Brauer group

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In mathematics, the Brauer group arose out of an attempt to classify division algebras over a given field K. It is an abelian group with elements isomorphism classes of division algebras over K, such that the center is exactly K. The group is named for the algebraist Richard Brauer.

1 Construction of the Brauer group
2 Examples
3 Generalization
4 See also
5 External links

[edit] Construction of the Brauer group

A central simple algebra, is a finite-dimensional (associative) algebra A, which is a simple ring, and for which the center is exactly K. For example, the complex numbers C form a CSA over themselves, but not over R (the center is C itself, hence too large). That is why division algebras over R are not 1-1 with Br(R).

Given two such central simple algebras A and B, one defines a product on

$A\otimes B$

(taken as vector spaces over K) using the bilinearity of the definition

$(a \otimes b) \cdot (c\otimes d) = ac\otimes bd.$

This makes the tensor product into a K-algebra (see also tensor product of R-algebras). It turns out that this is always central simple. A slick way to see this is to use a characterisation: a central simple algebra over K is a K-algebra that becomes a matrix ring when we extend the field of scalars to an algebraic closure of K.

Given this closure property for CSAs, they form a monoid under tensor product. To get a group, apply the Artin-Wedderburn theorem (Wedderburn's part, in fact), to express any CSA as M(n,D), an n×n matrix ring over a division algebra D. If we look just at D, rather than the value of n, the monoid becomes a group. That is, if we impose an equivalence relation identifying M(m,D) with M(n,D) for all integers m and n at least 1, we get a congruence relation; and the congruence classes are all invertible, the inverse class to that of an algebra A containing the opposite algebra $A op$ .

[edit] Examples

The Brauer group for an algebraically closed field or a finite field is the trivial group with only the identity element.

The Brauer group Br(R) of the real number field R is a cyclic group of order two: there are just two types of division algebra, R and the quaternion algebra H. The product in the Brauer group is based on the tensor product: the statement that H has order two in the group is equivalent to the existence of an isomorphism of R-algebras

$\mathbb{H} \otimes \mathbb{H} \cong M(4, \mathbb{R})$

of 16-dimensional algebras, where the RHS is the ring of 4×4 real matrices.

[edit] Generalization

In the further theory, the Brauer groups of local fields are computed (they all turn out to be canonically isomorphic to Q/Z, for p-adic fields); and the results applied to global fields. This gives one approach to class field theory. It also has been applied to Diophantine equations. More precisely, the Brauer group Br(K) of a global field K is given by the exact sequence

$0\rightarrow Br(K)\rightarrow \oplus_p Br(K_p)\rightarrow Q/Z \rightarrow 0$

where the sum in the middle is over all (archimedean and non-archimedean) completions of K. The group Q/Z on the right is really the "Brauer group" of the class formation of idele classes associated to K.

In the general theory the Brauer group is expressed by factor sets; and expressed in terms of Galois cohomology via

$Br(K) \cong H^2(Gal(K^s/K), {K^s}^*).$

Here, not assuming K to be a perfect field, K^s is the separable closure. When K is perfect this is the same as an algebraic closure; otherwise the Galois group must be defined in terms of K^s/K even to make sense.

A generalisation via the theory of Azumaya algebras was introduced in algebraic geometry by Grothendieck.