2004
DOI: 10.1016/j.jpaa.2003.11.009
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Cosimplicial versus DG-rings: a version of the Dold–Kan correspondence

Abstract: The (dual) Dold-Kan correspondence says that there is an equivalence of categories K : Ch ¿0 → Ab between nonnegatively graded cochain complexes and cosimplicial abelian groups, which is inverse to the normalization functor. We show that the restriction of K to DG-rings can be equipped with an associative product and that the resulting functor DGR * → Rings , although not itself an equivalence, does induce one at the level of homotopy categories. In other words both DGR * and Rings are Quillen closed model cat… Show more

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Cited by 9 publications
(16 citation statements)
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“…Dual Dold-Kan Equivalence. The dual Dold-Kan equivalence is studied in [CC04], where the authors study the classical Quillen pair K ∶ Ch ≥0 ⇆ Ab ∆ ∶ N between non-negatively graded cochain complexes Ch ≥0 and cosimplicial abelian groups, where N is the normalized complex functor (also known as the Moore complex), and K is its left adjoint. They replace K ⊣ N with the following Quillen pair, which we will refer to as the monoidal dual Dold-Kan equivalence:…”
Section: Applications To Left Bousfield Localizationmentioning
confidence: 99%
“…Dual Dold-Kan Equivalence. The dual Dold-Kan equivalence is studied in [CC04], where the authors study the classical Quillen pair K ∶ Ch ≥0 ⇆ Ab ∆ ∶ N between non-negatively graded cochain complexes Ch ≥0 and cosimplicial abelian groups, where N is the normalized complex functor (also known as the Moore complex), and K is its left adjoint. They replace K ⊣ N with the following Quillen pair, which we will refer to as the monoidal dual Dold-Kan equivalence:…”
Section: Applications To Left Bousfield Localizationmentioning
confidence: 99%
“…This description is in the spirit of that given in [8] for the inverse of the conormalization functor.…”
Section: The Inverse Of the Normalization Functormentioning
confidence: 96%
“…Restricting to infinitesimal gauge transformations, this picture reduces nicely to the well-known BRST formalism, see [FR12] for a presentation of this topic in the context of the algebraic approach to field theory. By the dual Dold-Kan correspondence (see Appendix A) we can regard our cosimplicial algebra as a differential graded algebra (dg-algebra), see also [CC04] for more details. This dg-algebra can be 'linearized' via a procedure called the van-Est map (here we require the smooth structure mentioned above) to yield the BRST algebra (Chevalley-Eilenberg dg-algebra) of gauge theory, see e.g.…”
Section: Groupoids and Cosimplicial Algebrasmentioning
confidence: 99%