In algebraic geometry, the Cartier isomorphism is a certain isomorphism between the cohomology sheaves of the de Rham complex of a smooth algebraic variety over a field of positive characteristic, and the sheaves of differential forms on the Frobenius twist of the variety. It is named after Pierre Cartier. Intuitively, it shows that de Rham cohomology in positive characteristic is a much larger object than one might expect. It plays an important role in the approach of Deligne and Illusie to the degeneration of the Hodge–de Rham spectral sequence.[1]

Statement

Let k be a field of characteristic p > 0, and let be a morphism of k-schemes. Let denote the Frobenius twist and let be the relative Frobenius. The Cartier map is defined to be the unique morphism

of graded -algebras such that for any local section x of . (Here, for the Cartier map to be well-defined in general it is essential that one takes cohomology sheaves for the codomain.) The Cartier isomorphism is then the assertion that the map is an isomorphism if is a smooth morphism.

In the above, we have formulated the Cartier isomorphism in the form it is most commonly encountered (e.g., in the 1970 paper of Katz).[2] In his original paper, Cartier actually considered the inverse map in a more restrictive setting, whence the notation for the Cartier map.[3]

The smoothness assumption is not essential for the Cartier map to be an isomorphism. For instance, one has it for ind-smooth morphisms since both sides of the Cartier map commute with filtered colimits. By Popescu's theorem, one then has the Cartier isomorphism for a regular morphism of noetherian k-schemes.[4] Ofer Gabber has also proven a Cartier isomorphism for valuation rings.[5] In a different direction, one can dispense with such assumptions entirely if one instead works with derived de Rham cohomology (now taking the associated graded of the conjugate filtration) and the exterior powers of the cotangent complex.[6]

References

  1. Pierre Deligne; Luc Illusie (1987). "Relèvements modulo p2 et décomposition du complexe de de Rham". Inventiones Mathematicae. 89 (2): 247–270. doi:10.1007/BF01389078. S2CID 119635574.
  2. Nicholas M. Katz (January 1970). "Nilpotent connections and the monodromy theorem: Applications of a result of Turrittin". Publications Mathématiques de l'Institut des Hautes Études Scientifiques. 39: 175–232. doi:10.1007/BF02684688. S2CID 16261793.
  3. Cartier, Pierre (1957). "Une nouvelle opération sur les formes différentielles". C. R. Acad. Sci. Paris. 244: 426–428.
  4. Kelly, Shane; Morrow, Matthew (2021-05-20). "K-theory of valuation rings". Compositio Mathematica. 157 (6): 1121–1142. doi:10.1112/S0010437X21007119. ISSN 0010-437X. S2CID 119721861. cf. discussion in §2.
  5. Kerz, Moritz; Strunk, Florian; Tamme, Georg (2021-05-20). "Towards Vorst's conjecture in positive characteristic". Compositio Mathematica. 157 (6): 1143–1171. arXiv:1812.05342. doi:10.1112/S0010437X21007120. ISSN 0010-437X. S2CID 119755507. cf. Appendix A.
  6. Kedlaya, Kiran S. "Derived de Rham cohomology". kskedlaya.org. Prop. 17.2.4. Archived from the original on 2022-09-22.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.