Kunneth formula for homology: Difference between revisions

Latest revision as of 15:32, 27 July 2011

Statement

Suppose $X$ and $Y$ are topological spaces. We then have the following relation for the homology groups of $X$ , $Y$ , and the product space $X \times Y$ .

For any $n \geq 0$ and any module $M$ over a principal ideal domain $R$ for coefficients, we have:

$H_{n} (X \times Y; M) ≅ (\sum_{i + j = n} H_{i} (X; M) \otimes H_{j} (Y; M)) \oplus (\sum_{p + q = n - 1} T o r (H_{p} (X; M), H_{q} (Y; M)))$

Here, $T o r$ is torsion of modules over the ring $R$ .

Related facts

Kunneth formula for cohomology
Universal coefficients theorem for homology
Universal coefficients theorem for cohomology
Dual universal coefficients theorem (computes cohomology in terms of homology)

Particular cases

Case of free modules

If all the homology groups $H_{i} (X; M), 0 \leq i \leq n - 1$ are free (or more generally torsion-free) modules over $R$ , and/or all the homology groups $H_{j} (X; M), 0 \leq j \leq n - 1$ , are free (or more generally torsion-free) modules over $R$ , then all the torsion part vanishes and we get:

$H_{n} (X \times Y; M) ≅ \sum_{i + j = n} H_{i} (X; M) \otimes H_{j} (Y; M)$

In particular, if all $H_{i} (X; M)$ and $H_{j} (Y; M)$ are free modules over $R$ and $b_{i} (X; M)$ and $b_{j} (Y; M)$ denote the respective free ranks, and all these are finite, we obtain that:

$b_{n} (X \times Y; M) = \sum_{i + j = n} b_{i} (X; M) b_{j} (Y; M)$

Note that if $R$ is a field, then the above holds.

Impact for ranks even in case of torsion

When $R$ is a principal ideal domain and all the homologies are finitely generated modules over $R$ , we can consider the rank as the rank of the torsion-free part of the homology modules. If $b_{i} (X; M)$ denotes the free rank of the torsion-free part of $H_{i} (X; M)$ , we get:

$b_{n} (X \times Y; M) = \sum_{i + j = n} b_{i} (X; M) b_{j} (Y; M)$

Note that this applies even if the homology modules have torsion.

In the special case that $R = M = Z$ , the numbers $b_{i}$ are called Betti numbers, and we get:

$b_{n} (X \times Y) = \sum_{i + j = n} b_{i} (X) b_{j} (Y)$

In particular, this yields that Poincare polynomial of product is product of Poincare polynomials.

Facts used

The Kunneth formula combines the Kunneth theorem and the Eilenberg-Zilber theorem.

Proof

Fill this in later

@@ Line 3: / Line 3: @@
 Suppose <math>X</math> and <math>Y</math> are [[topological space]]s. We then have the following relation for the [[homology group]]s of <math>X</math>, <math>Y</math>, and the [[product topology|product space]] <math>X \times Y</math>.
-For any <math>n \ge 0</math> and any module <math>M</math> over a commutative unital ring <math>R</math> for coefficients, we have:
+For any <math>n \ge 0</math> and any module <math>M</math> over a [[principal ideal domain]] <math>R</math> for coefficients, we have:
 <math>H_n(X \times Y;M) \cong \left(\sum_{i + j = n} H_i(X;M) \otimes H_j(Y;M)\right) \oplus \left(\sum_{p + q = n-1} \operatorname{Tor}(H_p(X;M),H_q(Y;M))\right)</math>
 Here, <math>\operatorname{Tor}</math> is torsion of modules over the ring <math>R</matH>.
+==Related facts==
+* [[Kunneth formula for cohomology]]
+* [[Universal coefficients theorem for homology]]
+* [[Universal coefficients theorem for cohomology]]
+* [[Dual universal coefficients theorem]] (computes cohomology in terms of homology)
 ==Particular cases==