Milnor K-theory

In mathematics, Milnor K-theory^[1] is an algebraic invariant (denoted ${\displaystyle K_{\ast }(F)}$ for a field ${\displaystyle F}$) defined by Template:Harvs as an attempt to study higher algebraic K-theory in the special case of fields. It was hoped this would help illuminate the structure for algebraic Template:Nowrap and give some insight about its relationships with other parts of mathematics, such as Galois cohomology and the Grothendieck–Witt ring of quadratic forms. Before Milnor K-theory was defined, there existed ad-hoc definitions for ${\displaystyle K_1}$ and ${\displaystyle K_2}$. Fortunately, it can be shown Milnor Template:Nowrap is a part of algebraic Template:Nowrap, which in general is the easiest part to compute.^[2]

After the definition of the Grothendieck group ${\displaystyle K(R)}$ of a commutative ring, it was expected there should be an infinite set of invariants ${\displaystyle K_i(R)}$ called higher Template:Nowrap groups, from the fact there exists a short exact sequence

${\displaystyle K(R,I)\to K(R)\to K(R/I)\to 0}$

which should have a continuation by a long exact sequence. Note the group on the left is relative Template:Nowrap. This led to much study and as a first guess for what this theory would look like, Milnor gave a definition for fields. His definition is based upon two calculations of what higher Template:Nowrap "should" look like in degrees ${\displaystyle 1}$ and ${\displaystyle 2}$. Then, if in a later generalization of algebraic Template:Nowrap was given, if the generators of ${\displaystyle K_{\ast }(R)}$ lived in degree ${\displaystyle 1}$ and the relations in degree ${\displaystyle 2}$, then the constructions in degrees ${\displaystyle 1}$ and ${\displaystyle 2}$ would give the structure for the rest of the Template:Nowrap ring. Under this assumption, Milnor gave his "ad-hoc" definition. It turns out algebraic Template:Nowrap ${\displaystyle K_{\ast }(R)}$ in general has a more complex structure, but for fields the Milnor Template:Nowrap groups are contained in the general algebraic Template:Nowrap groups after tensoring with ${\displaystyle \mathbb{Q}}$, i.e. ${\displaystyle K_n^M(F)\otimes \mathbb{Q}\subseteq K_n(F)\otimes \mathbb{Q}}$.^[3] It turns out the natural map ${\displaystyle \lambda :K_4^M(F)\to K_4(F)}$ fails to be injective for a global field ${\displaystyle F}$^{[3]pg 96}.

Note for fields the Grothendieck group can be readily computed as ${\displaystyle K_0(F)=\mathbb{Z}}$ since the only finitely generated modules are finite-dimensional vector spaces. Also, Milnor's definition of higher Template:Nowrap depends upon the canonical isomorphism

${\displaystyle l:K_1(F)\to F^{\ast }}$

(the group of units of ${\displaystyle F}$) and observing the calculation of K₂ of a field by Hideya Matsumoto, which gave the simple presentation

${\displaystyle K_2(F)=\frac{F^{\ast }\otimes F^{\ast }}{\{l(a)\otimes l(1-a):a\ne 0,1\}}}$

for a two-sided ideal generated by elements ${\displaystyle l(a)\otimes l(a-1)}$, called Steinberg relations. Milnor took the hypothesis that these were the only relations, hence he gave the following "ad-hoc" definition of Milnor K-theory as

${\displaystyle K_n^M(F)=\frac{K_1(F)\otimes \cdots \otimes K_1(F)}{\{l(a_1)\otimes \cdots \otimes l(a_n):a_i+a_{i+1}=1\}}.}$

The direct sum of these groups is isomorphic to a tensor algebra over the integers of the multiplicative group ${\displaystyle K_1(F)\cong F^{\ast }}$ modded out by the two-sided ideal generated by:

${\displaystyle \{l(a)\otimes l(1-a):0,1\ne a\in F\}}$

so

${\displaystyle {\displaystyle \underset{n=0}{\overset{\mathrm{\infty }}{⨁}}}{K}_n^M(F)\cong \frac{T^{\ast }(K_1^M(F))}{\{l(a)\otimes l(1-a):a\ne 0,1\}}}$

showing his definition is a direct extension of the Steinberg relations.

The graded module ${\displaystyle K_{\ast }^M(F)}$ is a graded-commutative ring^{[1]pg 1-3}.^[4] If we write

${\displaystyle (l(a_1)\otimes \cdots \otimes l(a_n))\cdot (l(b_1)\otimes \cdots \otimes l(b_m))}$

as

${\displaystyle l(a_1)\otimes \cdots \otimes l(a_n)\otimes l(b_1)\otimes \cdots \otimes l(b_m)}$

then for ${\displaystyle \xi \in K_i^M(F)}$ and ${\displaystyle \eta \in K_j^M(F)}$ we have

${\displaystyle \xi \cdot \eta =(-1{)}^{i\cdot j}\eta \cdot \xi .}$

From the proof of this property, there are some additional properties which fall out, like $${\displaystyle l(a{)}^2=l(a)l(-1)}$$ for ${\displaystyle l(a)\in K_1(F)}$ since ${\displaystyle l(a)l(-a)=0}$. Also, if ${\displaystyle a_1+\cdots +a_n}$ of non-zero fields elements equals ${\displaystyle 0,1}$, then $${\displaystyle l(a_1)\cdots l(a_n)=0}$$ There's a direct arithmetic application: ${\displaystyle -1\in F}$ is a sum of squares if and only if every positive dimensional ${\displaystyle K_n^M(F)}$ is nilpotent, which is a powerful statement about the structure of Milnor Template:Nowrap. In particular, for the fields ${\displaystyle \mathbb{Q}(i)}$, ${\displaystyle {\mathbb{Q}}_p(i)}$ with ${\displaystyle \sqrt{-1}\in ̸{\mathbb{Q}}_p}$, all of its Milnor Template:Nowrap are nilpotent. In the converse case, the field ${\displaystyle F}$ can be embedded into a real closed field, which gives a total ordering on the field.

One of the core properties relating Milnor K-theory to higher algebraic K-theory is the fact there exists natural isomorphisms $${\displaystyle K_n^M(F)\to {\text{CH}}^n(F,n)}$$ to Bloch's Higher chow groups which induces a morphism of graded rings $${\displaystyle K_{\ast }^M(F)\to {\text{CH}}^{\ast }(F,\ast )}$$ This can be verified using an explicit morphism^{[2]pg 181} $${\displaystyle \varphi :F^{\ast }\to {\text{CH}}^1(F,1)}$$ where $${\displaystyle \varphi (a)\varphi (1-a)=0\text{in}{\text{CH}}^2(F,2)\text{for}a,1-a\in F^{\ast }}$$ This map is given by $${\displaystyle \begin{array}{cc}\{1\}& \mapsto 0\in {\text{CH}}^1(F,1)\\ \{a\}& \mapsto [a]\in {\text{CH}}^1(F,1)\end{array}}$$ for ${\displaystyle [a]}$ the class of the point ${\displaystyle [a:1]\in {\mathbb{P}}_F^1-\{0,1,\mathrm{\infty }\}}$ with ${\displaystyle a\in F^{\ast }-\{1\}}$. The main property to check is that ${\displaystyle [a]+[1/a]=0}$ for ${\displaystyle a\in F^{\ast }-\{1\}}$ and ${\displaystyle [a]+[b]=[ab]}$. Note this is distinct from ${\displaystyle [a]\cdot [b]}$ since this is an element in ${\displaystyle {\text{CH}}^2(F,2)}$. Also, the second property implies the first for ${\displaystyle b=1/a}$. This check can be done using a rational curve defining a cycle in ${\displaystyle C^1(F,2)}$ whose image under the boundary map ${\displaystyle \partial }$ is the sum ${\displaystyle [a]+[b]-[ab]}$for ${\displaystyle ab\ne 1}$, showing they differ by a boundary. Similarly, if ${\displaystyle ab=1}$ the boundary map sends this cycle to ${\displaystyle [a]-[1/a]}$, showing they differ by a boundary. The second main property to show is the Steinberg relations. With these, and the fact the higher Chow groups have a ring structure $${\displaystyle {\text{CH}}^p(F,q)\otimes {\text{CH}}^r(F,s)\to {\text{CH}}^{p+r}(F,q+s)}$$ we get an explicit map $${\displaystyle K_{\ast }^M(F)\to {\text{CH}}^{\ast }(F,\ast )}$$ Showing the map in the reverse direction is an isomorphism is more work, but we get the isomorphisms $${\displaystyle K_n^M(F)\to {\text{CH}}^n(F,n)}$$ We can then relate the higher Chow groups to higher algebraic K-theory using the fact there are isomorphisms $${\displaystyle K_n(X)\otimes \mathbb{Q}\cong \underset{p}{⨁}{\text{CH}}^p(X,n)\otimes \mathbb{Q}}$$ giving the relation to Quillen's higher algebraic K-theory. Note that the maps

${\displaystyle K_n^M(F)\to K_n(F)}$

from the Milnor K-groups of a field to the Quillen K-groups, which is an isomorphism for ${\displaystyle n\le 2}$ but not for larger n, in general. For nonzero elements ${\displaystyle a_1,\dots ,a_n}$ in F, the symbol ${\displaystyle \{a_1,\dots ,a_n\}}$ in ${\displaystyle K_n^M(F)}$ means the image of ${\displaystyle a_1\otimes \cdots \otimes a_n}$ in the tensor algebra. Every element of Milnor K-theory can be written as a finite sum of symbols. The fact that ${\displaystyle \{a,1-a\}=0}$ in ${\displaystyle K_2^M(F)}$ for ${\displaystyle a\in F\setminus \{0,1\}}$ is sometimes called the Steinberg relation.

In motivic cohomology, specifically motivic homotopy theory, there is a sheaf ${\displaystyle K_{n,A}}$ representing a generalization of Milnor K-theory with coefficients in an abelian group ${\displaystyle A}$. If we denote ${\displaystyle A_{tr}(X)={\mathbb{Z}}_{tr}(X)\otimes A}$ then we define the sheaf ${\displaystyle K_{n,A}}$ as the sheafification of the following pre-sheaf^{[5]pg 4} $${\displaystyle K_{n,A}^{pre}:U\mapsto A_{tr}({𝔸}^n)(U)/A_{tr}({𝔸}^n-\{0\})(U)}$$ Note that sections of this pre-sheaf are equivalent classes of cycles on ${\displaystyle U\times {𝔸}^n}$ with coefficients in ${\displaystyle A}$ which are equidimensional and finite over ${\displaystyle U}$ (which follows straight from the definition of ${\displaystyle {\mathbb{Z}}_{tr}(X)}$). It can be shown there is an ${\displaystyle {𝔸}^1}$-weak equivalence with the motivic Eilenberg-Maclane sheaves ${\displaystyle K(A,2n,n)}$ (depending on the grading convention).

For a finite field ${\displaystyle F={𝔽}_q}$, ${\displaystyle K_1^M(F)}$ is a cyclic group of order ${\displaystyle q-1}$ (since is it isomorphic to ${\displaystyle {𝔽}_q^{\ast }}$), so graded commutativity gives $${\displaystyle l(a)\cdot l(b)=-l(b)\cdot l(a)}$$ hence $${\displaystyle l(a{)}^2=-l(a{)}^2}$$ Because ${\displaystyle K_2^M(F)}$ is a finite group, this implies it must have order ${\displaystyle \le 2}$. Looking further, ${\displaystyle 1}$ can always be expressed as a sum of quadratic non-residues, i.e. elements ${\displaystyle a,b\in F}$ such that ${\displaystyle [a],[b]\in F/F^{\times 2}}$ are not equal to ${\displaystyle 0}$, hence ${\displaystyle a+b=1}$ showing ${\displaystyle K_2^M(F)=0}$. Because the Steinberg relations generate all relations in the Milnor K-theory ring, we have ${\displaystyle K_n^M(F)=0}$ for ${\displaystyle n>2}$.

For the field of real numbers ${\displaystyle ℝ}$ the Milnor Template:Nowrap groups can be readily computed. In degree ${\displaystyle n}$ the group is generated by $${\displaystyle K_n^M(ℝ)=\{(-1{)}^n,l(a_1)\cdots l(a_n):a_1,\dots ,a_n>0\}}$$ where ${\displaystyle (-1{)}^n}$ gives a group of order ${\displaystyle 2}$ and the subgroup generated by the ${\displaystyle l(a_1)\cdots l(a_n)}$ is divisible. The subgroup generated by ${\displaystyle (-1{)}^n}$ is not divisible because otherwise it could be expressed as a sum of squares. The Milnor K-theory ring is important in the study of motivic homotopy theory because it gives generators for part of the motivic Steenrod algebra.^[6] The others are lifts from the classical Steenrod operations to motivic cohomology.

${\displaystyle K_2^M(ℂ)}$ is an uncountable uniquely divisible group.^[7] Also, ${\displaystyle K_2^M(ℝ)}$ is the direct sum of a cyclic group of order 2 and an uncountable uniquely divisible group; ${\displaystyle K_2^M({\mathbb{Q}}_p)}$ is the direct sum of the multiplicative group of ${\displaystyle {𝔽}_p}$ and an uncountable uniquely divisible group; ${\displaystyle K_2^M(\mathbb{Q})}$ is the direct sum of the cyclic group of order 2 and cyclic groups of order ${\displaystyle p-1}$ for all odd prime ${\displaystyle p}$. For ${\displaystyle n\ge 3}$, ${\displaystyle K_n^M(\mathbb{Q})\cong \mathbb{Z}/2}$. The full proof is in the appendix of Milnor's original paper.^[1] Some of the computation can be seen by looking at a map on ${\displaystyle K_2^M(F)}$ induced from the inclusion of a global field ${\displaystyle F}$ to its completions ${\displaystyle F_v}$, so there is a morphism$${\displaystyle K_2^M(F)\to \underset{v}{⨁}{K}_2^M(F_v)/(\text{max. divis. subgr.})}$$ whose kernel finitely generated. In addition, the cokernel is isomorphic to the roots of unity in ${\displaystyle F}$.

In addition, for a general local field ${\displaystyle F}$ (such as a finite extension ${\displaystyle K/{\mathbb{Q}}_p}$), the Milnor Template:Nowrap ${\displaystyle K_n^M(F)}$ are divisible.

There is a general structure theorem computing ${\displaystyle K_n^M(F(t))}$ for a field ${\displaystyle F}$ in relation to the Milnor Template:Nowrap of ${\displaystyle F}$ and extensions ${\displaystyle F[t]/(\pi )}$ for non-zero primes ideals ${\displaystyle (\pi )\in \text{Spec}(F[t])}$. This is given by an exact sequence $${\displaystyle 0\to K_n^M(F)\to K_n^M(F(t))\stackrel{{\partial }_{\pi }}{\to }\underset{(\pi )\in \text{Spec}(F[t])}{⨁}{K}_{n-1}F[t]/(\pi )\to 0}$$ where ${\displaystyle {\partial }_{\pi }:K_n^M(F(t))\to K_{n-1}F[t]/(\pi )}$ is a morphism constructed from a reduction of ${\displaystyle F}$ to ${\displaystyle \underset{v}{\bar{F}}}$ for a discrete valuation ${\displaystyle v}$. This follows from the theorem there exists only one homomorphism $${\displaystyle \partial :K_n^M(F)\to K_{n-1}^M(\bar{F})}$$ which for the group of units ${\displaystyle U\subset F}$ which are elements have valuation ${\displaystyle 0}$, having a natural morphism $${\displaystyle U\to \underset{v}{\overset{\ast }{\bar{F}}}}$$ where ${\displaystyle u\mapsto \bar{u}}$ we have $${\displaystyle \partial (l(\pi )l(u_2)\cdots l(u_n))=l(\underset{2}{\bar{u}})\cdots l(\underset{n}{\bar{u}})}$$ where ${\displaystyle \pi }$ a prime element, meaning ${\displaystyle {\text{Ord}}_v(\pi )=1}$, and $${\displaystyle \partial (l(u_1)\cdots l(u_n))=0}$$ Since every non-zero prime ideal ${\displaystyle (\pi )\in \text{Spec}(F[t])}$ gives a valuation ${\displaystyle v_{\pi }:F(t)\to F[t]/(\pi )}$, we get the map ${\displaystyle {\partial }_{\pi }}$ on the Milnor K-groups.

Milnor K-theory plays a fundamental role in higher class field theory, replacing ${\displaystyle K_1^M(F)=F^{\times }}$ in the one-dimensional class field theory.

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

${\displaystyle K_n^M(F)\cong H^n(F,\mathbb{Z}(n))}$

of the Milnor K-theory of a field with a certain motivic cohomology group.^[8] In this sense, the apparently ad hoc definition of Milnor Template:Nowrap 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 Template:Nowrap to Galois cohomology or étale cohomology:

${\displaystyle K_n^M(F)/r\cong H_{\mathrm{e}\mathrm{t}}^n(F,\mathbb{Z}/r(n)),}$

for any positive integer r invertible in the field F. This conjecture was proved by Vladimir Voevodsky, with contributions by Markus Rost and others.^[9] This includes the theorem of Alexander Merkurjev and Andrei Suslin as well as the Milnor conjecture as special cases (the cases when ${\displaystyle n=2}$ and ${\displaystyle r=2}$, 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 ${\displaystyle W(F)\to \mathbb{Z}/2}$ given by the dimension of a quadratic form, modulo 2. Milnor defined a homomorphism:

${\displaystyle \{\begin{array}{c}{K}_n^M(F)/2\to I^n/I^{n+1}\\ \{a_1,\dots ,a_n\}\mapsto ⟨⟨a_1,\dots ,a_n⟩⟩=⟨1,-a_1⟩\otimes \cdots \otimes ⟨1,-a_n⟩\end{array}}$

where ${\displaystyle ⟨⟨a_1,a_2,\dots ,a_n⟩⟩}$ denotes the class of the n-fold Pfister form.^[10]

Dmitri Orlov, Alexander Vishik, and Voevodsky proved another statement called the Milnor conjecture, namely that this homomorphism ${\displaystyle K_n^M(F)/2\to I^n/I^{n+1}}$ is an isomorphism.^[11]

• Azumaya algebra
• Motivic homotopy theory

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• Some aspects of the functor ${\displaystyle K_2}$ of fields
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