Homological Algebra for Commutative Monoids
Abstract
We first study commutative, pointed monoids providing basic definitions and results in a manner similar commutative ring theory. Included are results on chain conditions, primary decomposition as well as normalization for a special class of monoids which lead to a study monoid schemes, divisors, Picard groups and class groups. It is shown that the normalization of a monoid need not be a monoid, but possibly a monoid scheme. After giving the definition of, and basic results for, -sets, we classify projective -sets and show they are completely determine by their rank. Subsequently, for a monoid , we compute and and prove the Devissage Theorem for . With the definition of short exact sequence for -sets in hand, we describe the set of extensions for -sets and classify the set of square-zero extensions of a monoid by an -set using the Hochschild cosimplicial set. We also examine the projective model structure on simplicial -sets showcasing the difficulties involved in computing homotopy groups as well as determining the derived category for a monoid. The author defines the category of double-arrow complexes for a class of non-abelian categories and, in the case of -sets, shows an adjunction with the category of simplicial -sets.
Cite
@article{arxiv.1503.02309,
title = {Homological Algebra for Commutative Monoids},
author = {Jaret Flores},
journal= {arXiv preprint arXiv:1503.02309},
year = {2015}
}
Comments
PhD thesis, Rutgers Univ