🪡K-Theory Unit 14 – K–Theory in Algebraic Geometry and Number Theory

K-theory is a powerful mathematical framework that studies invariants of rings, schemes, and varieties using algebraic topology and category theory. It connects various branches of mathematics, providing a unified approach to vector bundles, projective modules, and algebraic cycles. Originating from Grothendieck's work on coherent sheaves, K-theory has evolved to include higher K-groups that capture refined structural information. It plays a crucial role in algebraic geometry and number theory, offering insights into algebraic cycles, motives, and arithmetic properties of schemes and number fields.

Study Guides for Unit 14

14.1

K-Theory of schemes and varieties

3 min read

14.2

Riemann-Roch theorems in algebraic geometry

3 min read

14.3

K-Theory and zeta functions

5 min read

14.4

Applications to arithmetic geometry

4 min read

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Foundations of K-Theory

K-theory studies invariants of mathematical objects (rings, schemes, varieties) using techniques from algebraic topology and category theory
Originated from Alexander Grothendieck's work on coherent sheaves and the Grothendieck group in the 1950s
Developed further by Hyman Bass, Michael Atiyah, and Friedrich Hirzebruch in the 1960s
Connects various branches of mathematics (algebraic geometry, number theory, topology, representation theory)
Provides a unified framework for studying vector bundles, projective modules, and algebraic cycles
- Vector bundles generalize the concept of a vector space over a manifold or algebraic variety
- Projective modules are a generalization of free modules and play a crucial role in non-commutative ring theory
K-groups are abelian groups associated with a mathematical object that capture its essential properties and structure
Higher K-groups ( $K_n$ for $n > 0$ ) contain more refined information about the object and its symmetries

Key Concepts and Definitions

Grothendieck group $K_0(X)$ of a scheme $X$ is the free abelian group generated by coherent sheaves on $X$ modulo the relation $[F] = [F'] + [F'']$ for every short exact sequence $0 \to F' \to F \to F'' \to 0$
Higher algebraic K-groups $K_n(R)$ $K_{n} (R)$ of a ring $R$ $R$ are defined using the Quillen's Q-construction or the Waldhausen's S-construction
- $K_1(R)$ is closely related to the group of units $R^\times$ and the Picard group $\mathrm{Pic}(R)$
- $K_2(R)$ is related to the Brauer group $\mathrm{Br}(R)$ and the Milnor K-theory
Bott periodicity establishes a periodic relationship between the K-groups of a topological space $X$ : $K_n(X) \cong K_{n+2}(X)$ for all $n \geq 0$
Chern character is a ring homomorphism from the K-theory of a smooth variety $X$ to its Chow groups tensored with $\mathbb{Q}$ : $\mathrm{ch}: K_0(X) \to \bigoplus_{i \geq 0} \mathrm{CH}^i(X) \otimes \mathbb{Q}$
Adams operations $\psi^k$ are ring endomorphisms of K-theory that generalize the k-th power map on line bundles and provide a way to study the structure of K-groups
Quillen's higher algebraic K-theory extends the notion of K-theory to exact categories and provides a powerful tool for studying the K-groups of schemes and rings

Algebraic K-Groups

$K_0(X)$ $K_{0} (X)$ of a scheme $X$ $X$ classifies coherent sheaves on $X$ $X$ up to stable equivalence
- For a smooth variety $X$ , $K_0(X)$ is isomorphic to the Grothendieck group of vector bundles on $X$
$K_1(R)$ $K_{1} (R)$ of a ring $R$ $R$ is the abelianization of the infinite general linear group $\mathrm{GL}(R)$ $GL (R)$
- For a field $F$ , $K_1(F)$ is isomorphic to the multiplicative group $F^\times$
- $K_1(R)$ captures information about the automorphisms of projective modules over $R$
$K_2(R)$ $K_{2} (R)$ is related to the Steinberg group $\mathrm{St}(R)$ $St (R)$ and the Milnor K-theory $K_2^M(R)$ $K_{2}^{M} (R)$
- For a field $F$ , there is a surjective homomorphism $K_2(F) \to K_2^M(F)$ whose kernel is the group of universal symbols
Higher K-groups $K_n(R)$ $K_{n} (R)$ for $n > 2$ $n > 2$ are defined using the Quillen's Q-construction or the Waldhausen's S-construction and have a rich structure
- They are related to the motivic cohomology groups and the Bloch's higher Chow groups
Milnor K-theory $K_*^M(F)$ $K_{*}^{M} (F)$ of a field $F$ $F$ is a graded ring defined using the tensor algebra of $F^\times$ $F^{\times}$ modulo the Steinberg relations
- There is a natural homomorphism from Milnor K-theory to Quillen's algebraic K-theory: $K_n^M(F) \to K_n(F)$ for all $n \geq 0$

K-Theory in Algebraic Geometry

K-theory provides a powerful tool for studying algebraic cycles and motives in algebraic geometry
For a smooth projective variety $X$ $X$ , the Grothendieck group $K_0(X)$ $K_{0} (X)$ is isomorphic to the Chow ring $\mathrm{CH}^*(X) \otimes \mathbb{Z}$ $CH^{*} (X) \otimes Z$
- The Chern character gives a ring isomorphism $K_0(X) \otimes \mathbb{Q} \cong \mathrm{CH}^*(X) \otimes \mathbb{Q}$
Algebraic K-theory of a scheme $X$ $X$ is related to its motivic cohomology groups $H^{p,q}(X, \mathbb{Z})$ $H^{p, q} (X, Z)$ via the motivic spectral sequence
- The motivic cohomology groups generalize the Chow groups and provide a way to study the arithmetic and geometric properties of $X$
Bloch's higher Chow groups $\mathrm{CH}^p(X, n)$ $CH^{p} (X, n)$ are a generalization of the usual Chow groups that capture information about the algebraic cycles on $X$ $X$
- There is a natural homomorphism from the higher Chow groups to the algebraic K-groups: $\mathrm{CH}^p(X, n) \to K_n(X)^{(p)}$ for all $p, n \geq 0$
Riemann-Roch theorem for algebraic K-theory relates the Euler characteristic of a coherent sheaf on a smooth projective variety $X$ to its Chern character in the Chow ring of $X$
Quillen-Lichtenbaum conjecture relates the algebraic K-theory of a scheme $X$ $X$ to its étale cohomology groups with finite coefficients
- It provides a connection between the algebraic and topological properties of $X$ and has important applications in arithmetic geometry

K-Theory in Number Theory

Algebraic K-theory of rings of integers and their quotients plays a crucial role in number theory
For a number field $F$ $F$ , the K-groups $K_n(\mathcal{O}_F)$ $K_{n} (O_{F})$ of its ring of integers $\mathcal{O}_F$ $O_{F}$ contain important arithmetic information
- $K_0(\mathcal{O}_F)$ is the Picard group of $\mathcal{O}_F$ and classifies the fractional ideals of $F$ up to principal ideals
- $K_1(\mathcal{O}_F)$ is the group of units $\mathcal{O}_F^\times$ and is related to the class number of $F$
- Higher K-groups $K_n(\mathcal{O}_F)$ for $n > 1$ are related to the Dedekind zeta function and the Tamagawa number of $F$
Quillen-Lichtenbaum conjecture for rings of integers relates the K-groups $K_n(\mathcal{O}_F)$ $K_{n} (O_{F})$ to the étale cohomology groups of $\mathrm{Spec}(\mathcal{O}_F)$ $Spec (O_{F})$ with finite coefficients
- It provides a way to study the arithmetic properties of $F$ using the tools of algebraic geometry and topology
Beilinson conjectures relate the values of the Dedekind zeta function $\zeta_F(s)$ $ζ_{F} (s)$ at integers $s \leq 0$ $s \leq 0$ to the K-groups and the motivic cohomology groups of $F$ $F$
- They provide a deep connection between the analytic and algebraic properties of number fields and have important applications in the study of special values of L-functions
Iwasawa theory studies the behavior of arithmetic objects (class groups, units, Galois modules) in towers of number fields using the tools of algebraic K-theory and p-adic analysis
- Main conjecture of Iwasawa theory relates the p-adic L-functions to the characteristic ideals of certain Iwasawa modules and has important applications in the study of cyclotomic fields and elliptic curves

Applications and Examples

Algebraic K-theory has applications in various branches of mathematics, including algebraic geometry, number theory, topology, and representation theory
In algebraic geometry, K-theory is used to study algebraic cycles, motives, and the arithmetic properties of schemes
- Example: Grothendieck's proof of the Grothendieck-Riemann-Roch theorem uses the K-theory of coherent sheaves and the Chern character
In number theory, K-theory is used to study the arithmetic properties of rings of integers, special values of L-functions, and the Galois modules
- Example: Quillen's computation of the K-groups of finite fields using the Adams operations and the Brauer lift
In topology, K-theory is used to study the classification of vector bundles, the Atiyah-Singer index theorem, and the Novikov conjecture
- Example: Atiyah-Hirzebruch spectral sequence relates the K-theory of a topological space to its singular cohomology
In representation theory, K-theory is used to study the representation rings of groups and the character formulas
- Example: Weyl character formula expresses the characters of irreducible representations of compact Lie groups in terms of the K-theory of flag varieties
Other examples include:
- Milnor's construction of the K-theory of fields and its relation to the quadratic forms and the Witt rings
- Suslin's proof of the Quillen-Lichtenbaum conjecture for fields using the motivic cohomology and the Bloch-Kato conjecture
- Voevodsky's proof of the Milnor conjecture on the Galois cohomology of fields using the motivic cohomology and the norm residue isomorphism theorem

Advanced Topics and Current Research

Motivic homotopy theory is a generalization of algebraic K-theory that studies the homotopy theory of schemes and motives using the language of model categories and infinity-categories
- Voevodsky's construction of the motivic stable homotopy category $\mathbf{SH}(k)$ over a field $k$ provides a powerful tool for studying the motivic cohomology and the algebraic K-theory of $k$
- Motivic Adams spectral sequence relates the motivic stable homotopy groups to the motivic cohomology groups and the algebraic K-groups
Trace methods in algebraic K-theory use the trace maps from the K-theory to the cyclic homology and the topological cyclic homology to study the K-groups of rings and schemes
- Topological cyclic homology $\mathrm{TC}(R)$ of a ring $R$ is a refinement of the Hochschild and cyclic homology that captures the arithmetic properties of $R$
- Trace methods have important applications in the study of the K-theory of local fields and the crystalline cohomology of schemes
Equivariant K-theory studies the K-theory of schemes and stacks with group actions using the tools of equivariant homotopy theory and representation theory
- Atiyah-Segal completion theorem relates the equivariant K-theory of a compact Lie group $G$ to the representation ring of $G$
- Equivariant K-theory has important applications in the study of the K-theory of quotient stacks and the geometric representation theory
K-theory of non-commutative rings and categories is a generalization of the classical K-theory that studies the K-groups of non-commutative rings, exact categories, and triangulated categories
- Waldhausen's S-construction provides a way to define the K-theory of categories with cofibrations and weak equivalences
- K-theory of non-commutative rings has important applications in the study of the K-theory of group rings, the cyclic homology of algebras, and the classification of C*-algebras
Current research in algebraic K-theory focuses on the following topics:
- Computation of the K-groups of rings and schemes using the trace methods, the motivic homotopy theory, and the equivariant techniques
- Study of the arithmetic properties of the K-groups of rings of integers and their relation to the special values of L-functions and the Galois modules
- Applications of K-theory to the study of the motivic cohomology, the algebraic cycles, and the motives in algebraic geometry
- Generalization of K-theory to the non-commutative settings, such as the K-theory of dg-categories, the K-theory of ring spectra, and the K-theory of stable infinity-categories

Problem-Solving Techniques

Computation of K-groups using the Quillen's Q-construction or the Waldhausen's S-construction
- Example: Compute the K-groups of a finite field $\mathbb{F}_q$ using the Quillen's Q-construction and the Adams operations
Use of the long exact sequences and the spectral sequences to compute the K-groups of schemes and rings
- Example: Use the localization sequence to compute the K-groups of a scheme $X$ in terms of the K-groups of its closed subschemes and their complements
Application of the Chern character and the Adams operations to study the structure of K-groups
- Example: Use the Chern character to decompose the K-theory of a smooth projective variety into the direct sum of its Chow groups tensored with $\mathbb{Q}$
Use of the trace methods and the descent techniques to compute the K-groups of rings and schemes
- Example: Use the trace map from the K-theory to the topological cyclic homology to compute the K-groups of a local field
Reduction of the computation of K-groups to the study of the motivic cohomology and the algebraic cycles using the motivic spectral sequence
- Example: Use the motivic spectral sequence to express the K-groups of a smooth projective variety in terms of its motivic cohomology groups and the Adams eigenspaces
Use of the equivariant techniques and the representation theory to study the K-theory of group actions and quotient stacks
- Example: Use the Atiyah-Segal completion theorem to compute the equivariant K-theory of a compact Lie group in terms of its representation ring
Application of the categorical and the homotopical methods to study the K-theory of non-commutative rings and categories
- Example: Use the Waldhausen's S-construction to define the K-theory of a triangulated category and study its properties using the tools of homotopy theory
Use of the computational tools, such as the computer algebra systems and the programming languages, to perform explicit calculations and verify conjectures
- Example: Use the SageMath or the Macaulay2 to compute the K-groups of a given ring or scheme and compare the results with the theoretical predictions