Dold–Kan correspondence

Template:Short description In mathematics, more precisely, in the theory of simplicial sets, the Dold–Kan correspondence (named after Albrecht Dold and Daniel Kan) states^[1] that there is an equivalence between the category of (nonnegatively graded) chain complexes and the category of simplicial abelian groups. Moreover, under the equivalence, the ${\displaystyle n}$th homology group of a chain complex is the ${\displaystyle n}$th homotopy group of the corresponding simplicial abelian group, and a chain homotopy corresponds to a simplicial homotopy. (In fact, the correspondence preserves the respective standard model structures.) The correspondence is an example of the nerve and realization paradigm.^[2]

There is also an ∞-category-version of the Dold–Kan correspondence.^[3] The book "Nonabelian Algebraic Topology"^[4] has a Section 14.8 on cubical versions of the Dold–Kan theorem, and relates them to a previous equivalence of categories between cubical omega-groupoids and crossed complexes, which is fundamental to the work of that book.

For a chain complex C that has an abelian group A in degree n and zero in all other degrees, the corresponding simplicial group is the Eilenberg–MacLane space ${\displaystyle K(A,n)}$.

The Dold–Kan correspondence between the category sAb of simplicial abelian groups and the category ${\displaystyle {\text{Ch}}_{\ge 0}(\mathbf{\text{Ab}})}$ of nonnegatively graded chain complexes can be constructed explicitly through a pair of functors^{[1]pg 149} so that these functors form an equivalence of categories. The first functor is the normalized chain complex functor

${\displaystyle N:s\mathbf{\text{Ab}}\to {\text{Ch}}_{\ge 0}(\mathbf{\text{Ab}})}$

and the second functor is the "simplicialization" functor

${\displaystyle \mathrm{\Gamma }:{\text{Ch}}_{\ge 0}(\mathbf{\text{Ab}})\to s\mathbf{\text{Ab}}}$

constructing a simplicial abelian group from a chain complex. The formed equivalence is an instance of a special type of adjunction, called the nerve-realization paradigm^[5] (also called a nerve-realization context) where the data of this adjunction is determined by what's called a cosimplicial object^[6] ${\displaystyle dk:{\mathrm{\Delta }}^{\text{op}}\to {\text{Ch}}_{\ge 0}(\mathbf{\text{Ab}})}$, and the adjunction then takes the form

${\displaystyle \mathrm{\Gamma }={\mathrm{L}\mathrm{a}\mathrm{n}}_{y}dk:{\text{Ch}}_{\ge 0}(\mathbf{\text{Ab}})⊣s\mathbf{\text{Ab}}:{\mathrm{L}\mathrm{a}\mathrm{n}}_{dk}y=N}$

where we take the left Kan extension and ${\displaystyle y}$ is the Yoneda embedding.

Given a simplicial abelian group ${\displaystyle A_{\bullet }\in \text{Ob}(\text{s}\mathbf{\text{Ab}})}$ there is a chain complex ${\displaystyle N{A}_{\bullet }}$ called the normalized chain complex (also called the Moore complex) with terms

${\displaystyle N{A}_n={\displaystyle \bigcap _{i=0}^{n-1}}\ker (d_i)\subset A_n}$

and differentials given by

${\displaystyle N{A}_n\stackrel{(-1{)}^n{d}_n}{\to }N{A}_{n-1}}$

These differentials are well defined because of the simplicial identity

${\displaystyle d_i\circ d_n=d_{n-1}\circ d_i:A_n\to A_{n-2}}$

showing the image of ${\displaystyle d_n:N{A}_n\to A_{n-1}}$ is in the kernel of each ${\displaystyle d_i:N{A}_{n-1}\to N{A}_{n-2}}$. This is because the definition of ${\displaystyle N{A}_n}$ gives ${\displaystyle d_i(N{A}_n)=0}$.

Now, composing these differentials gives a commutative diagram

${\displaystyle N{A}_n\stackrel{(-1{)}^n{d}_n}{\to }N{A}_{n-1}\stackrel{(-1{)}^{n-1}{d}_{n-1}}{\to }N{A}_{n-2}}$

and the composition map ${\displaystyle (-1{)}^n(-1{)}^{n-1}{d}_{n-1}\circ d_n}$. This composition is the zero map because of the simplicial identity

${\displaystyle d_{n-1}\circ d_n=d_{n-1}\circ d_{n-1}}$

and the inclusion ${\displaystyle \text{Im}(d_n)\subset N{A}_{n-1}}$, hence the normalized chain complex is a chain complex in ${\displaystyle {\text{Ch}}_{\ge 0}(\mathbf{\text{Ab}})}$. Because a simplicial abelian group is a functor

${\displaystyle A_{\bullet }:\text{Ord}\to \mathbf{\text{Ab}}}$

and morphisms ${\displaystyle A_{\bullet }\to B_{\bullet }}$ are given by natural transformations, meaning the maps of the simplicial identities still hold, the normalized chain complex construction is functorial.

Template:Reflist

• Template:Cite book
• Template:Lurie-HA
• Template:Cite web

• Jacob Lurie, DAG-I

• Template:Nlab

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