In mathematics, more precisely, in the theory of simplicial sets, the DoldâÂÂKan correspondence (named after Albrecht Dold and Daniel Kan) states 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 th homology group of a chain complex is the 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.
There is also an âÂÂ-category-version of the DoldâÂÂKan correspondence. The book "Nonabelian Algebraic Topology" has a Section 14.8 on cubical versions of the DoldâÂÂKan 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 EilenbergâÂÂMacLane space .
The DoldâÂÂKan correspondence between the category sAb of simplicial abelian groups and the category of nonnegatively graded chain complexes can be constructed explicitly through a pair of functors<sup>pg 149</sup> so that these functors form an equivalence of categories. The first functor is the normalized chain complex functor <blockquote></blockquote> and the second functor is the "simplicialization" functor <blockquote></blockquote> 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 (also called a nerve-realization context) where the data of this adjunction is determined by what's called a cosimplicial object , and the adjunction then takes the form <blockquote></blockquote> where we take the left Kan extension and is the Yoneda embedding.
Given a simplicial abelian group there is a chain complex called the normalized chain complex (also called the Moore complex) with terms <blockquote></blockquote> and differentials given by <blockquote></blockquote> These differentials are well defined because of the simplicial identity <blockquote></blockquote> showing the image of is in the kernel of each . This is because the definition of gives .
Now, composing these differentials gives a commutative diagram <blockquote></blockquote> and the composition map . This composition is the zero map because of the simplicial identity <blockquote></blockquote> and the inclusion , hence the normalized chain complex is a chain complex in . Because a simplicial abelian group is a functor <blockquote></blockquote> and morphisms are given by natural transformations, meaning the maps of the simplicial identities still hold, the normalized chain complex construction is functorial.