Ext functor

In mathematics, the Ext functors of homological algebra are derived functors of Hom functors. They were first used in algebraic topology, but are common in many areas of mathematics.

Contents

Definition and computation

Let R be a ring and let \mathrm{Mod}_R be the category of modules over R. Let B be in \mathrm{Mod}_R and set  T(B) = \operatorname{Hom}_R(A,B), for fixed A in \mathrm{Mod}_R. This is a left exact functor and thus has right derived functors R^nT. The Ext functor is defined by

\operatorname{Ext}_R^n(A,B)=(R^nT)(B).

This can be calculated by taking any injective resolution

0 \rightarrow B \rightarrow I^0 \rightarrow I^1 \rightarrow \dots,

and computing

0 \rightarrow \operatorname{Hom}_R(A,I^0) \rightarrow 
\operatorname{Hom}_R(A,I^1) \rightarrow \dots.

Then (R^nT)(B) is the homology of this complex. Note that  \operatorname{Hom}_R(A,B) is excluded from the complex.

An alternative definition is given using the functor G(A)=\operatorname{Hom}_R(A,B). For a fixed module B, this is a contravariant left exact functor, and thus we also have right derived functors R^nG, and can define

\operatorname{Ext}_R^n(A,B)=(R^nG)(A).

This can be calculated by choosing any projective resolution

\dots \rightarrow P^1 \rightarrow P^0 \rightarrow A \rightarrow 0,

and proceeding dually by computing

0\rightarrow\operatorname{Hom}_R(P^0,B)\rightarrow 
\operatorname{Hom}_R(P^1,B) \rightarrow \dots.

Then (R^nG)(A) is the homology of this complex. Again note that  \operatorname{Hom}_R(A,B) is excluded.

These two constructions turn out to yield isomorphic results, and so both may be used to calculate the Ext functor.

Ext and extensions

Equivalence of extensions

Ext functors derive their name from the relationship to extensions of modules. Given R-modules A and B, an extension of A by B is a short exact sequence of R-modules

0\rightarrow B\rightarrow E\rightarrow A\rightarrow0.

Two extensions

0\rightarrow B\rightarrow E\rightarrow A\rightarrow0
0\rightarrow B\rightarrow E^\prime\rightarrow A\rightarrow0

are said to be equivalent (as extensions of A by B) if there is a commutative diagram

.

An extension of A by B is called split if it is equivalent to the trivial extension

0\rightarrow B\rightarrow A\oplus B\rightarrow A\rightarrow0.

There is a bijective correspondence between equivalence classes of extensions

0\rightarrow B\rightarrow E\rightarrow A\rightarrow 0

of A by B and elements of

\operatorname{Ext}_R^1(A,B).

The Baer sum of extensions

Given two extensions

0\rightarrow B\rightarrow E\rightarrow A\rightarrow 0 and 0\rightarrow B\rightarrow E^\prime\rightarrow A\rightarrow 0

we can construct the Baer sum, by forming the pullback \Gamma =\{(e,e') \in E \oplus E', \ g(e) = g' (e')\} of g: E\to A and  g'�: E^{\prime} \rightarrow A. We form the quotient Y=\Gamma /\{(b,0) - (0,b), b \in B\}, that is we mod out by the relation (b%2Be, e') ~ (e, b%2Be'). The extension

0\rightarrow B\rightarrow Y\rightarrow A\rightarrow 0

where the first arrow is b \mapsto [(b, 0)]( = [(0,b)]) and the second [(e,e')] \mapsto g(e) (= g'(e')) thus formed is called the Baer sum of the extensions E and E'.

Up to equivalence of extensions, the Baer sum is commutative and has the trivial extension as identity element. The extension 0 \to B \to E \to A \to 0 has for opposite the same extension with exactly one of the central arrows turned to their opposite eg the morphism g is replaced by -g.

The set of extensions up to equivalence is an abelian group that is a realization of the functor \operatorname{Ext}_R^1(A,B)

Construction of Ext in abelian categories

This identification enables us to define \operatorname{Ext}^1_{\mathcal{C}}(A,B) even for abelian categories \mathcal{C} without reference to projectives and injectives. We simply take \operatorname{Ext}^1_{\mathcal{C}}(A,B) to be the set of equivalence classes of extensions of A by B, forming an abelian group under the Baer sum. Similarly, we can define higher Ext groups \operatorname{Ext}^n_{\mathcal{C}}(A,B) as equivalence classes of n-extensions

0\rightarrow B\rightarrow X_n\rightarrow\cdots\rightarrow X_1\rightarrow A\rightarrow0

under the equivalence relation generated by the relation that identifies two extensions

0\rightarrow B\rightarrow X_n\rightarrow\cdots\rightarrow X_1\rightarrow A\rightarrow0 and
0\rightarrow B\rightarrow X'_n\rightarrow\cdots\rightarrow X'_1\rightarrow A\rightarrow0

if there are maps X_m\rightarrow X'_m for all m in 1,2,..,n so that every resulting square commutes.

The Baer sum of the two n-extensions above is formed by letting X''_1 be the pullback of X_1 and X'_1 over A, and X''_n be the pushout of X_n and X'_n under B. Then we define the Baer sum of the extensions to be

0\rightarrow B\rightarrow X''_n\rightarrow X_{n-1}\oplus X'_{n-1}\rightarrow\cdots\rightarrow X_2\oplus X'_2\rightarrow X''_1\rightarrow A\rightarrow0.

Further properties of Ext

The Ext functor exhibits some convenient properties, useful in computations.

Ring structure and module structure on specific Exts

One more very useful way to view the Ext functor is this: when an element of \operatorname{Ext}^n_R(A,B) is considered as an equivalence class of maps f: P_n\rightarrow B for a projective resolution P_* of A ; so, then we can pick a long exact sequence Q_* ending with B and lift the map f using the projectivity of the modules P_m to a chain map f_*: P_*\rightarrow Q_* of degree -n. It turns out that homotopy classes of such chain maps correspond precisely to the equivalence classes in the definition of Ext above.

Under sufficiently nice circumstances, such as when the ring R is a group ring over a field k, or an augmented k-algebra, we can impose a ring structure on \operatorname{Ext}^*_R(k,k). The multiplication has quite a few equivalent interpretations, corresponding to different interpretations of the elements of \operatorname{Ext}^*_R(k,k).

One interpretation is in terms of these homotopy classes of chain maps. Then the product of two elements is represented by the composition of the corresponding representatives. We can choose a single resolution of k, and do all the calculations inside \operatorname{Hom}_R(P_*,P_*), which is a differential graded algebra, with cohomology precisely \operatorname{Ext}_R(k,k).

The Ext groups can also be interpreted in terms of exact sequences; this has the advantage that it does not rely on the existence of projective or injective modules. Then we take the viewpoint above that an element of \operatorname{Ext}^n_R(A,B) is a class, under a certain equivalence relation, of exact sequences of length n%2B2 starting with B and ending with A. This can then be spliced with an element in \operatorname{Ext}^m_R(C,A), by replacing

\cdots \rightarrow X_1\rightarrow A\rightarrow 0 and 0\rightarrow A\rightarrow Y_n\rightarrow \cdots

with

\cdots \rightarrow X_1\rightarrow Y_n\rightarrow \cdots

where the middle arrow is the composition of the functions X_1\rightarrow A and A\rightarrow Y_n. This product is called the Yoneda splice.

These viewpoints turn out to be equivalent whenever both make sense.

Using similar interpretations, we find that \operatorname{Ext}_R^*(k,M) is a module over \operatorname{Ext}^*_R(k,k), again for sufficiently nice situations.

Interesting examples

If \mathbb ZG is the integral group ring for a group G, then \operatorname{Ext}^*_{\mathbb ZG}(\mathbb Z,M) is the group cohomology H^*(G,M) with coefficients in M.

For \mathbb F_p the finite field on p elements, we also have that H^*(G,M)=\operatorname{Ext}^*_{\mathbb F_pG}(\mathbb F_p,M), and it turns out that the group cohomology doesn't depend on the base ring chosen.

If A is a k-algebra, then \operatorname{Ext}^*_{A\otimes_k A^{op}}(A,M) is the Hochschild cohomology \operatorname{HH}^*(A,M) with coefficients in the A-bimodule M.

If R is chosen to be the universal enveloping algebra for a Lie algebra \mathfrak g, then \operatorname{Ext}^*_R(R,M) is the Lie algebra cohomology \operatorname{H}^*(\mathfrak g,M) with coefficients in the module M.

See also

References