In mathematics, a Pfister form is a particular kind of quadratic form, introduced by Albrecht Pfister in 1965. In what follows, quadratic forms are considered over a field F of characteristic not 2. For a natural number n, an n-fold Pfister form over F is a quadratic form of dimension 2<sup>n</sup> that can be written as a tensor product of quadratic forms
for some nonzero elements a<sub>1</sub>, ..., a<sub>n</sub> of F. (Some authors omit the signs in this definition; the notation here simplifies the relation to Milnor K-theory, discussed below.) An n-fold Pfister form can also be constructed inductively from an (nâÂÂ1)-fold Pfister form q and a nonzero element a of F, as .
So the 1-fold and 2-fold Pfister forms look like:
For n ⤠3, the n-fold Pfister forms are norm forms of composition algebras. In that case, two n-fold Pfister forms are isomorphic if and only if the corresponding composition algebras are isomorphic. In particular, this gives the classification of octonion algebras.
The n-fold Pfister forms additively generate the n-th power I<sup> n</sup> of the fundamental ideal of the Witt ring of F.
A quadratic form q over a field F is multiplicative if, for vectors of indeterminates x and y, we can write q(x).q(y) = q(z) for some vector z of rational functions in the x and y over F. Isotropic quadratic forms are multiplicative. For anisotropic quadratic forms, Pfister forms are multiplicative, and conversely.
For n-fold Pfister forms with n ⤠3, this had been known since the 19th century; in that case z can be taken to be bilinear in x and y, by the properties of composition algebras. It was a remarkable discovery by Pfister that n-fold Pfister forms for all n are multiplicative in the more general sense here, involving rational functions. For example, he deduced that for any field F and any natural number n, the set of sums of 2<sup>n</sup> squares in F is closed under multiplication, using that the quadratic form
is an n-fold Pfister form (namely, ).
Another striking feature of Pfister forms is that every isotropic Pfister form is in fact hyperbolic, that is, isomorphic to a direct sum of copies of the hyperbolic plane . This property also characterizes Pfister forms, as follows: If q is an anisotropic quadratic form over a field F, and if q becomes hyperbolic over every extension field E such that q becomes isotropic over E, then q is isomorphic to aÃÂ for some nonzero a in F and some Pfister form ÃÂ over F.
Let k<sub>n</sub>(F) be the n-th Milnor K-group modulo 2. There is a homomorphism from k<sub>n</sub>(F) to the quotient I<sup>n</sup>/I<sup>n+1</sup> in the Witt ring of F, given by
where the image is an n-fold Pfister form. The homomorphism is surjective, since the Pfister forms additively generate I<sup>n</sup>. One part of the Milnor conjecture, proved by Orlov, Vishik and Voevodsky, states that this homomorphism is in fact an isomorphism . That gives an explicit description of the abelian group I<sup>n</sup>/I<sup>n+1</sup> by generators and relations. The other part of the Milnor conjecture, proved by Voevodsky, says that k<sub>n</sub>(F) (and hence I<sup>n</sup>/I<sup>n+1</sup>) maps isomorphically to the Galois cohomology group H<sup>n</sup>(F, F<sub>2</sub>).
A Pfister neighbor is an anisotropic form ÃÂ which is isomorphic to a subform of aÃÂ for some nonzero a in F and some Pfister form ÃÂ with dim ÃÂ < 2 dim ÃÂ. The associated Pfister form ÃÂ is determined up to isomorphism by ÃÂ. Every anisotropic form of dimension 3 is a Pfister neighbor; an anisotropic form of dimension 4 is a Pfister neighbor if and only if its discriminant in F<sup>*</sup>/(F<sup>*</sup>)<sup>2</sup> is trivial. A field F has the property that every 5-dimensional anisotropic form over F is a Pfister neighbor if and only if it is a linked field.