DOCSLIB.ORG

5 Dedekind Extensions

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
5 Dedekind Extensions 18.785 Number theory I Fall 2017 Lecture #5 09/20/2017 5 Dedekind extensions In this lecture we prove that the integral closure of a Dedekind domain in a finite extension of its fraction field is also a Dedekind domain; this implies, in particular, that the ring of integers of a number field is a Dedekind domain. We then consider the factorization of prime ideals in Dedekind extensions. 5.1 Dual modules, pairings, and lattices In this section we work in a more general setting, where A is any commutative (unital) ring. Definition 5.1. Let A be a commutative ring and M an A-module. The dual module M _ is the A-module HomA(M; A) with scalar multiplication (af)(m) = af(m), where a 2 A, f 2 HomA(M; A), and m 2 M. If ': M ! N is an A-module homomorphism, the dual homomorphism '_ : N _ ! M _ is defined by '_(g)(m) = g('(m)), for g 2 N _ and m 2 M. It is easy to check that taking duals preserves identity maps and is compatible with composition: if '1 : M ! N and '2 : N ! P are A-module homomorphisms, then _ _ _ ('2'1) = '1 '2 . We thus have a contravariant functor from the category of A-modules to itself. This functor is compatible with (finite) direct sums, (M ⊕ N)_ ' M _ ⊕ N _. Lemma 5.2. Let A be a commutative ring. For all A-modules M and N the A-modules (M ⊕ N)_ and M _ ⊕ N _ are canonically isomorphic. Proof. We have inverse A-module homomorphisms ' 7! (m 7! '(m; 0); n 7! '(0; n)) and (φ, ) 7! ((m; n) 7! φ(m) + (n)). We have already seen some examples of dual modules: each invertible fractional ideal is isomorphic to the dual of its inverse. Proposition 5.3. Let A be an integral domain with fraction field K and let M be a nonzero A-submodule of K. Then M _ ' (A : M) := fx 2 K : xM ⊆ Ag; in particular, if M is an invertible fractional ideal then M _ ' M −1 and M __ ' M. Proof. For any x 2 (A : M) the map m 7! xm is an A-linear map from M to A, hence an element of M _, and this defines an A-module homomorphism ':(A : M) ! M _, since the map x 7! (m 7! xm) is itself A-linear. Since M ⊆ K is a nonzero A-module, it contains some nonzero a 2 A (if a=b 2 M, so is ba=b = a). If f 2 M _ and m = b=c 2 M then b ac b b ac b f(a) f(m) = f = f = f = f(a) = m; c ac c ac c ac a where we have used the fact that a1f(a2=a3) = a2f(a1=a3) for any a1; a2; a3 2 A with a1=a3; a2=a3 2 M, by the A-linearity of f. It follows that f corresponds to multiplication by x = f(a)=a, which lies in (A : M) since xm = f(m) 2 A for all m 2 M. The map f 7! f(a)=a defines an A-module homomorphism M _ ! (A : M) inverse to ', so ' is an isomorphism. When M is an invertible fractional ideal we have M _ ' (A : M) = M −1, by Lemma 3.2, and M __ ' (M −1)−1 = M follows. If A is a field, then M is a vector space, M _ is its dual space and we have M __ ' M, as in the proposition above. But in general not every A-module is isomorphic to its double dual; those that are are said to be reflexive. Andrew V. Sutherland _ Example 5.4. As a Z-module, we have Q = f0g because there are no non-trivial Z-linear homomorphisms from Q to Z; indeed, Q is a divisible group and Z contains no non-trivial __ _ __ divisible subgroups. It follows that Q = f0g (but as Q-modules we have Q ' Q ' Q ). Similarly, the dual of any finite Z-module (any finite abelian group) is the zero module, as is the double dual. More generally, if A is an integral domain every dual (and double dual) A-module must be torsion free, but not all A-modules are torsion free. One situation where we can recover many of the standard results that hold for vector spaces of finite dimension (with essentially the same proofs), is when M is a free module of finite rank. In particular, not only is M reflexive, we have M ' M _ (non-canonically) and may explicitly construct a dual basis. Theorem 5.5. Let A be a commutative ring and let M be a free A-module of rank n. Then _ M is also a free A-module of rank n, and each basis (e1; : : : ; en) of M uniquely determines _ _ _ a dual basis (e1 ; : : : en) of M with the property ( _ 1 i = j; e (ej) = δij := i 0 i 6= j: Proof. If n = 0 then M = M _ = f0g and the theorem holds. Now assume n ≥ 1 and fix an n _ A-basis e := (e1; : : : ; en) for M. For each a := (a1; : : : ; an) 2 A , define fa 2 M by setting fa(ei) = ai and extending A-linearly. The map a 7! fa gives an A-module homomorphism n _ A ! M with inverse f 7! (f(e1); : : : ; f(en)) and is therefore an isomorphism. It follows that M _ ' An is a free A-module of rank n. _ n Now let ei := f^ι, where ^ι := (0;:::; 0; 1; 0;:::; 0) 2 A has a 1 in the ith position. Then _ _ _ _ ^ n _ e := (e1 ; : : : ; en) is a basis for M , since (1;:::; n^) is a basis for A , and ei (ej) = δij. The basis e_ is uniquely determined by e: it must be the image of (1^;:::; n^) under the isomorphism a 7! fa determined by e. Definition 5.6. Let A be a commutative ring and M an A-module. A (bilinear) pairing on M is an A-linear map h·; ·i: M × M ! A. Explicitly, this means that for all u; v; w 2 M and λ 2 A we have hu + v; wi = hu; wi + hv; wi; hu; v + wi = hu; vi + hu; wi; hλu, vi = hu; λvi = λhu; vi: If hv; wi = hw; vi then h·; ·i is symmetric, if hv; wi = −hw; vi then h·; ·i is skew-symmetric, and if hv; vi = 0 then h·; ·i is alternating (the last two are equivalent provided char(A) 6= 2). The pairing h·; ·i induces an A-module homomorphism ': M ! M _ m 7! (n 7! hm; ni) If ker ' = f0g then h·; ·i is nondegenerate, and if ' is an isomorphism then h·; ·i is perfect. Every perfect pairing is necessarily nondegenerate. If M is a vector space of finite dimension the converse holds, but this is not true in general, not even for free modules of finite rank: consider the pairing hx; yi := 2xy on Z, which is non-degenerate but not perfect. 18.785 Fall 2017, Lecture #5, Page 2 If M is a free A-module with basis (e1; : : : ; en) and h·; ·i is a perfect pairing, we can apply the inverse of the isomorphism ': M −!∼ M _ induced by the pairing to the dual _ _ 0 0 basis (e1 ; : : : ; en) given by Theorem 5.5 to obtain a basis (e1; : : : ; en) for M that satisfies 0 hei; eji = δij: 0 0 When h·; ·i is symmetric we can similarly recover (e1; : : : ; en) from (e1; : : : ; en) in the same way. We record this fact in the following proposition. Proposition 5.7. Let A be a commutative ring and let M be a free A-module of rank n with 0 0 a perfect pairing h·; ·i. For each A-basis (e1; : : : ; en) of M there is a unique basis (e1; : : : ; en) 0 for M such that hei; eji = δij. Proof. Existence follows from the discussion above: apply the inverse of the isomorphism _ _ _ ': V ! V induced by h·; ·i to the dual basis (e1 ; : : : ; en) given by Theorem 5.5 to obtain 0 0 0 −1 _ _ 0 0 a basis (e1; : : : ; en) for M with ei = ' (ei ). We then have ei = '(ei) = m 7! hei; mi and 0 0 _ hei; eji = '(ei)(ej) = ei (ej) = δij 0 0 for 1 ≤ i; j ≤ n. If (f1; : : : ; fn) is another basis for M with the same property then for 0 0 0 0 each i we have hei − fi ; eji = δij − δij = 0 for every ej, and therefore hei − fi ; mi = 0 for 0 0 all m 2 M, but then ei − fi 2 ker ' = f0g, since the perfect pairing h·; ·i is nondegenerate, 0 0 and therefore fi = ei for each i; uniqueness follows. Remark 5.8. In what follows the commutative ring A in Proposition 5.7 will typically be a field K and the free A-module M will be a K-vector space that we will denote V . We may then use A to denote a subring of K and M to denote an A-submodule of V .A perfect paring h·; ·i on the K-vector space V will typically not restrict to a perfect pairing on the A-module M. For example, the perfect pairing hx; yi = xy on Q does not restrict _ to a perfect pairing on the Z-module 2Z because the induced map ': 2Z ! 2Z defined by _ '(m) = (n 7! mn) is not surjective: the map x 7! x=2 lies in 2Z = HomZ(2Z; Z) but it is not in the image of '.
Load more

Recommended publications
  • Dedekind Domains
    Dedekind Domains Mathematics 601 In this note we prove several facts about Dedekind domains that we will use in the course of proving the Riemann-Roch theorem. The main theorem shows that if K=F is a finite extension and A is a Dedekind domain with quotient field F , then the integral closure of A in K is also a Dedekind domain. As we will see in the proof, we need various results from ring theory and field theory. We first recall some basic definitions and facts. A Dedekind domain is an integral domain B for which every nonzero ideal can be written uniquely as a product of prime ideals. Perhaps the main theorem about Dedekind domains is that a domain B is a Dedekind domain if and only if B is Noetherian, integrally closed, and dim(B) = 1. Without fully defining dimension, to say that a ring has dimension 1 says nothing more than nonzero prime ideals are maximal. Moreover, a Noetherian ring B is a Dedekind domain if and only if BM is a discrete valuation ring for every maximal ideal M of B. In particular, a Dedekind domain that is a local ring is a discrete valuation ring, and vice-versa. We start by mentioning two examples of Dedekind domains. Example 1. The ring of integers Z is a Dedekind domain. In fact, any principal ideal domain is a Dedekind domain since a principal ideal domain is Noetherian integrally closed, and nonzero prime ideals are maximal. Alternatively, it is easy to prove that in a principal ideal domain, every nonzero ideal factors uniquely into prime ideals.
    [Show full text]
  • Unique Factorization of Ideals in a Dedekind Domain
    UNIQUE FACTORIZATION OF IDEALS IN A DEDEKIND DOMAIN XINYU LIU Abstract. In abstract algebra, a Dedekind domain is a Noetherian, inte- grally closed integral domain of Krull dimension 1. Parallel to the unique factorization of integers in Z, the ideals in a Dedekind domain can also be written uniquely as the product of prime ideals. Starting from the definitions of groups and rings, we introduce some basic theory in commutative algebra and present a proof for this theorem via Discrete Valuation Ring. First, we prove some intermediate results about the localization of a ring at its maximal ideals. Next, by the fact that the localization of a Dedekind domain at its maximal ideal is a Discrete Valuation Ring, we provide a simple proof for our main theorem. Contents 1. Basic Definitions of Rings 1 2. Localization 4 3. Integral Extension, Discrete Valuation Ring and Dedekind Domain 5 4. Unique Factorization of Ideals in a Dedekind Domain 7 Acknowledgements 12 References 12 1. Basic Definitions of Rings We start with some basic definitions of a ring, which is one of the most important structures in algebra. Definition 1.1. A ring R is a set along with two operations + and · (namely addition and multiplication) such that the following three properties are satisfied: (1) (R; +) is an abelian group. (2) (R; ·) is a monoid. (3) The distributive law: for all a; b; c 2 R, we have (a + b) · c = a · c + b · c, and a · (b + c) = a · b + a · c: Specifically, we use 0 to denote the identity element of the abelian group (R; +) and 1 to denote the identity element of the monoid (R; ·).
    [Show full text]
  • 13. Dedekind Domains 117
    13. Dedekind Domains 117 13. Dedekind Domains In the last chapter we have mainly studied 1-dimensional regular local rings, i. e. geometrically the local properties of smooth points on curves. We now want to patch these local results together to obtain global statements about 1-dimensional rings (resp. curves) that are “locally regular”. The corresponding notion is that of a Dedekind domain. Definition 13.1 (Dedekind domains). An integral domain R is called Dedekind domain if it is Noetherian of dimension 1, and for all maximal ideals P E R the localization RP is a regular local ring. Remark 13.2 (Equivalent conditions for Dedekind domains). As a Dedekind domain R is an integral domain of dimension 1, its prime ideals are exactly the zero ideal and all maximal ideals. So every localization RP for a maximal ideal P is a 1-dimensional local ring. As these localizations are also Noetherian by Exercise 7.23, we can replace the requirement in Definition 13.1 that the local rings RP are regular by any of the equivalent conditions in Proposition 12.14. For example, a Dedekind domain is the same as a 1-dimensional Noetherian domain such that all localizations at maximal ideals are discrete valuation rings. This works particularly well for the normality condition as this is a local property and can thus be transferred to the whole ring: Lemma 13.3. A 1-dimensional Noetherian domain is a Dedekind domain if and only if it is normal. Proof. By Remark 13.2 and Proposition 12.14, a 1-dimensional Noetherian domain R is a Dedekind domain if and only if all localizations RP at a maximal ideal P are normal.
    [Show full text]
  • A Class of Divisible Modules
    Pacific Journal of Mathematics A CLASS OF DIVISIBLE MODULES MARK LAWRENCE TEPLY Vol. 45, No. 2 October 1973 PACIFIC JOURNAL OF MATHEMATICS Vol. 45, No. 2, 1973 A CLASS OF DIVISIBLE MODULES MARK L. TEPLY The ^^divisible jβ-modules are defined in terms of a hereditary torsion theory of modules over an associative ring R with identity element. In the special case where J^~ is the usual torsion class of modules over a commutative in- tegral domain, the class of J^divisible modules is precisely the class of divisible modules M such that every nonzero homomorphic image of M has a nonzero /^-divisible submodule. In general, if J7~ is a stable hereditary torsion class, the class of ^-divisible modules satisfies many of the traditional properties of divisible modules over a commutative integral domain. This is especially true when J^~ is Goldie's torsion class 2^. For suitable ^\ the splitting of all ^divisible modules is equivalent to h.d.Q^- ^ 1, where Q^ is the ring of quotients naturally associated with ^T Generalizations of Dedekind domains are studied in terms of ^^divisibility. 1* Notation, terminology, and preliminary results* In this paper, all rings R are associative rings with identity element, and all modules are unitary left iϋ-modules. B^f denotes the category of all left i?-modules. E(M) denotes the injective envelope of Me R<^fί. In homological expressions, the "R" will be omitted for convenience 1 in printing (e.g. Ext^ = Ext and h.d RQ — h.d. Q). Following S.E. Dickson [4], we call a nonempty subclass J7~ of R^/^ a torsion class if ^ is closed under factors, extensions, and arbitrary direct sums.
    [Show full text]
  • Dedekind Domains and Rings of Quotients
    Pacific Journal of Mathematics DEDEKIND DOMAINS AND RINGS OF QUOTIENTS LUTHER ELIC CLABORN Vol. 15, No. 1 September 1965 PACIFIC JOURNAL OF MATHEMATICS Vol. 15, No. 1. 1965 DEDEKIND DOMAINS AND RINGS OF QUOTIENTS LUTHER CLABORN We study the relation of the ideal class group of a Dedekind domain A to that of As, where S is a multiplicatively closed subset of A. We construct examples of (a) a Dedekind domain with no principal prime ideal and (b) a Dedekind domain which is not the integral closure of a principal ideal domain. We also obtain some qualitative information on the number of non-principal prime ideals in an arbitrary Dedekind domain. If A is a Dadekind domain, S the set of all monic poly- nomials and T the set of all primitive polynomials of A[X], then A[X]<? and A[X]T are both Dadekind domains. We obtain the class groups of these new Dsdekind domains in terms of that of A. 1* LEMMA 1-1. If A is a Dedekind domain and S is a multi- plicatively closed set of A suoh that As is not a field, then As is also a Dedekind domain. Proof. That As is integrally closed and Noetherian if A is, follows from the general theory of quotient ring formations. The primes of As are of the type PAS) where P is a prime ideal of A such that PΓ)S = ψ. Since height PAS = height P if PΠS = φ, P Φ (0) and PΠS = φ imply that height PAS = 1. PROPOSITION 1-2.
    [Show full text]
  • Free Medial Quandles
    Algebra Univers. 78 (2017) 43–54 DOI 10.1007/s00012-017-0443-2 Published online May 23, 2017 © 2017 The Author(s) Algebra Universalis This article is an open access publication Free medial quandles Premyslˇ Jedlicka,ˇ Agata Pilitowska, and Anna Zamojska-Dzienio Abstract. This paper gives the construction of free medial quandles as well as free n-symmetric medial quandles and free m-reductive medial quandles. 1. Introduction A binary algebra (Q, ) is called a rack if the following conditions hold, for · every x, y, z Q: ∈ x(yz)=(xy)(xz) (we say Q is left distributive), • the equation xu = y has a unique solution u Q (we say Q is a left • ∈ quasigroup). An idempotent rack is called a quandle (we say Q is idempotent if xx = x for every x Q). A quandle Q is medial if, for every x, y, u, v Q, ∈ ∈ (xy)(uv)=(xu)(yv). An important example of a medial quandle is an abelian group A with an operation defined by a b = (1 h)(a)+h(b), where h is an automorphism ∗ ∗ − of A. This construction is called an affine quandle (or sometimes an Alexander quandle) and denoted by Aff(A, h). In the literature [6, 7], the group A is 1 usually considered to be a Z[t, t− ]-module, where t a = h(a), for each a A. · ∈ We shall adopt this point of view here as well and we usually write Aff(A, r) instead, where r is a ring element. Note that in universal algebra terminology, an algebra is said to be affine if it is polynomially equivalent to a module.
    [Show full text]
  • Clifford Regular Domains1
    Journal of Algebra 238, 703᎐722Ž. 2001 doi:10.1006rjabr.2000.8670, available online at http:rrwww.idealibrary.com on Clifford Regular Domains1 S. Bazzoni Dipartimento di Matematica Pura e Applicata, Uni¨ersita` di Pado¨a, Via Belzoni 7, View metadata, citation and similar papers at core.ac.uk35131 Pado¨a, Italy brought to you by CORE E-mail: [email protected] provided by Elsevier - Publisher Connector Communicated by Kent R. Fuller Received May 8, 2000 The class semigroup of a commutative integral domain R is the semigroup S Ž.R of the isomorphism classes of the nonzero ideals of R with operation induced by multiplication. A domain R is said to be Clifford regular if S Ž.R is a Clifford semigroup, i.e. S Ž.R is the disjoint union of the subgroups associated to the idempotent elements. In this paper we characterize the noetherian and the integrally closed Clifford regular domains and find some properties of an arbitrary Clifford regular domain. ᮊ 2001 Academic Press Key Words: Clifford semigroup; stable domains; Prufer¨ domains; finite character. INTRODUCTION The notion of the class group of a commutative domain is a classical one and it is one of the major objects of investigation in commutative algebra. The class group CŽ.R of a domain R consists of the isomorphism classes of the invertible ideals of R. We generalize this notion by considering the class semigroup S Ž.R of R consisting of the isomorphism classes of all the nonzero ideals of R. Throughout, R will denote a commutative domain.
    [Show full text]
  • The Lattice of Quasivarietes of Modules Over a Dedekind Ring∗
    “adm-n1” — 2019/3/22 — 12:03 — page 37 — #45 Algebra and Discrete Mathematics RESEARCH ARTICLE Volume 27 (2019). Number 1, pp. 37–49 c Journal “Algebra and Discrete Mathematics” The lattice of quasivarietes of modules over a Dedekind ring∗ Přemysl Jedlička, Katarzyna Matczak, Anna Mućka Communicated by A. I. Kashu Abstract. In 1995 D. V. Belkin described the lattice of qua- sivarieties of modules over principal ideal domains [1]. The following paper provides a description of the lattice of subquasivarieties of the variety of modules over a given Dedekind ring. It also shows which subvarieties of these modules are deductive (a variety is deductive if every subquasivariety is a variety). Introduction There are many algebraic structures that are polynomially equivalent to modules; typical examples are abelian algebras with a Mal’tsev term. However, in most cases these modules are over rings with no interesting algebraic properties. There are exceptions though, for instance finite idempotent entropic quasigroups. Since the work of Toyoda [12], we know that a finite idempotent entropic quasigroup is polynomially equivalent to a module over Z[x]/(xn 1), for some n, and these rings are well described − in commutative algebra; we know, for instance, that they are products of pairwise different Dedekind domains [14]. Since the polynomial equivalence preserves congruences, it is natural to study varieties and quasivarieties in better understood equivalent algebras, ∗ The joint research within the framework of the Polish-Czech cooperation grant no. 7AMB13PL013 and no. 8829/R13/R14. 2010 MSC: 08A62, 08C15, 20N02, 20N05. Key words and phrases: quasivarieties, lattices, modules, Dedekind rings.
    [Show full text]
  • Unique Factorization of Ideals in OK
    IDEAL FACTORIZATION KEITH CONRAD 1. Introduction We will prove here the fundamental theorem of ideal theory in number fields: every nonzero proper ideal in the integers of a number field admits unique factorization into a product of nonzero prime ideals. Then we will explore how far the techniques can be generalized to other domains. Definition 1.1. For ideals a and b in a commutative ring, write a j b if b = ac for an ideal c. Theorem 1.2. For elements α and β in a commutative ring, α j β as elements if and only if (α) j (β) as ideals. Proof. If α j β then β = αγ for some γ in the ring, so (β) = (αγ) = (α)(γ). Thus (α) j (β) as ideals. Conversely, if (α) j (β), write (β) = (α)c for an ideal c. Since (α)c = αc = fαc : c 2 cg and β 2 (β), β = αc for some c 2 c. Thus α j β in the ring. Theorem 1.2 says that passing from elements to the principal ideals they generate does not change divisibility relations. However, irreducibility can change. p Example 1.3. In Z[ −5],p 2 is irreduciblep as an element but the principal ideal (2) factors nontrivially: (2) = (2; 1 + −5)(2; 1 − −p5). p To see that neither of the idealsp (2; 1 + −5) and (2; 1 − −5) is the unit ideal, we give two arguments. Suppose (2; 1 + −5) = (1). Then we can write p p p 1 = 2(a + b −5) + (1 + −5)(c + d −5) for some integers a; b; c, and d.
    [Show full text]
  • Unique Factorization and Class Groups TCU Seminar Lecture Notes
    Unique Factorization and Class Groups TCU Seminar Lecture Notes George T. Gilbert Department of Mathematics, Texas Christian University [email protected] November 10, 17, & 29, 2011 1 Unique Factorization Our rings R will be integral domains (with identity). Definition. α1; α2 2 R are associates if α1 = α2u for some unit u 2 R. Definition. π 2 R is irreducible if π = π1π2 implies either π1 or π2 is a unit. Definition. R is a unique factorization domain (UFD) if every non-zero non-unit is a product of irreducible elements in a way that is unique up to order and associates. Examples: Z, any field k, the polynomial ring k[x1; : : : ; xk] GCDs exist in any UFD. (Greatest is in the sense of divisibility.) Theorem. If R is a UFD, then so is R[x]. n Proof. Let R be a UFD and K its field of fractions. The content of a0 + a1x + ··· + anx 2 K[x] is the GCD of a0; a1; : : : ; an. Primitive means content 1. Lemma. The content is multiplicative. Corollary. (Gauss' Lemma) The product of primitive polynomials is primitive. Lemma. A primitive polynomial is irreducible in R[x] if and only if it is irreducible in K[x]. Now use that K[x] is a UFD. Definition. R is a principal ideal domain (PID) if every ideal has the form (α) for some α 2 R. Theorem. In a PID R, a greatest common divisor g of α and β may be written as an R-linear combination of α and β. 1 Proof.
    [Show full text]
  • On Graded 2-Absorbing and Graded Weakly 2-Absorbing Pri- Mary Ideals
    KYUNGPOOK Math. J. 57(2017), 559-580 https://doi.org/10.5666/KMJ.2017.57.4.559 pISSN 1225-6951 eISSN 0454-8124 c Kyungpook Mathematical Journal On Graded 2-Absorbing and Graded Weakly 2-Absorbing Pri- mary Ideals Fatemeh Soheilnia∗ Department of Pure Mathematics, Faculty of Science, Imam Khomeini Interna- tional University, Qazvin, Iran e-mail : [email protected] Ahmad Yousefian Darani Department of Mathematics and Applications, University of Mohaghegh Ardabili, 5619911367, Ardabil, Iran e-mail : [email protected] Abstract. Let G be an arbitrary group with identity e and let R be a G-graded ring. In this paper, we define the concept of graded 2-absorbing and graded weakly 2-absorbing primary ideals of commutative G-graded rings with non-zero identity. A number of re- sults and basic properties of graded 2-absorbing primary and graded weakly 2-absorbing primary ideals are given. 1. Introduction Prime ideals (resp,. primary ideals) play an important role in commutative ring theory. Also, weakly prime ideals have been introduced and studied by D. D. Anderson and E. Smith in [1] and weakly primary ideals have been introduced and studied by S. E. Atani and F. Farzalipour in [2]. Later, A. Badawi in [6] generalized the concept of prime ideals in a different way. He defined a non-zero proper ideal I of commutative ring R to be a 2-absorbing ideal, if whenever a; b; c 2 R with abc 2 I, then either ab 2 I or ac 2 I or bc 2 I. This concept has a generalization that is called weakly 2-absorbing ideal, which has studied by A.
    [Show full text]
  • Monoid Rings and Strongly Two-Generated Ideals
    California State University, San Bernardino CSUSB ScholarWorks Electronic Theses, Projects, and Dissertations Office of aduateGr Studies 6-2014 MONOID RINGS AND STRONGLY TWO-GENERATED IDEALS Brittney M. Salt California State University - San Bernardino Follow this and additional works at: https://scholarworks.lib.csusb.edu/etd Part of the Algebra Commons, and the Other Mathematics Commons Recommended Citation Salt, Brittney M., "MONOID RINGS AND STRONGLY TWO-GENERATED IDEALS" (2014). Electronic Theses, Projects, and Dissertations. 31. https://scholarworks.lib.csusb.edu/etd/31 This Thesis is brought to you for free and open access by the Office of aduateGr Studies at CSUSB ScholarWorks. It has been accepted for inclusion in Electronic Theses, Projects, and Dissertations by an authorized administrator of CSUSB ScholarWorks. For more information, please contact [email protected]. Monoid Rings and Strongly Two-Generated Ideals A Thesis Presented to the Faculty of California State University, San Bernardino In Partial Fulfillment of the Requirements for the Degree Master of Arts in Mathematics by Brittney Salt June, 2014 Monoid Rings and Strongly Two-Generated Ideals A Thesis Presented to the Faculty of California State University, San Bernardino by Brittney Salt June, 2014 Approved by: J. Paul Vicknair, Committee Chair Date Zahid Hasan, Committee Member Jim Okon, Committee Member Peter Williams, Chair, Charles Stanton Department of Mathematics Graduate Coordinator, Department of Mathematics iii Abstract This paper determines whether monoid rings with the two-generator property have the strong two-generator property. Dedekind domains have both the two-generator and strong two-generator properties. How common is this? Two cases are considered here: the zero-dimensional case and the one-dimensional case for monoid rings.
    [Show full text]