In mathematics, a Bézout domain is a form of a Prüfer domain. It is an

integral domain In mathematics, specifically abstract algebra, 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 s ...

in which the sum of two

principal ideal In mathematics, specifically ring theory, a principal ideal is an ideal I in a ring R that is generated by a single element a of R through multiplication by every element of R. The term also has another, similar meaning in order theory, where ...

s is again a principal ideal. This means that for every pair of elements a Bézout identity holds, and that every

finitely generated ideal In ring theory, a branch of abstract algebra, an ideal of a ring is a special subset of its elements. Ideals generalize certain subsets of the integers, such as the even numbers or the multiples of 3. Addition and subtraction of even numbers pre ...

is principal. Any

principal ideal domain 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 princip ...

(PID) is a Bézout domain, but a Bézout domain need not be a

Noetherian ring 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-Noethe ...

, so it could have non-finitely generated ideals (which obviously excludes being a PID); if so, it is not a

unique factorization domain In mathematics, a unique factorization domain (UFD) (also sometimes called a factorial ring following the terminology of Bourbaki) is a ring in which a statement analogous to the fundamental theorem of arithmetic holds. Specifically, a UFD is ...

(UFD), but still is a

GCD domain In mathematics, a GCD domain is an integral domain ''R'' with the property that any two elements have a greatest common divisor (GCD); i.e., there is a unique minimal principal ideal containing the ideal generated by two given elements. Equivalentl ...

. The theory of Bézout domains retains many of the properties of PIDs, without requiring the Noetherian property. Bézout domains are named after the

French French (french: français(e), link=no) may refer to: * Something of, from, or related to France ** French language, which originated in France, and its various dialects and accents ** French people, a nation and ethnic group identified with Franc ...

mathematician A mathematician is someone who uses an extensive knowledge of mathematics in their work, typically to solve mathematical problems. Mathematicians are concerned with numbers, data, quantity, mathematical structure, structure, space, Mathematica ...

Étienne Bézout Étienne Bézout (; 31 March 1730 – 27 September 1783) was a French mathematician who was born in Nemours, Seine-et-Marne, France, and died in Avon (near Fontainebleau), France. Work In 1758 Bézout was elected an adjoint in mechanics of the F ...

Examples

* All PIDs are Bézout domains. * Examples of Bézout domains that are not PIDs include the ring of

entire function In complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic on the whole complex plane. Typical examples of entire functions are polynomials and the exponential function, and any fin ...

s (functions holomorphic on the whole complex plane) and the ring of all

algebraic integer In algebraic number theory, an algebraic integer is a complex number which is integral over the integers. That is, an algebraic integer is a complex root of some monic polynomial (a polynomial whose leading coefficient is 1) whose coefficien ...

s. In case of entire functions, the only irreducible elements are functions associated to a polynomial function of degree 1, so an element has a factorization only if it has finitely many zeroes. In the case of the algebraic integers there are no irreducible elements at all, since for any algebraic integer its square root (for instance) is also an algebraic integer. This shows in both cases that the ring is not a UFD, and so certainly not a PID. *

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

s are Bézout domains. Any non-Noetherian valuation ring is an example of a non-noetherian Bézout domain. *The following general construction produces a Bézout domain ''S'' that is not a UFD from any Bézout domain ''R'' that is not a field, for instance from a PID; the case is the basic example to have in mind. Let ''F'' be the

field of fractions In abstract algebra, the field of fractions of an integral domain is the smallest field in which it can be embedded. The construction of the field of fractions is modeled on the relationship between the integral domain of integers and the field ...

of ''R'', and put , the subring of polynomials in ''F'' 'X''with constant term in ''R''. This ring is not Noetherian, since an element like ''X'' with zero constant term can be divided indefinitely by noninvertible elements of ''R'', which are still noninvertible in ''S'', and the ideal generated by all these quotients of is not finitely generated (and so ''X'' has no factorization in ''S''). One shows as follows that ''S'' is a Bézout domain. :# It suffices to prove that for every pair ''a'', ''b'' in ''S'' there exist ''s'', ''t'' in ''S'' such that divides both ''a'' and ''b''. :# If ''a'' and ''b'' have a common divisor ''d'', it suffices to prove this for ''a''/''d'' and ''b''/''d'', since the same ''s'', ''t'' will do. :# We may assume the polynomials ''a'' and ''b'' nonzero; if both have a zero constant term, then let ''n'' be the minimal exponent such that at least one of them has a nonzero coefficient of ''X''^''n''; one can find ''f'' in ''F'' such that ''fX''^''n'' is a common divisor of ''a'' and ''b'' and divide by it. :# We may therefore assume at least one of ''a'', ''b'' has a nonzero constant term. If ''a'' and ''b'' viewed as elements of ''F'' 'X''are not relatively prime, there is a greatest common divisor of ''a'' and ''b'' in this UFD that has constant term 1, and therefore lies in ''S''; we can divide by this factor. :# We may therefore also assume that ''a'' and ''b'' are relatively prime in ''F'' 'X'' so that 1 lies in , and some constant polynomial ''r'' in ''R'' lies in . Also, since ''R'' is a Bézout domain, the gcd ''d'' in ''R'' of the constant terms ''a''₀ and ''b''₀ lies in . Since any element without constant term, like or , is divisible by any nonzero constant, the constant ''d'' is a common divisor in ''S'' of ''a'' and ''b''; we shall show it is in fact a greatest common divisor by showing that it lies in . Multiplying ''a'' and ''b'' respectively by the Bézout coefficients for ''d'' with respect to ''a''₀ and ''b''₀ gives a polynomial ''p'' in with constant term ''d''. Then has a zero constant term, and so is a multiple in ''S'' of the constant polynomial ''r'', and therefore lies in . But then ''d'' does as well, which completes the proof.

Properties

A ring is a Bézout domain if and only if it is an integral domain in which any two elements have a

greatest common divisor In mathematics, the greatest common divisor (GCD) of two or more integers, which are not all zero, is the largest positive integer that divides each of the integers. For two integers ''x'', ''y'', the greatest common divisor of ''x'' and ''y'' i ...

that is a linear combination of them: this is equivalent to the statement that an ideal which is generated by two elements is also generated by a single element, and induction demonstrates that all finitely generated ideals are principal. The expression of the greatest common divisor of two elements of a PID as a linear combination is often called

Bézout's identity In mathematics, Bézout's identity (also called Bézout's lemma), named after Étienne Bézout, is the following theorem: Here the greatest common divisor of and is taken to be . The integers and are called Bézout coefficients for ; they ...

, whence the terminology. Note that the above gcd condition is stronger than the mere existence of a gcd. An integral domain where a gcd exists for any two elements is called a

and thus Bézout domains are GCD domains. In particular, in a Bézout domain, irreducibles are

prime A prime number (or a prime) is a natural number greater than 1 that is not a product of two smaller natural numbers. A natural number greater than 1 that is not prime is called a composite number. For example, 5 is prime because the only way ...

(but as the algebraic integer example shows, they need not exist). For a Bézout domain ''R'', the following conditions are all equivalent: # ''R'' is a principal ideal domain. # ''R'' is Noetherian. # ''R'' is a

(UFD). # ''R'' satisfies the

ascending chain condition on principal ideals In abstract algebra, the ascending chain condition can be applied to the posets of principal left, principal right, or principal two-sided ideals of a ring, partially ordered by inclusion. The ascending chain condition on principal ideals (abbreviat ...

(ACCP). # Every nonzero nonunit in ''R'' factors into a product of irreducibles (R is an atomic domain). The equivalence of (1) and (2) was noted above. Since a Bézout domain is a GCD domain, it follows immediately that (3), (4) and (5) are equivalent. Finally, if ''R'' is not Noetherian, then there exists an infinite ascending chain of finitely generated ideals, so in a Bézout domain an infinite ascending chain of principal ideals. (4) and (2) are thus equivalent. A Bézout domain is a Prüfer domain, i.e., a domain in which each finitely generated ideal is invertible, or said another way, a commutative semihereditary domain.) Consequently, one may view the equivalence "Bézout domain iff Prüfer domain and GCD-domain" as analogous to the more familiar "PID iff

Dedekind domain 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 necessari ...

and UFD". Prüfer domains can be characterized as integral domains whose localizations at all

(equivalently, at all maximal) ideals are valuation domains. So the localization of a Bézout domain at a prime ideal is a valuation domain. Since an invertible ideal in a

local ring In abstract algebra, more specifically ring theory, local rings are certain rings that are comparatively simple, and serve to describe what is called "local behaviour", in the sense of functions defined on varieties or manifolds, or of algebraic ...

is principal, a local ring is a Bézout domain iff it is a valuation domain. Moreover, a valuation domain with noncyclic (equivalently non-

discrete Discrete may refer to: *Discrete particle or quantum in physics, for example in quantum theory *Discrete device, an electronic component with just one circuit element, either passive or active, other than an integrated circuit *Discrete group, a ...

) value group is not Noetherian, and every

totally ordered In mathematics, a total or linear order is a partial order in which any two elements are comparable. That is, a total order is a binary relation \leq on some set X, which satisfies the following for all a, b and c in X: # a \leq a ( reflexiv ...

abelian group In mathematics, an abelian group, also called a commutative group, is a group in which the result of applying the group operation to two group elements does not depend on the order in which they are written. That is, the group operation is com ...

is the value group of some valuation domain. This gives many examples of non-Noetherian Bézout domains. In noncommutative algebra, right Bézout domains are domains whose finitely generated right ideals are principal right ideals, that is, of the form ''xR'' for some ''x'' in ''R''. One notable result is that a right Bézout domain is a right Ore domain. This fact is not interesting in the commutative case, since ''every'' commutative domain is an Ore domain. Right Bézout domains are also right semihereditary rings.

Modules over a Bézout domain

Some facts about modules over a PID extend to modules over a Bézout domain. Let ''R'' be a Bézout domain and ''M'' finitely generated module over ''R''. Then ''M'' is flat if and only if it is torsion-free.

References

* * * * * {{DEFAULTSORT:Bezout domain Commutative algebra Ring theory

Examples

Properties

Modules over a Bézout domain

See also

References