English

Ramification filtration via deformations

Number Theory 2021-01-22 v5

Abstract

Let K\mathcal K be a field of formal Laurent series with coefficients in a finite field of characteristic pp, G<p\mathcal G_{<p} -- the maximal quotient of Gal(Ksep/K)\operatorname{Gal} (\mathcal K_{sep}/\mathcal K) of period pp and nilpotent class <p<p and {G<p(v)}v0\{\mathcal G_{<p}^{(v)}\}_{v\geqslant 0} -- its filtration by ramification subgroups in the upper numbering. Let G<p=G(L)\mathcal G_{<p}=G(\mathcal L) be the identification of nilpotent Artin-Schreier theory: here G(L)G(\mathcal L) is the group obtained from a suitable profinite Lie Fp\mathbb{F}_p-algebra L\mathcal L via the Campbell-Hausdorff composition law. We develop a new technique to describe the ideals L(v)\mathcal L^{(v)} such that G(L(v))=G<p(v)G(\mathcal L^{(v)})=\mathcal G_{<p}^{(v)} and to find their generators. Given v01v_0\geqslant 1 we construct epimorphism of Lie algebras ηˉ:LLˉ\bar\eta ^{\dag }:\mathcal L\longrightarrow \bar{\mathcal L}^{\dag } and an action ΩU\Omega_U of the formal group of order pp, α=p=SpecFp[U]\alpha =_p=\operatorname{Spec}\,\mathbb{F}_p[U], Up=0U^p=0, on Lˉ\bar{\mathcal L}^{\dag }. Suppose dΩU=BUd\Omega_U=B^{\dag }U, where BDiffLˉB^{\dag }\in\operatorname{Diff}\bar{\mathcal L}^{\dag }, and Lˉ[v0]\bar{\mathcal L}^{\dag }[v_0] is the ideal of Lˉ\bar{\mathcal L}^{\dag } generated by the elements of B(Lˉ)B^{\dag }(\bar{\mathcal L}^{\dag }). The main result of the paper states that L(v0)=(ηˉ)1Lˉ[v0]\mathcal L^{(v_0)}=(\bar\eta ^{\dag })^{-1}\bar{\mathcal L}^{\dag }[v_0]. In the last sections we relate this result to the explicit construction of generators of L(v0)\mathcal L^{(v_0)} obtained earlier by the author, develop its more efficient version and apply it to the recovering of the whole ramification filtration of G<p\mathcal G_{<p} from the set of its jumps.

Keywords

Cite

@article{arxiv.1701.02207,
  title  = {Ramification filtration via deformations},
  author = {Victor Abrashkin},
  journal= {arXiv preprint arXiv:1701.02207},
  year   = {2021}
}

Comments

37 pages, revised version, added Section 5.3

R2 v1 2026-06-22T17:44:51.128Z