English

Witt vectors as a polynomial functor

Algebraic Geometry 2017-10-13 v3 Algebraic Topology K-Theory and Homology

Abstract

For every commutative ring AA, one has a functorial commutative ring W(A)W(A) of pp-typical Witt vectors of AA, an iterated extension of AA by itself. If AA is not commutative, it has been known since the pioneering work of L. Hesselholt that W(A)W(A) is only an abelian group, not a ring, and it is an iterated extension of the Hochschild homology group HH0(A)HH_0(A) by itself. It is natural to expect that this construction generalizes to higher degrees and arbitrary coefficients, so that one can define "Hochschild-Witt homology" WHH(A,M)WHH_*(A,M) for any bimodule MM over an associative algebra AA over a field kk. Moreover, if one want the resulting theory to be a trace theory in the sense of arXiv:1308.3743, then it suffices to define it for A=kA=k. This is what we do in this paper, for a perfect field kk of positive characteristic pp. Namely, we construct a sequence of polynomial functors WmW_m, m1m \geq 1 from kk-vector spaces to abelian groups, related by restriction maps, we prove their basic properties such as the existence of Frobenius and Verschiebung maps, and we show that WmW_m are trace functors in the sense of arXiv:1308.3743. The construction is very simple, and it only depends on elementary properties of finite cyclic groups.

Keywords

Cite

@article{arxiv.1602.04254,
  title  = {Witt vectors as a polynomial functor},
  author = {D. Kaledin},
  journal= {arXiv preprint arXiv:1602.04254},
  year   = {2017}
}

Comments

LaTeX2e, 49 pages. Final version -- corrected some typos

R2 v1 2026-06-22T12:49:27.039Z