Mi) is uniserial, by ([8],Theorem 55.9]), we can see that f(Mi)is i=1 a serial module. Therefore f(M) is serial. Theorem 3.5. Let M be an Artinian right R-module which is a projective generator in σ[M]. Then the following statements are equivalent: (1) M is serial and every indecomposable quasi-injective module in σ[M] is uniserial; (2) Every finitely generated module in σ[M] is serial; (3) Every module in σ[M] is serial; (4) Every finitely generated indecomposable module in σ[M] is uniserial. Proof. Since M is an Artinian projective generator in σ[M],Mhas finite length. (1) ⇒ (2) Since M is a generator in σ[M], every finitely generated module in σ[M] is finitely M-generated. By Theorem 2.4, we have that every finitely generated module in σ[M] is serial. (2) ⇒ (3) Since M is of finite length and our assumption, we have every module in σ[M] is serial. (3) ⇒ (4) (4) is a special case of (3). n (4)⇒ (1) Since M is projective and Artinian, M = Mi, where each Mi is i=1 local module. Thus Mi is indecomposable and finitely generated. It follows that each Mi is uniserial, proving that M is serial. From M has finite length, [8] and our assumption, we have every indecomposable quasi-injective module in σ[M] is uniserial. From the preceding theorems, we have the following result for a ring R. 84 S. Sompong Corollary 3.6. Let R be an Artinian right R-module. Then the following statements are equivalent: (1) R is serial and every indecomposable quasi-injective right R-module is uniserial; (2) Every finitely generated right R-module is serial; (3) Every right R-module is serial; (4) Every finitely generated indecomposable right R-module is uniserial. References [1] B. Stenstr¨om, "Rings of quotients", Springer Verlag, Berlin-Heidelberg- New York, 1975. [2] C. Faith, "Algebra : Rings, Modules and Categories I", Springer Grundl, 1973, 190. [3] C. Faith, "Algebra : Rings, Modules and Categories II", Springer Grundl, 1976, 191. [4] F.W. Anderson , K.R. Fuller, "Rings and Categories of Modules", Gradu- ate Texts in Mathematics, No.13, Springer-Verlag, New York-Heidelberg- Berlin, 1974. [5] J. Clark , Ch. Lomp , Na. Vanaja , R. Wisbauer, "Lifting Modules supple- mentes and Projectivity in Module Theory", Basel-Boston-Berlin, 2006. [6] K.R. Fuller, On indecomposable injectives over Artinian rings, Pacific J. of Math., Vol 29, No. 1(1969), 115 - 135. [7] N.V. Dung , D.V. Huynh , F. Smith Patrick, R. Wisbauer, "Extending Modules", 1996. [8] R. Wisbauer, "Foundations of Module and Ring Theory", Gordon and Breach, Tokyo, e.a., 1991. Received: August, 2011.
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