nLab Morava K-theory

Redirected from "Morava K-theories".

Morava K-theory

Context

Cohomology

Stable Homotopy theory

Higher algebra

Morava K-theory

Idea
Definition

Construction from complex cobordism
Axiomatic characterization

Properties

Universal characterization
Ring structure
As $A_\infty$ -fields
As the primes in the $\infty$ -category of spectra
Relation to chromatic homotopy theory
Relation to Bousfield lattice
Orientation
$\infty$ -Group rings and twists

Related concepts
References

Idea

For each prime $p$ , the Morava K-theories are a tower $\{K(n)\}_{n \in \mathbb{N}}$ of complex oriented cohomology theories whose coefficient ring is

\pi_\bullet\left(K\left(n\right)\right) \simeq \mathbb{F}_p [v_n, v_n^{-1}]

where $v_n$ is in degree $2(p^n-1)$ .

Hence with $p = 2$ for $n = 1$ $v_1$ is a Bott element of degree 2 and $K(1)$ is closely related to complex K-theory, while for $n= 2$ $v_2$ is then a Bott element of degree 6 and $K(2)$ is closely related to elliptic cohomology.

There is also integral Morava K-theory which instead has coefficient ring

\pi_\bullet\left(K\left(n\right)\right) \simeq \mathbb{Z}_{(p)} [v_n, v_n^{-1}] \,,

where $\mathbb{Z}_{(p)}$ is the p-adic integers.

Integral Morava K-theory can be obtained as a localization of a quotient $MU/I$ of complex cobordism cohomology theory $MU$ (Buhné 11).

Definition

We need the following standard notation throughout this entry.

Definition

For $p \in \mathbb{N}$ a prime number, we write

$\mathbb{F}_p = \mathbb{Z}/(p)$ for the field with $p$ elements;
$\mathbb{Z}_{(p)}$ for the localization ring of the integers at $p$ ;
$\mathbb{Z}_p$ for the p-adic integers.

Construction from complex cobordism

(e.g. Lurie 10, lecture 22, def. 5)

Axiomatic characterization

Proposition/Definition

For each prime integer $p$ the Morava K-theories are the sequences

\big\{ K(n) \big\}_{n \in \mathbb{N}}

of multiplicative generalized cohomology/homology theories with the following properties:

$K(0)_\ast(X)=H_\ast(X;\mathbb{Q})$ and $\overline{K(0)}_\ast(X)=0$ when $\overline{H}_\ast(X)$ is all torsion.
$K(1)_\ast(X)$ is one of $p-1$ isomorphic summands of mod- $p$ complex topological K-theory.
$K(0)_\ast(pt.)=\mathbb{Q}$ and for $n\neq 0$ , $K(n)_\ast(pt.)=\mathbb{F}_p[v_n,v_n^{-1}]$ where $\vert v_n\vert=2p^n-2$ .

(This ring is a graded field in the sense that every graded module over it is free. $K(n)_\ast(X)$ is a module over $K(n)_\ast(pt.)$ , see below)
There is a Künneth isomorphism: $K(n)_\ast(X\times Y)\cong K(n)_\ast(X)\otimes_{K(n)_\ast(pt.)}K(n)_\ast(Y).$
Let $X$ be a p-local finite CW-complex. If $\overline{K(n)}_\ast(X)$ vanishes then so does $\overline{K(n-1)}_\ast(X)$ .
If $X$ is as above, then $\overline{K(n)}_\ast(X)=K(n)_\ast(pt.)\otimes \overline{H}_\ast(X;\mathbb{Z}/(p))$ for $n$ sufficiently large.

(Ravenel 1992, Prop. 1.5.2)

Remark

Due to the third point in , one may regard $K(n)$ as a ∞-field among the A-infinity rings. See below.

Properties

Universal characterization

Proposition

For each prime number $p$ and each $n \in \mathbb{N}$ , the Morava K-theory $K(n)$ is, up to equivalence, the unique spectrum underlying an homotopy associative spectrum which is

complex oriented;
whose formal group has height exactly $n$ ;
whose homotopy groups are $\pi_\bullet \simeq \mathbb{F}_p[v_n^\pm]$ . (with $v_n$ defined as at height).

For instance (Lurie, lecture 24, prop. 11).

Ring structure

Proposition

$K(n)$ admits the structure of an A-∞ algebra, in fact of an $MU_{(p)}$ -A-∞ algebra.

Due to Robinson (and Andrew Baker at $p = 2$ ). (See e.g. Lurie 10, lecture 22, lemma 2)

Remark

With the exception of the extreme case of $n=0$ , the fields $K(n)$ do not admit E-∞-ring multiplicative structures. However, when $p\neq 2$ , the multiplication is homotopy commutative. For $p = 2$ it is not even homotopy commutative. Nevertheless, for many spaces $X$ , the $K(n)$ -generalized cohomology at the prime $2$ of $X$ forms a commutative ring.

(e.g. Lurie 10, lecture 22, warning 6)

As $A_\infty$ -fields

Proposition

If $E$ is an ∞-field and $E \otimes K(n) \neq 0$ , then $E$ admits the structure of a $K(n)$ -module.

This appears for instance as (Lurie, lecture 24, prop. 9, remark 13)

Remark

This means that the Morava $A_\infty$ -rings $K(n)$ are essentially the only ∞-fields in the stable homotopy category.

See (Lurie, lecture 24, remark 13)

As the primes in the $\infty$ -category of spectra

The Morava K-theories label the prime spectrum of a symmetric monoidal stable (∞,1)-category of the (∞,1)-category of spectra for p-local and finite spectra . This is the content of the thick subcategory theorem.

Relation to chromatic homotopy theory

The layers in the chromatic tower capture periodic phenomena in stable homotopy theory, corresponding to the Morava K-theory $E_\infty$ -fields.

Specifically the Bousfield localization of spectra $L_{K(n)}$ acts on complex oriented cohomology theories like completion along the locally closed substack

\mathcal{M}^n_{FG} \hookrightarrow \mathcal{M}_{FG}

of the moduli stack of formal groups at those of height $n$ .

(Lurie 10, lecture 29)

chromatic homotopy theory

chromatic level	complex oriented cohomology theory	E-∞ ring/A-∞ ring	real oriented cohomology theory
0	ordinary cohomology	Eilenberg-MacLane spectrum $H \mathbb{Z}$	HZR-theory
	0th Morava K-theory	$K(0)$
1	complex K-theory	complex K-theory spectrum $KU$	KR-theory
	first Morava K-theory	$K(1)$
	first Morava E-theory	$E(1)$
2	elliptic cohomology	elliptic spectrum $Ell_E$
	second Morava K-theory	$K(2)$
	second Morava E-theory	$E(2)$
	algebraic K-theory of KU	$K(KU)$
3 …10	K3 cohomology	K3 spectrum
$n$	$n$ th Morava K-theory	$K(n)$
	$n$ th Morava E-theory	$E(n)$	BPR-theory
$n+1$	algebraic K-theory applied to chrom. level $n$	$K(E_n)$ (red-shift conjecture)
$\infty$	complex cobordism cohomology	MU	MR-theory

Relation to Bousfield lattice

It is known that in the Bousfield lattice of the stable homotopy category, the Bousfield classes of the Morava K-theories are minimal. It is conjectured by Mark Hovey and John Palmieri that the Boolean algebra contained in the Bousfield lattice is atomic and generated by the Morava K-theories and the spectra $A(n)$ which measure the failure of the telescope conjecture.

Orientation

The orientation of integral Morava K-theory is discussed in (Sati-Kriz 04, Buhné 11). It is essentially given by the vanishing of the seventh integral Stiefel-Whitney class $W_7$ .

Notice that this is in higher analogy to how orientation in complex K-theory is given by the vanishing third integral Stiefel-Whitney class $W_3$ (spin^c-structure).

$\infty$ -Group rings and twists

Write $gl_1(K(n))$ for the ∞-group of units of the (a) Morava K-theory spectrum

Proposition

For $p = 2$ and all $n \in \mathbb{N}$ , there is an equivalence

Maps(B^{n+1}U(1), B gl_1(K(n))) \simeq \mathbb{Z}_2

between

the mapping space from the classifying space for circle (n+1)-bundles to the delooping of the ∞-group of units of $K(n)$

and

the 2-adic integers.

(Sati-Westerland 11, theorem 1)

Remark

By the discussion at (∞,1)-vector bundle this means that for each such map there is a type of twist of Morava K-theory (at $p = 2$ ).

Related concepts

References

Morava K-theory originates in unpublished preprints by Jack Morava in the early 1970s.

A first published account appears in (see at Johnson-Wilson spectrum):

David Copeland Johnson, W. Stephen Wilson, BP operations and Morava’s extraordinary K-theories, Math. Z. 144 (1): 55−75, (1975) (pdf)

nLab Morava K-theory

Context

Cohomology

Special and general types

Special notions

Variants

Extra structure

Operations

Theorems

Stable Homotopy theory

Ingredients

Contents

Higher algebra

Algebraic theories

Algebras and modules

Higher algebras

Model category presentations

Geometry on formal duals of algebras

Theorems

Morava K-theory

Idea

Definition

Definition

Construction from complex cobordism

Axiomatic characterization

Proposition/Definition

Remark

Properties

Universal characterization

Proposition

Ring structure

Proposition

Remark

As A ∞A_\infty-fields

Proposition

Remark

As the primes in the ∞\infty-category of spectra

Relation to chromatic homotopy theory

Relation to Bousfield lattice

Orientation

∞\infty-Group rings and twists

Proposition

Remark

Related concepts

References

As $A_\infty$ -fields

As the primes in the $\infty$ -category of spectra

$\infty$ -Group rings and twists