-- We import definitions of adic_space, Huber_pair, etc import Frobenius import adic_space import Tate_ring import power_bounded /-! # Perfectoid Spaces Definitions in this file follow Scholze's paper: Étale cohomology of diamonds, specifically Definition 3.1 and 3.19 For more information on how to read this file, see https://leanprover-community.github.io/lean-perfectoid-spaces/how-to-read-lean.html -/ section -- notation for the power bounded subring local postfix `ᵒ` : 66 := power_bounded_subring open nat power_bounded_subring topological_space function -- We fix a prime number p parameter (p : primes) /-- A perfectoid ring is a Huber ring that is complete, uniform, that has a pseudo-uniformizer whose p-th power divides p in the power bounded subring, and such that Frobenius is a surjection on the reduction modulo p.-/ structure perfectoid_ring (R : Type) [Huber_ring R] extends Tate_ring R : Prop := (complete : is_complete_hausdorff R) (uniform : is_uniform R) (ramified : ∃ ϖ : pseudo_uniformizer R, ϖ^p ∣ p in Rᵒ) (Frobenius : surjective (Frob Rᵒ∕p)) /- CLVRS ("complete locally valued ringed space") is a category whose objects are topological spaces with a sheaf of complete topological rings and an equivalence class of valuation on each stalk, whose support is the unique maximal ideal of the stalk; in Wedhorn's notes this category is called 𝒱. A perfectoid space is an object of CLVRS which is locally isomorphic to Spa(A) with A a perfectoid ring. Note however that CLVRS is a full subcategory of the category `PreValuedRingedSpace` of topological spaces equipped with a presheaf of topological rings and a valuation on each stalk, so the isomorphism can be checked in PreValuedRingedSpace instead, which is what we do. -/ /-- Condition for an object of CLVRS to be perfectoid: every point should have an open neighbourhood isomorphic to Spa(A) for some perfectoid ring A.-/ def is_perfectoid (X : CLVRS) : Prop := ∀ x : X, ∃ (U : opens X) (A : Huber_pair) [perfectoid_ring A], (x ∈ U) ∧ (Spa A ≊ U) /-- The category of perfectoid spaces.-/ def PerfectoidSpace := {X : CLVRS // is_perfectoid X} end