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, the tensor-hom adjunction is that the

tensor product In mathematics, the tensor product V \otimes W of two vector spaces and (over the same field) is a vector space to which is associated a bilinear map V\times W \to V\otimes W that maps a pair (v,w),\ v\in V, w\in W to an element of V \otimes W ...

- \otimes X

and

hom-functor In mathematics, specifically in category theory, hom-sets (i.e. sets of morphisms between objects) give rise to important functors to the category of sets. These functors are called hom-functors and have numerous applications in category theory and ...

\operatorname(X,-)

form an adjoint pair: :

\operatorname(Y \otimes X, Z) \cong \operatorname(Y,\operatorname(X,Z)).

This is made more precise below. The order of terms in the phrase "tensor-hom adjunction" reflects their relationship: tensor is the left adjoint, while hom is the right adjoint.

General statement

Say ''R'' and ''S'' are (possibly noncommutative) rings, and consider the right

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categories (an analogous statement holds for left modules): :

\mathcal = \mathrm_S\quad \text \quad  \mathcal = \mathrm_R .

Fix an (''R'',''S'')-bimodule ''X'' and define functors ''F'': ''D'' → ''C'' and ''G'': ''C'' → ''D'' as follows: :

F(Y) = Y \otimes_R X \quad \text Y \in \mathcal

G(Z) = \operatorname_S (X, Z) \quad \text Z \in \mathcal

Then ''F'' is left adjoint to ''G''. This means there is a natural isomorphism :

\operatorname_S (Y \otimes_R X, Z) \cong \operatorname_R (Y , \operatorname_S (X, Z)).

This is actually an isomorphism of

abelian group In mathematics, an abelian group, also called a commutative group, is a group in which the result of applying the group operation to two group elements does not depend on the order in which they are written. That is, the group operation is commut ...

s. More precisely, if ''Y'' is an (''A'', ''R'') bimodule and ''Z'' is a (''B'', ''S'') bimodule, then this is an isomorphism of (''B'', ''A'') bimodules. This is one of the motivating examples of the structure in a closed bicategory.

Counit and unit

Like all adjunctions, the tensor-hom adjunction can be described by its counit and unit natural transformations. Using the notation from the previous section, the counit :

\varepsilon : FG \to 1_

has

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s :

\varepsilon_Z : \operatorname_S (X, Z) \otimes_R X \to Z

given by evaluation: For :

\phi \in \operatorname_R (X, Z) \quad \text \quad x \in X,

\varepsilon(\phi \otimes x) = \phi(x).

The

s of the unit :

\eta : 1_ \to GF

\eta_Y : Y \to \operatorname_S (X, Y \otimes_R X)

are defined as follows: For

y

Y

, :

\eta_Y(y) \in \operatorname_S (X, Y \otimes_R X)

is a right

S

-module homomorphism given by :

\eta_Y(y)(t) = y \otimes t \quad \text t \in X.

The counit and unit equations can now be explicitly verified. For

Y

\mathcal

, :

\varepsilon_\circ F(\eta_Y) : 
Y \otimes_R X \to 
\operatorname_S (X , Y \otimes_R X) \otimes_R X \to
Y \otimes_R X

is given on

simple tensor In mathematics, the modern component-free approach to the theory of a tensor views a tensor as an abstract object, expressing some definite type of multilinear concept. Their properties can be derived from their definitions, as linear maps or mo ...

s of

Y \otimes X

by :

\varepsilon_\circ F(\eta_Y)(y \otimes x) = \eta_Y(y)(x) = y \otimes x.

Likewise, :

G(\varepsilon_Z)\circ\eta_ :
\operatorname_S (X, Z) \to 
\operatorname_S (X, \operatorname_S (X , Z) \otimes_R X) \to
\operatorname_S (X, Z).

For

\phi

\operatorname_S (X, Z)

'','' :

G(\varepsilon_Z)\circ\eta_(\phi)

is a right

S

-module homomorphism defined by :

G(\varepsilon_Z)\circ\eta_(\phi)(x) = \varepsilon_(\phi \otimes x) = \phi(x)

and therefore :

G(\varepsilon_Z)\circ\eta_(\phi) = \phi.

The Ext and Tor functors

The Hom functor

\hom(X,-)

commutes with arbitrary limits, while the tensor product

-\otimes X

functor commutes with arbitrary colimits that exist in their domain category. However, in general,

\hom(X,-)

fails to commute with colimits, and

-\otimes X

fails to commute with limits; this failure occurs even among finite limits or colimits. This failure to preserve short exact sequences motivates the definition of the Ext functor and the

Tor functor In mathematics, the Tor functors are the derived functors of the tensor product of modules over a ring. Along with the Ext functor, Tor is one of the central concepts of homological algebra, in which ideas from algebraic topology are used to constr ...

References

* {{Category theory Adjoint functors Commutative algebra

General statement

Counit and unit

The Ext and Tor functors

See also

References