Tor functor

In homological algebra, the Tor functors are the derived functors of the tensor product functor. They were first defined in generality to express the Künneth theorem and universal coefficient theorem in algebraic topology.

Specifically, suppose R is a ring, and denote by R-Mod the category of left R-modules and by Mod-R the category of right R-modules (if R is commutative, the two categories coincide). Pick a fixed module B in R-Mod. For A in Mod-R, set T(A) = AR B. Then T is a right exact functor from Mod-R to the category of abelian groups Ab (in the case when R is commutative, it is a right exact functor from Mod-R to Mod-R) and its left derived functors LnT are defined. We set

\mathrm{Tor}_n^R(A,B)=(L_nT)(A)

i.e., we take a projective resolution

\cdots\to P_2 \to P_1 \to P_0 \to A\to 0

then remove the A term and tensor the projective resolution with B to get the complex

\cdots \to P_2\otimes_R B \to P_1\otimes_R B \to P_0\otimes_R B \to 0

(note that AR B does not appear and the last arrow is just the zero map) and take the homology of this complex.

Properties

\cdots\to\mathrm{Tor}_2^R(M,B)\to\mathrm{Tor}_1^R(K,B)\to\mathrm{Tor}_1^R(L,B)\to\mathrm{Tor}_1^R(M,B)\to K\otimes B\to L\otimes B\to M\otimes B\to 0.
\mathrm{Tor}_1^R(R/(r),B)=\{b\in B:rb=0\},
from which the terminology Tor (that is, Torsion) comes: see torsion subgroup.
\mathrm{Tor}_n^R \left (\bigoplus_i A_i, \bigoplus_j B_j \right) \simeq \bigoplus_i \bigoplus_j \mathrm{Tor}_n^R(A_i,B_j)
 0 \to M_i \to K_i \to L_i,
so that M
i
and K
i
are free abelian groups. This gives rise to a double-complex with exact rows and columns
Start with x ∈ TorZ
1
(L
1
, L
2
), so β03(x) ∈ Ker(β13). Let x
12
M
1
K
2
be such that α12(x
12
) = β03(x). Then
 \alpha_{22}\circ \beta_{12}(x_{12}) = \beta_{13} \circ \alpha_{21}(x_{12}) = \beta_{13} \circ \beta_{03}(x) = 0,
i.e., β12(x
12
) ∈ Ker(α22). By exactness of the second row, this means that β12(x
12
) = α21(x
21
) for some unique x
21
K
1
M
2
. Then
 \alpha_{31}\circ\beta_{21}(x_{21}) = \beta_{22}\circ\alpha_{21}(x_{21}) = \beta_{22}\circ\beta_{12}(x_{12})=0,
i.e., β21(x
21
) ∈ Ker(α31). By exactness of the bottom row, this means that β21(x
21
) = α30(y) for some unique y ∈ TorZ
1
(L
2
, L
1
).
Upon checking that y is uniquely determined by x (not dependent on the choice of x
12
), this defines a function TorZ
n
(L
1
, L
2
) → TorZ
n
(L
2
, L
1
), taking x to y, which is a group homomorphism. One may check that this map has an inverse, namely the function TorZ
n
(L
2
, L
1
) → TorZ
n
(L
1
, L
2
) defined in a similarly manner. One can also check that the function does not depend on the choice of free resolutions.

See also

References

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