English

The Monoid Structure on Homotopy Obstructions

Commutative Algebra 2019-02-26 v5

Abstract

Let AA be a commutative noetherian ring, containing a field kk, with 1/2k1/2\in k, dimA=d\dim A=d, and let PP be a projective AA-module or rank(P)=nrank(P)=n. In continuation of \cite{MM}, we study Homotopy obstructions for PP to split off a free direct summand. Let LO(P){\mathcal LO}(P) be the set of all pairs (I,ω)(I, \omega), where II is an ideal of AA and ω:PI/I2\omega: P\rightarrow I/I^2 is a surjective map. The homotopy relations on LO(P){\mathcal LO}(P), induced by LO(P[T]){\mathcal LO}(P[T]), leads to a set π0(LO(P))\pi_0\left({\mathcal LO}(P)\right) of equivalence classes in LO(P){\mathcal LO}(P). There are two distinguished elements e0,e1π0(LO(P)){\bf e}_0, {\bf e}_1\in \pi_0\left({\mathcal LO}(P)\right), respectively, the images of (0,0)(0, 0) and (A,0)(A, 0). Define the obstruction class e(P)=e0π0(LO(P))e(P)={\bf e}_0\in \pi_0\left({\mathcal LO}(P)\right). The following results are under suitable smoothness or regularity hypotheses. When 2nd+32n\geq d+3, we prove e(P)=e1PQAe(P)={\bf e}_1 \Leftrightarrow P\cong Q\oplus A. We prove, if 2nd+22n\geq d+2, then π0(LO(P))\pi_0\left({\mathcal LO}(P)\right) has a natural structure of a monoid, which is a group if PQAP\cong Q\oplus A. Further, we give a definition of a Euler class group E(P)E(P). Under suitable smoothness hypotheses, we prove, if PQAP\cong Q\oplus A and 2nd+32n\geq d+3, then there is natural isomorphism E(P)π0(LO(P))E(P) \rightarrow \pi_0\left({\mathcal LO}(P)\right) of groups.

Keywords

Cite

@article{arxiv.1612.00749,
  title  = {The Monoid Structure on Homotopy Obstructions},
  author = {Satya Mandal and Bibekananda Mishra},
  journal= {arXiv preprint arXiv:1612.00749},
  year   = {2019}
}

Comments

Simplified and naturalized the proof of additive structure in section 6. In fact, in the earlier version, the proof went to an unintended track

R2 v1 2026-06-22T17:11:54.790Z