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Cohomologies.

Yoshifumi Tsuchimoto

\fbox{08. Tensor products and Tor}

DEFINITION 08.1   Let $ A$ be an associative unital (but not necessarily commutative) ring. Let $ L$ be a right $ A$ -module. Let $ M$ be a left $ A$ -module. For any ( $ \mathbb{Z}$ -)module $ N$ , an map

$\displaystyle \varphi: L\times M \to N $

is called an $ A$ -balanced biadditive map if
  1. $ \varphi(x_1+x_2,y)=\varphi(x_1,y)+\varphi(x_2,y)$      $ (\forall x_1,\forall x_2\in L, \forall y\in M)$ .
  2. $ \varphi(x,y_1+y_2)=\varphi(x,y_1)+\varphi(x,y_2)$      $ (\forall x\in L, \forall y_1,\forall y_2\in M)$ .
  3. $ \varphi(x a, y)=\varphi(x, a y)$      $ (\forall x\in L, \forall y\in M, \forall a\in A)$ .

PROPOSITION 08.2   Let $ A$ be an associative unital (but not necessarily commutative) ring. Then for any right $ A$ -module $ L$ and for any left $ A$ -module $ M$ , there exists a ( $ \mathbb{Z}$ -)module $ X_{L,M}$ together with a $ A$ -balanced map

$\displaystyle \varphi_0: L\times M \to X_{L,M} $

which is universal amoung $ A$ -balanced maps.

DEFINITION 08.3   We employ the assumption of the proposition above. By a standard argument on universal objects, we see that such object is unique up to a unique isomorphism. We call it the tensor product of $ L$ and $ M$ and denote it by

$\displaystyle L\otimes_A M. $

LEMMA 08.4   Let $ A$ be an associative unital ring. Then:
  1. $ A\otimes_A M \cong M$ .
  2. $ (L_1\oplus L_2) \otimes_A M \cong (L_1 \otimes M) \oplus (L_2 \otimes_A M ). $
  3. For any $ M$ , $ L\mapsto L \otimes_A M$ is a right exact functor.
  4. For any right ideal $ J$ of $ A$ and for any $ A$ -module $ M$ , we have

    $\displaystyle (A/J) \otimes_A M \cong M/ J.M $

In particular, if the ring $ A$ is commutative, then for any ideals $ I,J$ of $ A$ , we have

$\displaystyle (A/I) \otimes_A (A/J) \cong A/ (I+ J) $

DEFINITION 08.5   For any left $ A$ -module $ M$ , the left derived functor $ L_j F(M)$ of $ F_M=\bullet \otimes_A M$ is called the Tor functor and denoted by $ \operatorname{Tor}^A_j(\bullet,M)$ .

By definition, $ \operatorname{Tor}^A_j(L,M)$ may be computed by using projective resolutions of $ L$ .

EXERCISE 08.1   Compute $ \operatorname{Tor}_j^\mathbb{Z}(\mathbb{Z}/n \mathbb{Z}, \mathbb{Z}/m\mathbb{Z})$ for $ n,m\in \mathbb{Z}_{>0}$ .

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2010-06-16