Cohomological dimension explained

In abstract algebra, cohomological dimension is an invariant of a group which measures the homological complexity of its representations. It has important applications in geometric group theory, topology, and algebraic number theory.

Cohomological dimension of a group

As most cohomological invariants, the cohomological dimension involves a choice of a "ring of coefficients" R, with a prominent special case given by

R=\Z

, the ring of integers. Let G be a discrete group, R a non-zero ring with a unit, and

RG

the group ring. The group G has cohomological dimension less than or equal to n, denoted

\operatorname{cd}R(G)\len

, if the trivial

RG

-module R has a projective resolution of length n, i.e. there are projective

RG

-modules

P0,...,Pn

and

RG

-module homomorphisms

dk\colonPk\toPk-1(k=1,...,n)

and

d0\colonP0\toR

, such that the image of

dk

coincides with the kernel of

dk-1

for

k=1,...,n

and the kernel of

dn

is trivial.

Equivalently, the cohomological dimension is less than or equal to n if for an arbitrary

RG

-module M, the cohomology of G with coefficients in M vanishes in degrees

k>n

, that is,

Hk(G,M)=0

whenever

k>n

. The p-cohomological dimension for prime p is similarly defined in terms of the p-torsion groups

Hk(G,M){p}

.[1]

The smallest n such that the cohomological dimension of G is less than or equal to n is the cohomological dimension of G (with coefficients R), which is denoted

n=\operatorname{cd}R(G)

.

A free resolution of

\Z

can be obtained from a free action of the group G on a contractible topological space X. In particular, if X is a contractible CW complex of dimension n with a free action of a discrete group G that permutes the cells, then

\operatorname{cd}\Z(G)\len

.

Examples

In the first group of examples, let the ring R of coefficients be

\Z

.

\Z

. More generally, the same is true for groups with nontrivial torsion.

Now consider the case of a general ring R.

RG

is semisimple. Thus a finite group has cohomological dimension 0 if and only if its order (or, equivalently, the orders of its elements) is invertible in R.

R=\Z

, Martin Dunwoody proved that a group has cohomological dimension at most one over an arbitrary ring R if and only if it is the fundamental group of a connected graph of finite groups whose orders are invertible in R.

Cohomological dimension of a field

The p-cohomological dimension of a field K is the p-cohomological dimension of the Galois group of a separable closure of K.[4] The cohomological dimension of K is the supremum of the p-cohomological dimension over all primes p.[5]

Examples

\hat{\Z}

and so has cohomological dimension 1.[7]

k((t))

over an algebraically closed field k of characteristic zero also has absolute Galois group isomorphic to

\hat{\Z}

and so cohomological dimension 1.[7]

See also

References

. Kenneth Brown (mathematician). Cohomology of groups . Corrected reprint of the 1982 original . . 87 . . New York . 1994 . 1324339 . 0-387-90688-6 . 0584.20036 .

. Jean-Pierre Serre . Galois cohomology . . 1997. 3-540-61990-9 . 0902.12004 .

Notes and References

  1. Gille & Szamuely (2006) p.136
  2. Book: Baumslag, Gilbert. Gilbert Baumslag

    . Gilbert Baumslag. Topics in Combinatorial Group Theory. 2012. 16. Springer Basel AG.

  3. Gruenberg. Karl W.. Karl W. Gruenberg. Review of Homology in group theory by Urs Stammbach. . 81. 1975. 851–854. 10.1090/S0002-9904-1975-13858-4. free.
  4. Shatz (1972) p.94
  5. Gille & Szamuely (2006) p.138
  6. Gille & Szamuely (2006) p.139
  7. Gille & Szamuely (2006) p.140