Krull ring

Last updated March 20, 2024

In commutative algebra, a Krull ring, or Krull domain, is a commutative ring with a well behaved theory of prime factorization. They were introduced by Wolfgang Krull in 1931.^[1] They are a higher-dimensional generalization of Dedekind domains, which are exactly the Krull domains of dimension at most 1.

Formal definition

Let $A$ be an integral domain and let $P$ be the set of all prime ideals of $A$ of height one, that is, the set of all prime ideals properly containing no nonzero prime ideal. Then $A$ is a Krull ring if

$A_{\mathfrak {p}}$ is a discrete valuation ring for all ${\mathfrak {p}}\in P$ ,
$A$ is the intersection of these discrete valuation rings (considered as subrings of the quotient field of $A$ ),
any nonzero element of $A$ is contained in only a finite number of height 1 prime ideals.

It is also possible to characterize Krull rings by mean of valuations only:^[2]

An integral domain $A$ is a Krull ring if there exists a family $\{v_{i}\}_{i\in I}$ of discrete valuations on the field of fractions $K$ of $A$ such that:

for any $x\in K\setminus \{0\}$ and all $i$ , except possibly a finite number of them, $v_{i}(x)=0$ ,
for any $x\in K\setminus \{0\}$ , $x$ belongs to $A$ if and only if $v_{i}(x)\geq 0$ for all $i\in I$ .

The valuations $v_{i}$ are called essential valuations of $A$ .

The link between the two definitions is as follows: for every ${\mathfrak {p}}\in P$ , one can associate a unique normalized valuation $v_{\mathfrak {p}}$ of $K$ whose valuation ring is $A_{\mathfrak {p}}$ .^[3] Then the set ${\mathcal {V}}=\{v_{\mathfrak {p}}\}$ satisfies the conditions of the equivalent definition. Conversely, if the set ${\mathcal {V}}'=\{v_{i}\}$ is as above, and the $v_{i}$ have been normalized, then ${\mathcal {V}}'$ may be bigger than ${\mathcal {V}}$ , but it must contain ${\mathcal {V}}$ . In other words, ${\mathcal {V}}$ is the minimal set of normalized valuations satisfying the equivalent definition.

There are other ways to introduce and define Krull rings. The theory of Krull rings can be exposed in synergy with the theory of divisorial ideals. One of the best^{[ according to whom? ]} references on the subject is Lecture on Unique Factorization Domains by P. Samuel.

Properties

With the notations above, let $v_{\mathfrak {p}}$ denote the normalized valuation corresponding to the valuation ring $A_{\mathfrak {p}}$ , $U$ denote the set of units of $A$ , and $K$ its quotient field.

An element $x\in K$ belongs to $U$ if, and only if, $v_{\mathfrak {p}}(x)=0$ for every ${\mathfrak {p}}\in P$ . Indeed, in this case, $x\not \in A_{\mathfrak {p}}{\mathfrak {p}}$ for every ${\mathfrak {p}}\in P$ , hence $x^{-1}\in A_{\mathfrak {p}}$ ; by the intersection property, $x^{-1}\in A$ . Conversely, if $x$ and $x^{-1}$ are in $A$ , then $v_{\mathfrak {p}}(xx^{-1})=v_{\mathfrak {p}}(1)=0=v_{\mathfrak {p}}(x)+v_{\mathfrak {p}}(x^{-1})$ , hence $v_{\mathfrak {p}}(x)=v_{\mathfrak {p}}(x^{-1})=0$ , since both numbers must be $\geq 0$ .
An element $x\in A$ is uniquely determined, up to a unit of $A$ , by the values $v_{\mathfrak {p}}(x)$ , ${\mathfrak {p}}\in P$ . Indeed, if $v_{\mathfrak {p}}(x)=v_{\mathfrak {p}}(y)$ for every ${\mathfrak {p}}\in P$ , then $v_{\mathfrak {p}}(xy^{-1})=0$ , hence $xy^{-1}\in U$ by the above property (q.e.d). This shows that the application $x\ {\rm {mod}}\ U\mapsto \left(v_{\mathfrak {p}}(x)\right)_{{\mathfrak {p}}\in P}$ is well defined, and since $v_{\mathfrak {p}}(x)\not =0$ for only finitely many ${\mathfrak {p}}$ , it is an embedding of $A^{\times }/U$ into the free Abelian group generated by the elements of $P$ . Thus, using the multiplicative notation " $\cdot$ " for the later group, there holds, for every $x\in A^{\times }$ , $x=1\cdot {\mathfrak {p}}_{1}^{\alpha _{1}}\cdot {\mathfrak {p}}_{2}^{\alpha _{2}}\cdots {\mathfrak {p}}_{n}^{\alpha _{n}}\ {\rm {mod}}\ U$ , where the ${\mathfrak {p}}_{i}$ are the elements of $P$ containing $x$ , and $\alpha _{i}=v_{{\mathfrak {p}}_{i}}(x)$ .
The valuations $v_{\mathfrak {p}}$ are pairwise independent.^[4] As a consequence, there holds the so-called weak approximation theorem,^[5] an homologue of the Chinese remainder theorem: if ${\mathfrak {p}}_{1},\ldots {\mathfrak {p}}_{n}$ are distinct elements of $P$ , $x_{1},\ldots x_{n}$ belong to $K$ (resp. $A_{\mathfrak {p}}$ ), and $a_{1},\ldots a_{n}$ are $n$ natural numbers, then there exist $x\in K$ (resp. $x\in A_{\mathfrak {p}}$ ) such that $v_{{\mathfrak {p}}_{i}}(x-x_{i})=n_{i}$ for every $i$ .
A consequence of the weak approximation theorem is a characterization of when Krull rings are noetherian; namely, a Krull ring $A$ is noetherian if and only if all of its quotients $A/{\mathfrak {p}}$ by height-1 primes are noetherian.
Two elements $x$ and $y$ of $A$ are coprime if $v_{\mathfrak {p}}(x)$ and $v_{\mathfrak {p}}(y)$ are not both $>0$ for every ${\mathfrak {p}}\in P$ . The basic properties of valuations imply that a good theory of coprimality holds in $A$ .
Every prime ideal of $A$ contains an element of $P$ .^[6]
Any finite intersection of Krull domains whose quotient fields are the same is again a Krull domain.^[7]
If $L$ is a subfield of $K$ , then $A\cap L$ is a Krull domain.^[8]
If $S\subset A$ is a multiplicatively closed set not containing 0, the ring of quotients $S^{-1}A$ is again a Krull domain. In fact, the essential valuations of $S^{-1}A$ are those valuation $v_{\mathfrak {p}}$ (of $K$ ) for which ${\mathfrak {p}}\cap S=\emptyset$ .^[9]
If $L$ is a finite algebraic extension of $K$ , and $B$ is the integral closure of $A$ in $L$ , then $B$ is a Krull domain.^[10]

Examples

Any unique factorization domain is a Krull domain. Conversely, a Krull domain is a unique factorization domain if (and only if) every prime ideal of height one is principal.^[11]^[12]
Every integrally closed noetherian domain is a Krull domain.^[13] In particular, Dedekind domains are Krull domains. Conversely, Krull domains are integrally closed, so a Noetherian domain is Krull if and only if it is integrally closed.
If $A$ is a Krull domain then so is the polynomial ring $A[x]$ and the formal power series ring $A[[x]]$ .^[14]
The polynomial ring $R[x_{1},x_{2},x_{3},\ldots ]$ in infinitely many variables over a unique factorization domain $R$ is a Krull domain which is not noetherian.
Let $A$ be a Noetherian domain with quotient field $K$ , and $L$ be a finite algebraic extension of $K$ . Then the integral closure of $A$ in $L$ is a Krull domain (Mori–Nagata theorem).^[15]
Let $A$ be a Zariski ring (e.g., a local noetherian ring). If the completion ${\widehat {A}}$ is a Krull domain, then $A$ is a Krull domain (Mori).^[16]^[17]
Let $A$ be a Krull domain, and $V$ be the multiplicatively closed set consisting in the powers of a prime element $p\in A$ . Then $S^{-1}A$ is a Krull domain (Nagata).^[18]

The divisor class group of a Krull ring

Assume that $A$ is a Krull domain and $K$ is its quotient field. A prime divisor of $A$ is a height 1 prime ideal of $A$ . The set of prime divisors of $A$ will be denoted $P(A)$ in the sequel. A (Weil) divisor of $A$ is a formal integral linear combination of prime divisors. They form an Abelian group, noted $D(A)$ . A divisor of the form $div(x)=\sum _{p\in P}v_{p}(x)\cdot p$ , for some non-zero $x$ in $K$ , is called a principal divisor. The principal divisors of $A$ form a subgroup of the group of divisors (it has been shown above that this group is isomorphic to $A^{\times }/U$ , where $U$ is the group of unities of $A$ ). The quotient of the group of divisors by the subgroup of principal divisors is called the divisor class group of $A$ ; it is usually denoted $C(A)$ .

Assume that $B$ is a Krull domain containing $A$ . As usual, we say that a prime ideal ${\mathfrak {P}}$ of $B$ lies above a prime ideal ${\mathfrak {p}}$ of $A$ if ${\mathfrak {P}}\cap A={\mathfrak {p}}$ ; this is abbreviated in ${\mathfrak {P}}|{\mathfrak {p}}$ .

Denote the ramification index of $v_{\mathfrak {P}}$ over $v_{\mathfrak {p}}$ by $e({\mathfrak {P}},{\mathfrak {p}})$ , and by $P(B)$ the set of prime divisors of $B$ . Define the application $P(A)\to D(B)$ by

j({\mathfrak {p}})=\sum _{{\mathfrak {P}}|{\mathfrak {p}},\ {\mathfrak {P}}\in P(B)}e({\mathfrak {P}},{\mathfrak {p}}){\mathfrak {P}}

(the above sum is finite since every $x\in {\mathfrak {p}}$ is contained in at most finitely many elements of $P(B)$ ). Let extend the application $j$ by linearity to a linear application $D(A)\to D(B)$ . One can now ask in what cases $j$ induces a morphism ${\bar {j}}:C(A)\to C(B)$ . This leads to several results.^[19] For example, the following generalizes a theorem of Gauss:

The application ${\bar {j}}:C(A)\to C(A[X])$ is bijective. In particular, if $A$ is a unique factorization domain, then so is $A[X]$ .^[20]

The divisor class group of a Krull rings are also used to set up powerful descent methods, and in particular the Galoisian descent.^[21]

Cartier divisor

A Cartier divisor of a Krull ring is a locally principal (Weil) divisor. The Cartier divisors form a subgroup of the group of divisors containing the principal divisors. The quotient of the Cartier divisors by the principal divisors is a subgroup of the divisor class group, isomorphic to the Picard group of invertible sheaves on Spec(A).

Example: in the ring k[x,y,z]/(xy–z²) the divisor class group has order 2, generated by the divisor y=z, but the Picard subgroup is the trivial group.^[22]

Related Research Articles

In mathematics, more specifically in ring theory, a Euclidean domain is an integral domain that can be endowed with a Euclidean function which allows a suitable generalization of the Euclidean division of integers. This generalized Euclidean algorithm can be put to many of the same uses as Euclid's original algorithm in the ring of integers: in any Euclidean domain, one can apply the Euclidean algorithm to compute the greatest common divisor of any two elements. In particular, the greatest common divisor of any two elements exists and can be written as a linear combination of them. Also every ideal in a Euclidean domain is principal, which implies a suitable generalization of the fundamental theorem of arithmetic: every Euclidean domain is a unique factorization domain.

In mathematics, an integral domain is a nonzero commutative ring in which the product of any two nonzero elements is nonzero. Integral domains are generalizations of the ring of integers and provide a natural setting for studying divisibility. In an integral domain, every nonzero element a has the cancellation property, that is, if a ≠ 0, an equality ab = ac implies b = c.

In mathematics, a principal ideal domain, or PID, is an integral domain in which every ideal is principal, i.e., can be generated by a single element. More generally, a principal ideal ring is a nonzero commutative ring whose ideals are principal, although some authors refer to PIDs as principal rings. The distinction is that a principal ideal ring may have zero divisors whereas a principal ideal domain cannot.

In mathematics, rings are algebraic structures that generalize fields: multiplication need not be commutative and multiplicative inverses need not exist. Informally, a ring is a set equipped with two binary operations satisfying properties analogous to those of addition and multiplication of integers. Ring elements may be numbers such as integers or complex numbers, but they may also be non-numerical objects such as polynomials, square matrices, functions, and power series.

In commutative algebra, the Krull dimension of a commutative ring R, named after Wolfgang Krull, is the supremum of the lengths of all chains of prime ideals. The Krull dimension need not be finite even for a Noetherian ring. More generally the Krull dimension can be defined for modules over possibly non-commutative rings as the deviation of the poset of submodules.

In mathematics, a Noetherian ring is a ring that satisfies the ascending chain condition on left and right ideals; if the chain condition is satisfied only for left ideals or for right ideals, then the ring is said left-Noetherian or right-Noetherian respectively. That is, every increasing sequence $of left ideals has a largest element; that is, there exists an n such that:$

In mathematics, a unique factorization domain (UFD) is a ring in which a statement analogous to the fundamental theorem of arithmetic holds. Specifically, a UFD is an integral domain in which every non-zero non-unit element can be written as a product of irreducible elements, uniquely up to order and units.

In mathematics, a commutative ring is a ring in which the multiplication operation is commutative. The study of commutative rings is called commutative algebra. Complementarily, noncommutative algebra is the study of ring properties that are not specific to commutative rings. This distinction results from the high number of fundamental properties of commutative rings that do not extend to noncommutative rings.

In abstract algebra, a Dedekind domain or Dedekind ring, named after Richard Dedekind, is an integral domain in which every nonzero proper ideal factors into a product of prime ideals. It can be shown that such a factorization is then necessarily unique up to the order of the factors. There are at least three other characterizations of Dedekind domains that are sometimes taken as the definition: see below.

In mathematics, in particular commutative algebra, the concept of fractional ideal is introduced in the context of integral domains and is particularly fruitful in the study of Dedekind domains. In some sense, fractional ideals of an integral domain are like ideals where denominators are allowed. In contexts where fractional ideals and ordinary ring ideals are both under discussion, the latter are sometimes termed integral ideals for clarity.

In mathematics, especially in the area of abstract algebra known as module theory, an injective module is a module Q that shares certain desirable properties with the Z-module Q of all rational numbers. Specifically, if Q is a submodule of some other module, then it is already a direct summand of that module; also, given a submodule of a module Y, any module homomorphism from this submodule to Q can be extended to a homomorphism from all of Y to Q. This concept is dual to that of projective modules. Injective modules were introduced in and are discussed in some detail in the textbook.

In commutative algebra, a regular local ring is a Noetherian local ring having the property that the minimal number of generators of its maximal ideal is equal to its Krull dimension. In symbols, let A be a Noetherian local ring with maximal ideal m, and suppose a₁, ..., a_n is a minimal set of generators of m. Then by Krull's principal ideal theorem n ≥ dim A, and A is defined to be regular if n = dim A.

In ring theory, a branch of mathematics, a ring is called a reduced ring if it has no non-zero nilpotent elements. Equivalently, a ring is reduced if it has no non-zero elements with square zero, that is, x² = 0 implies x = 0. A commutative algebra over a commutative ring is called a reduced algebra if its underlying ring is reduced.

In abstract algebra, a discrete valuation ring (DVR) is a principal ideal domain (PID) with exactly one non-zero maximal ideal.

In abstract algebra, a valuation ring is an integral domain D such that for every non-zero element x of its field of fractions F, at least one of x or x⁻¹ belongs to D.

In mathematics, the Lasker–Noether theorem states that every Noetherian ring is a Lasker ring, which means that every ideal can be decomposed as an intersection, called primary decomposition, of finitely many primary ideals. The theorem was first proven by Emanuel Lasker for the special case of polynomial rings and convergent power series rings, and was proven in its full generality by Emmy Noether.

In commutative algebra, an element b of a commutative ring B is said to be integral over a subring A of B if b is a root of some monic polynomial over A.

In mathematics, especially in commutative algebra, certain prime ideals called minimal prime ideals play an important role in understanding rings and modules. The notion of height and Krull's principal ideal theorem use minimal prime ideals.

In commutative algebra, an integrally closed domainA is an integral domain whose integral closure in its field of fractions is A itself. Spelled out, this means that if x is an element of the field of fractions of A that is a root of a monic polynomial with coefficients in A, then x is itself an element of A. Many well-studied domains are integrally closed, as shown by the following chain of class inclusions:

This is a glossary of commutative algebra.

References

↑ WolfgangKrull ( 1931 ).
↑ P. Samuel, Lectures on Unique Factorization Domain, Theorem 3.5.
↑ A discrete valuation $v$ is said to be normalized if $v(O_{v})=\mathbb {N}$ , where $O_{v}$ is the valuation ring of $v$ . So, every class of equivalent discrete valuations contains a unique normalized valuation.
↑ If $v_{{\mathfrak {p}}_{1}}$ and $v_{{\mathfrak {p}}_{2}}$ were both finer than a common valuation $w$ of $K$ , the ideals $A_{{\mathfrak {p}}_{1}}{\mathfrak {p}}_{1}$ and $A_{{\mathfrak {p}}_{2}}{\mathfrak {p}}_{2}$ of their corresponding valuation rings would contain properly the prime ideal ${\mathfrak {p}}_{w}=\{x\in K:\ w(x)>0\},$ hence ${\mathfrak {p}}_{1}$ and ${\mathfrak {p}}_{2}$ would contain the prime ideal ${\mathfrak {p}}_{w}\cap A$ of $A$ , which is forbidden by definition.
↑ See Moshe Jarden, Intersections of local algebraic extensions of a Hilbertian field , in A. Barlotti et al., Generators and Relations in Groups and Geometries, Dordrecht, Kluwer, coll., NATO ASI Series C (no 333), 1991, p. 343-405. Read online: archive, p. 17, Prop. 4.4, 4.5 and Rmk 4.6.
↑ P. Samuel, Lectures on Unique Factorization Domains, Lemma 3.3.
↑ Idem, Prop 4.1 and Corollary (a).
↑ Idem, Prop 4.1 and Corollary (b).
↑ Idem, Prop. 4.2.
↑ Idem, Prop 4.5.
↑ P. Samuel, Lectures on Factorial Rings, Thm. 5.3.
↑ "Krull ring", Encyclopedia of Mathematics , EMS Press, 2001 [1994], retrieved 2016-04-14
↑ P. Samuel, Lectures on Unique Factorization Domains, Theorem 3.2.
↑ Idem, Proposition 4.3 and 4.4.
↑ Huneke, Craig; Swanson, Irena (2006-10-12). Integral Closure of Ideals, Rings, and Modules. Cambridge University Press. ISBN 9780521688604.
↑ Bourbaki, 7.1, no 10, Proposition 16.
↑ P. Samuel, Lectures on Unique Factorization Domains, Thm. 6.5.
↑ P. Samuel, Lectures on Unique Factorization Domains, Thm. 6.3.
↑ P. Samuel, Lectures on Unique Factorization Domains, p. 14-25.
↑ Idem, Thm. 6.4.
↑ See P. Samuel, Lectures on Unique Factorization Domains, P. 45-64.
↑ Hartshorne, GTM52, Example 6.5.2, p.133 and Example 6.11.3, p.142.

N. Bourbaki. Commutative algebra .
"Krull ring", Encyclopedia of Mathematics , EMS Press, 2001 [1994]
Krull, Wolfgang (1931), "Allgemeine Bewertungstheorie", J. Reine Angew. Math., 167: 160–196, archived from the original on January 6, 2013
Hideyuki Matsumura, Commutative Algebra. Second Edition. Mathematics Lecture Note Series, 56. Benjamin/Cummings Publishing Co., Inc., Reading, Mass., 1980. xv+313 pp. ISBN 0-8053-7026-9
Hideyuki Matsumura, Commutative Ring Theory. Translated from the Japanese by M. Reid. Cambridge Studies in Advanced Mathematics, 8. Cambridge University Press, Cambridge, 1986. xiv+320 pp. ISBN 0-521-25916-9
Samuel, Pierre (1964), Murthy, M. Pavman (ed.), Lectures on unique factorization domains, Tata Institute of Fundamental Research Lectures on Mathematics, vol. 30, Bombay: Tata Institute of Fundamental Research, MR 0214579

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] WolfgangKrull ( 1931 ).

[2] P. Samuel, Lectures on Unique Factorization Domain, Theorem 3.5.

[3] A discrete valuation $v$ is said to be normalized if $v(O_{v})=\mathbb {N}$ , where $O_{v}$ is the valuation ring of $v$ . So, every class of equivalent discrete valuations contains a unique normalized valuation.

[4] If $v_{{\mathfrak {p}}_{1}}$ and $v_{{\mathfrak {p}}_{2}}$ were both finer than a common valuation $w$ of $K$ , the ideals $A_{{\mathfrak {p}}_{1}}{\mathfrak {p}}_{1}$ and $A_{{\mathfrak {p}}_{2}}{\mathfrak {p}}_{2}$ of their corresponding valuation rings would contain properly the prime ideal ${\mathfrak {p}}_{w}=\{x\in K:\ w(x)>0\},$ hence ${\mathfrak {p}}_{1}$ and ${\mathfrak {p}}_{2}$ would contain the prime ideal ${\mathfrak {p}}_{w}\cap A$ of $A$ , which is forbidden by definition.

[5] See Moshe Jarden, Intersections of local algebraic extensions of a Hilbertian field , in A. Barlotti et al., Generators and Relations in Groups and Geometries, Dordrecht, Kluwer, coll., NATO ASI Series C (no 333), 1991, p. 343-405. Read online: archive, p. 17, Prop. 4.4, 4.5 and Rmk 4.6.

[6] P. Samuel, Lectures on Unique Factorization Domains, Lemma 3.3.

[7] Idem, Prop 4.1 and Corollary (a).

[8] Idem, Prop 4.1 and Corollary (b).

[9] Idem, Prop. 4.2.

[10] Idem, Prop 4.5.

[11] P. Samuel, Lectures on Factorial Rings, Thm. 5.3.

[12] "Krull ring", Encyclopedia of Mathematics , EMS Press, 2001 [1994], retrieved 2016-04-14

[13] P. Samuel, Lectures on Unique Factorization Domains, Theorem 3.2.

[14] Idem, Proposition 4.3 and 4.4.

[15] Huneke, Craig; Swanson, Irena (2006-10-12). Integral Closure of Ideals, Rings, and Modules. Cambridge University Press. ISBN 9780521688604.

[16] Bourbaki, 7.1, no 10, Proposition 16.

[17] P. Samuel, Lectures on Unique Factorization Domains, Thm. 6.5.

[18] P. Samuel, Lectures on Unique Factorization Domains, Thm. 6.3.

[19] P. Samuel, Lectures on Unique Factorization Domains, p. 14-25.

[20] Idem, Thm. 6.4.

[21] See P. Samuel, Lectures on Unique Factorization Domains, P. 45-64.

[22] Hartshorne, GTM52, Example 6.5.2, p.133 and Example 6.11.3, p.142.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

[14]

[15]

[16]

[17]

[18]

[19]

[20]

[21]

[22]