nLab quasi-isomorphism

Redirected from "quasi-isomorphism of chain complexes".

Contents

Context

Homological algebra

Homotopy theory

Idea
Definition
Properties

Relation to chain homology type
Relation to mapping cones and homotopy (co)fibers

In homotopy theory
Related concepts
References

Idea

A quasi-isomorphism is a chain map that induces isomorphisms on all homology groups. These are the natural choice of weak equivalences between chain complexes in the context of (stable) homotopy theory.

The localization of a category of chain complexes at the quasi-isomorphisms is called the derived category of the underlying abelian category.

Under the relation between topological spaces and chain complexes established by forming singular simplicial complexes, quasi-isomorphism can be understood as the abelianization of weak homotopy equivalences (see the Hurewicz theorem for more on this).

Definition

Let $\mathcal{A}$ be an abelian category and write $Ch_\bullet(\mathcal{A})$ for its category of chain complexes.

Definition

A chain map $f_\bullet : C_\bullet \to D_\bullet$ in $Ch_\bullet(\mathcal{A})$ is called a quasi-isomorphism if for each $n \in \mathbb{N}$ the induced morphisms on chain homology groups

H_n(f) \colon H_n(C) \to H_n(D)

is an isomorphism.

Remark

Quasi-isomorphisms are also called, more descriptively, homology isomorphisms or $H_\bullet$ -isomorphisms. See at homology localization for more on this.

Properties

Relation to chain homology type

Proposition

The relation “There exists a quasi-isomorphism from $C_\bullet$ to $D_\bullet$ .” is a reflexive and transitive relation, but it is not a symmetric relation.

Proof

Reflexivity and transitivity are evident. An explicit counter-example showing the non-symmetry is the chain map

\array{ \cdots &\to& 0 &\to& \mathbb{Z} &\stackrel{\cdot 2}{\to}& \mathbb{Z} &\to& 0 &\to& \cdots \\ \cdots && \downarrow && \downarrow && \downarrow && \downarrow && \cdots \\ \cdots &\to& 0 &\to& 0 &\to& \mathbb{Z}/2\mathbb{Z} &\to& 0 &\to& \cdots }

from the chain complex concentrated on the morphism of multiplication by 2 on integers, to the chain complex concentrated on the cyclic group of order 2.

This clearly induces an isomorphism on all homology groups. But there is not even a non-zero chain map in the other direction, since there is no non-zero group homomorphism $\mathbb{Z}/2\mathbb{Z} \to \mathbb{Z}$ .

Remark

This is as for weak homotopy equivalences, see the discussion at Relation to homotopy types there.

Relation to mapping cones and homotopy (co)fibers

Proposition

A chain map is a quasi-isomorphism precisely if its homotopy cofiber in the (∞,1)-category of chain complexes has trivial homology groups.

By basic properties discussed at truncated object in an (∞,1)-category.

Concretely this means in particular the following.

Proposition

A chain map $f_\bullet : C_\bullet \to D_\bullet$ is a quasi-isomorphism precisely if its mapping cone $cone(f)_\bullet \in Ch_\bullet(\mathcal{A})$ has all trivial chain homology groups.

Proof

This follows for instance from the homology long exact sequence

\cdots \to H_{n+1}(c)\to H_{n+1}(D) \to H_{n+1}(cone(f)) \to H_n(C) \to H_n(D) \to H_n(cone(f)) \to H_{n-1}(C) \to H_{n-1}(D) \to H_{n-1}(cone(f)) \to \cdots \,.

If here by assumption $H_n(cone(f)) = 0$ for all $n$ , then this involves exact sequences of the form

0 \to H_n(C) \stackrel{H_n(f)}{\to} H_n(D) \to 0

for all $n$ . But this says that the kernel and cokernel of $H_n(f)$ are trivial for all $n$ , hence that $H_n(f)$ is an isomorphism for all $n$ , hence that $f_\bullet$ is a quasi-isomorphism.

In homotopy theory

Quasi-isomorphisms are the weak equivalences in the most common model category structures on the category of chain complexes. See at model structure on chain complexes and derived category.

Related concepts

References

A basic introduction is around definition 1.1.2 in

Charles Weibel, An Introduction to Homological Algebra

A more systematic discussion is in section 12 of

Masaki Kashiwara, Pierre Schapira, Categories and Sheaves

Last revised on February 3, 2019 at 20:46:33. See the history of this page for a list of all contributions to it.