Milnor K-theory

In mathematics, Milnor K-theory is an invariant of fields defined by Milnor (1970). Originally viewed as an approximation to algebraic K-theory, Milnor K-theory has turned out to be an important invariant in its own right.

Definition

The calculation of K2 of a field by Matsumoto led Milnor to the following, seemingly naive, definition of the "higher" K-groups of a field F:

 K^M_*(F) := T^*F^\times/(a\otimes (1-a)), \,

the quotient of the tensor algebra over the integers of the multiplicative group F× by the two-sided ideal generated by the elements

a\otimes(1-a) \,

for a  0, 1 in F. The nth Milnor K-group KnM(F) is the nth graded piece of this graded ring; for example, K0M(F) = Z and K1M(F) = F*. There is a natural homomorphism

 K^M_n(F) \rightarrow K_n(F)

from the Milnor K-groups of a field to the Quillen K-groups, which is an isomorphism for n ≤ 2 but not for larger n, in general. For nonzero elements a1, ..., an in F, the symbol {a1, ..., an} in KnM(F) means the image of a1 ⊗ ... ⊗ an in the tensor algebra. Every element of Milnor K-theory can be written as a finite sum of symbols. The fact that {a, 1−a} = 0 in K2M(F) for a in F − {0,1} is sometimes called the Steinberg relation.

The ring K*M(F) is graded-commutative.[1]

Examples

We have K^M_n(\mathbb{F}_q) = 0 for n  2, while K^M_2(\mathbb{C}) is an uncountable uniquely divisible group. (An abelian group is uniquely divisible if it is a vector space over the rational numbers.) Also, K^M_2(\mathbb{R}) is the direct sum of a cyclic group of order 2 and an uncountable uniquely divisible group; K^M_2(\mathbb{Q}_p) is the direct sum of the multiplicative group of \mathbb{F}_p and an uncountable uniquely divisible group; K^M_2(\mathbb{Q}) is the direct sum of the cyclic group of order 2 and cyclic groups of order p-1 for all odd prime p.

Applications

Milnor K-theory plays a fundamental role in higher class field theory, replacing K1M(F) = F* in the one-dimensional class field theory.

Milnor K-theory fits into the broader context of motivic cohomology, via the isomorphism

K_M^n(F) \cong H^n(F, \mathbf{Z}(n))

of the Milnor K-theory of a field with a certain motivic cohomology group.[2] In this sense, the apparently ad hoc definition of Milnor K-theory becomes a theorem: certain motivic cohomology groups of a field can be explicitly computed by generators and relations.

A much deeper result, the Bloch-Kato conjecture (also called the norm residue isomorphism theorem), relates Milnor K-theory to Galois cohomology or etale cohomology:

 K_M^n(F)/r \cong H^n_{\text{et}}(F, \mathbf{Z}/r(n)),

for any positive integer r invertible in the field F. This was proved by Voevodsky, with contributions by Rost and others.[3] This includes the MerkurjevSuslin theorem and the Milnor conjecture as special cases (the cases n = 2 and r = 2, respectively).

Finally, there is a relation between Milnor K-theory and quadratic forms. For a field F of characteristic not 2, define the fundamental ideal I in the Witt ring of quadratic forms over F to be the kernel of the homomorphism W(F) → Z/2 given by the dimension of a quadratic form, modulo 2. Milnor defined a homomorphism from the mod 2 Milnor K-group KnM(F)/2 to the quotient In/In+1, sending a symbol {a1, ..., an} to the class of the n-fold Pfister form[4]

 \langle \langle a_1, a_2, ... , a_n \rangle \rangle
 = \langle 1, -a_1 \rangle \otimes \langle 1, -a_2 \rangle \otimes ... \otimes \langle 1, -a_n \rangle.

Orlov, Vishik, and Voevodsky proved another statement called the Milnor conjecture, namely that this homomorphism KnM(F)/2 → In/In+1 is an isomorphism.[5]

References

  1. Gille & Szamuely (2006), p. 184.
  2. Mazza, Voevodsky, Weibel (2005), Theorem 5.1.
  3. Voevodsky (2011).
  4. Elman, Karpenko, Merkurjev (2008), sections 5 and 9.B.
  5. Orlov, Vishik, Voevodsky (2007).
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