English

Peiffer Elements in Simplicial Groups and Algebras

K-Theory and Homology 2007-05-23 v1 Algebraic Topology

Abstract

The main objectives of this paper are to give general proofs of the following two facts: A. For an operad \oo\oo in \ab\ab, let AA be a simplicial \oo\oo-algebra such that AmA_m is the \oo\oo-subalgebra generated by (i=0msi(Am1))(\sum_{i = 0}^{m} s_i(A_{m-1})), for every nn, and let NA\N A be the Moore complex of AA. Then d(NmA)=Iγ(\oopiI1kerdi...iIpkerdi) d (\N_m A) = \sum_{I} \gamma(\oo_{p} \otimes \bigcap_{i \in I_1}\ker d_i \otimes ... \otimes \bigcap_{i \in I_{p}}\ker d_i) where the sum runs over those partitions of [m1][m-1], I=(I1,...,Ip)I = (I_1,...,I_p), p1p \geq 1, and γ\gamma is the action of \oo\oo on AA. B. Let GG be a simplicial group with Moore complex NG\N G in which the normal subgroup of GnG_n generated by the degenerate elements in dimension nn is the proper GnG_n. Then d(NnG)=I,J[iIkerdi,jJkerdj]d(\N_nG) = \prod_{I,J}[\bigcap_{i \in I}\ker d_i, \bigcap_{j \in J}\ker d_j], for I,J[n1]I,J \subseteq [n-1] with IJ=[n1]I \cup J = [n-1]. In both cases, did_i is the ithi-th face of the corresponding simplicial object. The former result completes and generalizes results from Ak\c{c}a and Arvasi, and Arvasi and Porter; the latter, results from Mutlu and Porter. Our approach to the problem is different from that of the cited works. We have first succeeded with a proof for the case of algebras over an operad by introducing a different description of the adjoint inverse of the normalization functor N:\sabch\N: \sab \to \ch. For the case of simplicial groups, we have then adapted the construction for the adjoint inverse used for algebras to get a simplicial group G\lbG \boxtimes \lb from the Moore complex of a simplicial group GG. This construction could be of interest in itself.

Keywords

Cite

@article{arxiv.math/0501260,
  title  = {Peiffer Elements in Simplicial Groups and Algebras},
  author = {J. L. Castiglioni and M. Ladra},
  journal= {arXiv preprint arXiv:math/0501260},
  year   = {2007}
}

Comments

18 pages