Eilenberg–Ganea theorem

In mathematics, particularly in homological algebra and algebraic topology, the Eilenberg–Ganea theorem states for every finitely generated group G with certain conditions on its cohomological dimension (namely $3\leq \operatorname {cd} (G)\leq n$ ), one can construct an aspherical CW complex X of dimension n whose fundamental group is G. The theorem is named after Polish mathematician Samuel Eilenberg and Romanian mathematician Tudor Ganea. The theorem was first published in a short paper in 1957 in the Annals of Mathematics.^[1]

Definitions

Group cohomology: Let $G$ be a group and let $X=K(G,1)$ be the corresponding

Eilenberg−MacLane space. Then we have the following singular chain complex which is a free resolution

of

\mathbb {Z}

over the group ring

\mathbb {Z} [G]

(where

\mathbb {Z}

is a trivial

\mathbb {Z} [G]

-module):

\cdots \xrightarrow {\delta _{n}+1} C_{n}(E)\xrightarrow {\delta _{n}} C_{n-1}(E)\rightarrow \cdots \rightarrow C_{1}(E)\xrightarrow {\delta _{1}} C_{0}(E)\xrightarrow {\varepsilon } \mathbb {Z} \rightarrow 0,

where $E$ is the universal cover of $X$ and $C_{k}(E)$ is the free abelian group generated by the singular $k$ -chains on $E$ . The group cohomology of the group $G$ with coefficient in a $\mathbb {Z} [G]$ -module $M$ is the cohomology of this chain complex with coefficients in $M$ , and is denoted by $H^{*}(G,M)$ .

Cohomological dimension: A group $G$ has cohomological dimension $n$ with coefficients in $\mathbb {Z}$ (denoted by $\operatorname {cd} _{\mathbb {Z} }(G)$ ) if

n=\sup\{k:{\text{There exists a }}\mathbb {Z} [G]{\text{ module }}M{\text{ with }}H^{k}(G,M)\neq 0\}.

Fact: If $G$ has a

projective resolution

of length at most

n

, i.e.,

\mathbb {Z}

as trivial

\mathbb {Z} [G]

module has a projective resolution of length at most

n

if and only if

H_{\mathbb {Z} }^{i}(G,M)=0

for all

\mathbb {Z}

-modules

M

and for all

i>n

.^{[citation needed]}

Therefore, we have an alternative definition of cohomological dimension as follows,

The cohomological dimension of G with coefficient in $\mathbb {Z}$ is the smallest n (possibly infinity) such that G has a projective resolution of length n, i.e., $\mathbb {Z}$ has a projective resolution of length n as a trivial $\mathbb {Z} [G]$ module.

Eilenberg−Ganea theorem

Let $G$ be a finitely presented group and $n\geq 3$ be an integer. Suppose the cohomological dimension of $G$ with coefficients in $\mathbb {Z}$ is at most $n$ , i.e., $\operatorname {cd} _{\mathbb {Z} }(G)\leq n$ . Then there exists an $n$ -dimensional aspherical CW complex $X$ such that the fundamental group of $X$ is $G$ , i.e., $\pi _{1}(X)=G$ .

Converse

Converse of this theorem is an consequence of cellular homology, and the fact that every free module is projective.

Theorem: Let X be an aspherical n-dimensional CW complex with π₁(X) = G, then cd_Z(G) ≤ n.

Related results and conjectures

For n = 1 the result is one of the consequences of Stallings theorem about ends of groups.^[2]

Theorem: Every finitely generated group of cohomological dimension one is free.

For $n=2$ the statement is known as the Eilenberg–Ganea conjecture.

Eilenberg−Ganea Conjecture: If a group G has cohomological dimension 2 then there is a 2-dimensional aspherical CW complex X with $\pi _{1}(X)=G$ .

It is known that given a group G with $\operatorname {cd} _{\mathbb {Z} }(G)=2$ , there exists a 3-dimensional aspherical CW complex X with $\pi _{1}(X)=G$ .

References

MR 0085510
.

MR0228573

S2CID 120422255
..

ISBN 0-387-90688-6

Retrieved from "https://en.wikipedia.org/w/index.php?title=Eilenberg–Ganea_theorem&oldid=1168071250"

[1] MR 0085510
.

[2] MR0228573

[1]

[2]

Definitions

Eilenberg−Ganea theorem

Converse

Related results and conjectures

See also

References