English

Excellence, F-singularities, and solidity

Commutative Algebra 2020-07-22 v1 Algebraic Geometry

Abstract

An RR-algebra SS is RR-solid if there exists a nonzero RR-linear map SRS \rightarrow R. In characteristic pp, the study of FF-singularities such as Frobenius splittings implicitly rely on the RR-solidity of R1/pR^{1/p}. Following recent results of the first two authors on the Frobenius non-splitting of certain excellent FF-pure rings, in this paper we use the notion of solidity to systematically study the notion of excellence, with an emphasis on FF-singularities. We show that for rings RR essentially of finite type over complete local rings of characteristic pp, reducedness implies the RR-solidity of R1/pR^{1/p}, FF-purity implies Frobenius splitting, and FF-pure regularity implies split FF-regularity. We demonstrate that Henselizations and completions are not solid, providing obstructions for the RR-solidity of R1/pR^{1/p} for arbitrary excellent rings. This also has negative consequences for the solidity of big Cohen-Macaulay algebras, an important example of which are absolute integral closures of excellent local rings in prime characteristic. We establish a close relationship between the solidity of absolute integral closures and the notion of Japanese rings. Analyzing the Japanese property reveals that Dedekind domains RR for which R1/pR^{1/p} is RR-solid are excellent, despite our recent examples of excellent Euclidean domains with no nonzero p1p^{-1}-linear maps. Additionally, we show that while perfect closures are often solid in algebro-geometric situations, there exist locally excellent domains with solid perfect closures whose absolute integral closures are not solid. In an appendix, Karen E. Smith uses the solidity of absolute integral closures to characterize the test ideal for a large class of Gorenstein domains of prime characteristic.

Keywords

Cite

@article{arxiv.2007.10383,
  title  = {Excellence, F-singularities, and solidity},
  author = {Rankeya Datta and Takumi Murayama and Karen E. Smith},
  journal= {arXiv preprint arXiv:2007.10383},
  year   = {2020}
}

Comments

56 pages. Appendix by Karen E. Smith

R2 v1 2026-06-23T17:15:37.121Z