Ore condition

In mathematics, especially in the area of algebra known as ring theory, the Ore condition is a condition introduced by Øystein Ore, in connection with the question of extending beyond commutative rings the construction of a field of fractions, or more generally localization of a ring. The ''right Ore condition'' for a multiplicative subset ''S'' of a ring ''R'' is that for and , the intersection . A (non-commutative) domain for which the set of non-zero elements satisfies the right Ore condition is called a right Ore domain. The left case is defined similarly.

General idea

The goal is to construct the right ring of fractions ''R'' 'S''^−1with respect to a multiplicative subset ''S''. In other words, we want to work with elements of the form ''as''^−1 and have a ring structure on the set ''R'' 'S''^−1 The problem is that there is no obvious interpretation of the product (''as''^−1)(''bt''^−1); indeed, we need a method to "move" ''s''^−1 past ''b''. This means that we need to be able to rewrite ''s''^−1''b'' as a product ''b''₁''s''₁^−1. Suppose then multiplying on the left by ''s'' and on the right by ''s''₁, we get . Hence we see the necessity, for a given ''a'' and ''s'', of the existence of ''a''₁ and ''s''₁ with and such that .

Application

Since it is well known that each integral domain is a subring of a field of fractions (via an embedding) in such a way that every element is of the form ''rs''^−1 with ''s'' nonzero, it is natural to ask if the same construction can take a noncommutative domain and associate a division ring (a noncommutative field) with the same property. It turns out that the answer is sometimes "no", that is, there are domains which do not have an analogous "right division ring of fractions".

For every right Ore domain ''R'', there is a unique (up to natural ''R''-isomorphism) division ring ''D'' containing ''R'' as a subring such that every element of ''D'' is of the form ''rs''^−1 for ''r'' in ''R'' and ''s'' nonzero in ''R''. Such a division ring ''D'' is called a ring of right fractions of ''R'', and ''R'' is called a right order in ''D''. The notion of a ring of left fractions and left order are defined analogously, with elements of ''D'' being of the form ''s''^−1''r''.

It is important to remember that the definition of ''R'' being a right order in ''D'' includes the condition that ''D'' must consist entirely of elements of the form ''rs''^−1. Any domain satisfying one of the Ore conditions can be considered a subring of a division ring, however this does not automatically mean ''R'' is a left order in ''D'', since it is possible ''D'' has an element which is not of the form ''s''^−1''r''. Thus it is possible for ''R'' to be a right-not-left Ore domain. Intuitively, the condition that all elements of ''D'' be of the form ''rs''^−1 says that ''R'' is a "big" ''R''-submodule of ''D''. In fact the condition ensures ''R''_''R'' is an essential submodule of ''D''_''R''. Lastly, there is even an example of a domain in a division ring which satisfies ''neither'' Ore condition (see examples below).

Another natural question is: "When is a subring of a division ring right Ore?" One characterization is that a subring ''R'' of a division ring ''D'' is a right Ore domain if and only if ''D'' is a flat left ''R''-module .

A different, stronger version of the Ore conditions is usually given for the case where ''R'' is not a domain, namely that there should be a common multiple

:''c'' = ''au'' = ''bv''

with ''u'', ''v'' not zero divisors. In this case, Ore's theorem guarantees the existence of an over-ring called the (right or left) classical ring of quotients.

Examples

Commutative domains are automatically Ore domains, since for nonzero ''a'' and ''b'', ''ab'' is nonzero in . Right Noetherian domains, such as right principal ideal domains, are also known to be right Ore domains. Even more generally, Alfred Goldie proved that a domain ''R'' is right Ore if and only if ''R''_''R'' has finite uniform dimension. It is also true that right Bézout domains are right Ore.

A subdomain of a division ring which is not right or left Ore: If ''F'' is any field, and $G = \langle x,y \rangle\,$ is the free monoid on two symbols ''x'' and ''y'', then the monoid ring F , does not satisfy any Ore condition, but it is a free ideal ring and thus indeed a subring of a division ring, by .

Multiplicative sets

The Ore condition can be generalized to other multiplicative subsets, and is presented in textbook form in and . A subset ''S'' of a ring ''R'' is called a right denominator set if it satisfies the following three conditions for every ''a'', ''b'' in ''R'', and ''s'', ''t'' in ''S'':
# ''st'' in ''S''; (The set ''S'' is multiplicatively closed.)
# ''aS'' ∩ ''sR'' is not empty; (The set ''S'' is right permutable.)
# If , then there is some ''u'' in ''S'' with ; (The set ''S'' is right reversible.)
If ''S'' is a right denominator set, then one can construct the ring of right fractions ''RS''^−1 similarly to the commutative case. If ''S'' is taken to be the set of regular elements (those elements ''a'' in ''R'' such that if ''b'' in ''R'' is nonzero, then ''ab'' and ''ba'' are nonzero), then the right Ore condition is simply the requirement that ''S'' be a right denominator set.

Many properties of commutative localization hold in this more general setting. If ''S'' is a right denominator set for a ring ''R'', then the left ''R''-module ''RS''^−1 is flat. Furthermore, if ''M'' is a right ''R''-module, then the ''S''-torsion, is an ''R''-submodule isomorphic to , and the module is naturally isomorphic to a module ''MS''^−1 consisting of "fractions" as in the commutative case.

Notes

References

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*{{citation, last=Stenström , first=Bo , title=Rings and modules of quotients , series=Lecture Notes in Mathematics , volume=237 , publisher=Springer-Verlag , place=Berlin , date=1971 , pages=vii+136 , isbn=978-3-540-05690-4, mr=0325663 , zbl=0229.16003 , doi=10.1007/BFb0059904

External links

PlanetMath page on Ore condition

PlanetMath page on Ore's theorem



Ring theory