Branched Covering and Profinite Completion

Runjie Hu

Abstract

Artin-Mazur established the étale homotopy theory of schemes and proved the generalized Riemann existence theorem, i.e., all étale morphisms of a complex finite type scheme induce its profinite completion. We generalize it to piecewise linear pseudomanifolds and prove that all branched coverings of a pseudomanifold induce its profinite completion.

1 Introduction

Weil conjectured the existence of some cohomology theory for nonsigular projective varieties over finite fields. According to the Lefschetz fixed-point formula and the Poincaré duality for ordinary cohomology theory, he further conjectured several statements which were later called the famous Weil Conjectures.

Grothendieck defined the étale topology for schemes and the associated étale cohomology theory was later defined by Artin-Grothendieck-Verdier, exposited in the famous SGA notes [1], or independently by Lubkin ([6]). The étale cohomology provides the Lefschetz fixed-point formula and the Poincaré duality. Hence the proof of most of the Weil conjectures is straightforward, except the Riemann hypothesis, which was completed by Deligne ([4]).

Out of the étale topology of schemes, Artin-Mazur ([2]) also defined the étale homotopy type of a scheme. They generalized the Cěch nerve of an open cover to define a hypercovering of a (pointed) Grothendieck-Verdier site by a (pointed) simplicial object satisfying some refinement condition at each level. Then all the hypercoverings of a site form a pro system up to homotopy. When the site is locally connected, levelwise connected components of a hypercovering form a simplicial set. Then one gets a pro-space out of hypercoverings.

They also defined the profinite completion of a pro-space by the left adjoint of the inclusion functor from the pro homotopy category of finite spaces to the pro homotopy category of pointed CW complexes. Later on, Sullivan ([8]) proved that the pro-space of Artin-Mazur’s profinite completion has a homotopy inverse limit.

If one considers the étale site of some ‘nice’ scheme, each hypercovering is a finite space and the pro-space induced from all hypercoverings is called the étale homotopy type of the scheme. Assuming that the scheme is finite type over $\mathbb{C}$ , Artin-Mazur proved that its étale homotopy type is homotopy equivalent to the profinite completion of its analytification.

This paper aims to extend Arin-Mazur’s construction to a piecewise linear pseudomanifold and prove the generalized Riemann existence theorem for pseudomanifolds. In the postscript of [8], Sullivan already claimed it and suggested a method for proof via transversality and the symmetric product approximation of an Eilenberg-Maclane space. However, the method of this paper is quite different.

Let us first explain why we use pseudomanifolds and branched coverings. Roughly speaking, a pseudomanifold $X$ is a manifold with singularity of real dimension at least $2$ . It is like a piecewise-linear generalization of a complex variety. Moreover, an étale morphism into a complex variety is almost a finite covering map onto a Zariski open subset. An appropriate piecewise-linear generalization is a finite covering map onto the complement of a real codimension at least $2$ subcomplex of the pseudomanifold. We can always complete such a map to a piecewise linear branched covering map.

Apply Artin-Mazur’s construction to the Grothendieck site of all branched cover over a pseudomanifold, i.e., the pro-space $X_{\operatorname{\acute{e}t}}$ formulated by the levelwise connected components of all hypercoverings. By Artin-Mazur’s arguments, we prove that each space in the pro-system is a finite space and then deduce that

Theorem 1.1.

If $X$ is a pointed connected pseudomanifold, then $X_{\operatorname{\acute{e}t}}$ is homotopy equivalent to the profinite completion of $X$ .

The technical part is the comparison theorem of cohomologies under ordinary topology and étale topology, i.e., any degree at least $1$ cocycle of a finite local system vanishes after passing to each branched covering in some ‘open’ covering of the étale site.

We use the complement of the codimension $2$ skeleton or the codimension $2$ coskeleton to form the étale cover. Each of them deformation retracts onto some $1$ -dimensional complex and any cocycle vanishes after passing to some finite cover of the $1$ -dimensional complex.

I want to thank my thesis advisor Dennis Sullivan, who led me to this fantastic area. I also want to thank Jason Starr for disucssions in the Riemann existence theorem and Siqing Zhang for explaining the algebro-geometric proof of the comparison theorem in the étale theory.

2 Profinite Completion

This chapter is a review of Artin-Mazur’s definition [2] of profinite completion.

Definition 2.1.

A small category $I$ is cofiltering if

(1) for any two objects $i$ and $j$ , there exists an object $k$ with morphisms $k\rightarrow i$ and $k\rightarrow j$ ;

(2) for any two morphisms $i\rightrightarrows j$ , there exists an object $k$ with a morphism $k\rightarrow i$ such that the two compositions $k\rightarrow i\rightrightarrows j$ are equal.

Definition 2.2.

Let $\phi:I\rightarrow J$ be a functor of two small cofiltering categories. Call $\phi$ cofinal for $J$ if

(1) for any object $j$ of $J$ , there is an object $j$ of $I$ with a morphism $\phi(i)\rightarrow j$ ;

(2) for any two morphisms $\phi(i)\rightrightarrows j$ , where $i$ and $j$ are objects of $I$ and $J$ respectively, there exists a morphism $i_{1}\rightarrow i$ in $I$ so that the compositions $\phi(i_{1})\rightarrow\phi(i)\rightrightarrows j$ are identical.

Definition 2.3.

Let $\mathbf{D}$ be a category. A pro-object of $\mathbf{D}$ is a functor $I\rightarrow\mathbf{D}$ for some cofiltering small category $I$ . The associated pro-category $\operatorname{Pro}(\mathbf{D})$ consists of pro-objects of $\mathbf{D}$ and the morphism sets are defined by

\operatorname{Hom}(\{X_{i}\}_{i\in I},\{Y_{j}\}_{j\in J})=\underset{j}{\varprojlim}\underset{i}{\varinjlim}\operatorname{Hom}(X_{i},Y_{j})

There is a more concrete way to represent a pro-morphism ([2]).

Proposition 2.4.

Let $f:X\rightarrow Y$ be a pro-morphism, where $X$ and $Y$ are two pro-objects indexed by $I$ and $J$ respectively. Then there exists a cofiltering small category $K$ with cofinal functors $\phi:K\rightarrow I$ , $\psi:K\rightarrow J$ such that $f$ is equivalent to a morphism $\{f_{k}:X_{k}\rightarrow Y_{k}\}_{k\in K}$ . In addition, the representative for $f$ is unique up to isomorphism.

Definition 2.5.

Let Gr be the category of groups. Call a full subcategory $\mathcal{C}$ of Gr complete if

(1) $\mathcal{C}$ contains the trivial group;

(2) for any exact sequence

1\rightarrow G\rightarrow H\rightarrow K\rightarrow 1

$H\in\mathcal{C}\Rightarrow G\in\mathcal{C}$ and $G,K\in\mathcal{C}\Rightarrow H\in\mathcal{C}$ ;

(3) $G^{|H|}\in\mathcal{C}$ for any $G,H\in\mathcal{C}$ .

Example 2.6.

There are only two major examples of $\mathcal{C}$ . One is the class of all finite groups and the other is the class of all $p$ -groups for a prime $p$ . We assume $\mathcal{C}$ is one of them in the following context.

In practice, we can avoid the set theoretic issue by isomorphism classes of objects and thus we can assume $\mathcal{C}$ is small.

Lemma 2.7.

The natural inclusion $\operatorname{Pro}(\mathcal{C})\rightarrow\operatorname{Pro}(\textbf{Gr})$ admits a left adjoint $\widehat{\cdot}:\operatorname{Pro}(\textbf{Gr})\rightarrow\operatorname{Pro}(\mathcal{C})$ .

Definition 2.8.

The left adjoint functor $\widehat{\cdot}:\operatorname{Pro}(\textbf{Gr})\rightarrow\operatorname{Pro}(\mathcal{C})$ in the lemma is called the $\mathcal{C}$ -completion of (pro-)groups.

Proof.

([2])

Let $G=\{G_{i}\}$ be a pro-group. Consider the pro-system of all pro-homomorphisms $f:G\rightarrow A$ with $A\in\mathcal{C}$ . We can get a pro-group $\{A\}$ indexed by the homomorphisms $f$ , where a morphism $f\rightarrow f^{\prime}$ is defined by the diagram .

Then we define $\widehat{G}$ by $\{A\}$ and check that it is left adjoint to the inclusion $\operatorname{Pro}(\mathcal{C})\rightarrow\operatorname{Pro}(\textbf{Gr})$ . ∎

Let $\textbf{W}_{0}$ be the category of based connected CW complexes and let $\textbf{H}_{0}$ be its homotopy category. A (pro) space is a (pro) object of $\textbf{H}_{0}$ .

Let $A$ be an abelian group. The homology of a pro-space $X=\{(X_{i},x_{i})\}$ with coefficient $A$ is defined by the pro-group $H_{n}(X;A)=\{H_{n}(X_{i};A)\}$ and the cohomology is the group $H^{n}(X;A)=\underset{i}{\varinjlim}H^{n}(X_{i};A)$ . Similarly, define the homotopy group $\pi_{n}X$ by the pro-group $\{\pi_{n}(X_{i},x_{i})\}$ .

Remark 2.9.

One may wish to get rid of the basepoint issue in the discussion, there are examples of pro-objects of the space category which are not pro-objects of based spaces. In [5] Isaksen suggested the following way. Let $X=\{X_{i}\}$ be a pro-object of the category of CW complexes. Define the fundamental groupoid of $X$ by the pro-system of fundamental groupoids $\Pi X=\{\Pi X_{i}\}$ . Let $\Pi_{n}X_{i}$ be a functor from $\Pi X_{i}$ to the category of (abelian) groups, which maps each point $x_{i}\in X_{i}$ to $\pi_{n}(X_{i},x_{i})$ . Call the pro-system $\Pi_{n}X=\{\Pi_{n}X_{i}\}$ the pro (local system of) homotopy groups of $X$ .

Let $\mathcal{C}\textbf{W}_{0}$ be the full subcategory of $\textbf{W}_{0}$ consisting of the CW complexes with all homotopy groups in $\mathcal{C}$ . Let $\mathcal{C}\textbf{H}_{0}$ be the corresponding homotopy category.

Definition 2.10.

The $\mathcal{C}$ -completion of a pro-space $X\in\operatorname{Pro}(\textbf{H}_{0})$ is an object $\widehat{X}$ of $\operatorname{Pro}(\mathcal{C}\textbf{H}_{0})$ together with a pro-morphism $X\rightarrow\widehat{X}$ such that any morphism $X\rightarrow Y$ with $Y\in\operatorname{Pro}(\mathcal{C}\textbf{H}_{0})$ uniquely factors through some morphism $\widehat{X}\rightarrow Y$ , in the category $\operatorname{Pro}(\textbf{H}_{0})$ .

Theorem 2.11.

(Artin-Mazur, [2]) The $\mathcal{C}$ -completion of a pro-space always exists. In other words, the natural inclusion $\operatorname{Pro}(\mathcal{C}\textbf{H}_{0})\rightarrow\operatorname{Pro}(\textbf{H}_{0})$ has a left adjoint $\widehat{\cdot}:\operatorname{Pro}(\textbf{H}_{0})\rightarrow\operatorname{Pro}(\mathcal{C}\textbf{H}_{0})$ .

The idea is analogous to the case of groups, namely, the pro-space $\widehat{X}$ is constructed out of all homotopy classes of pro-maps $f:X\rightarrow F$ with $F\in\mathcal{C}\textbf{H}_{0}$ .

Remark 2.12.

Sullivan ([8]) defined a homotopy inverse limit $\widehat{X}^{S}$ of the pro-space $\widehat{X}$ when $\mathcal{C}$ is the class of finite groups or $p$ -groups.

Remark 2.13.

Let $\mathcal{C}$ be the class of $p$ -groups. Then Artin-Mazur-Sullivan’s $\mathcal{C}$ -completion of a space is not homotopy equivalent to the Bousfield-Kan’s $\mathbb{Z}/p$ -localization, unless the space is nilpotent ([3]).

It is not hard that

Proposition 2.14.

([2])

\pi_{1}(\widehat{X})\simeq\widehat{\pi_{1}(X)}

Definition 2.15.

A map $f:X\rightarrow Y$ of pro-spaces is a weak equivalence if $f$ induces an isomorphism on (pro) homotopy groups.

Definition 2.16.

A map of pro-spaces $f:X\rightarrow Y$ is called a $\mathcal{C}$ -equivalence if

(1) $\widehat{\pi_{1}X}\rightarrow\widehat{\pi_{1}Y}$ is an isomorphism;

(2) for any $\mathcal{C}$ local system $A$ over $Y$ , $H^{n}(Y;A)\rightarrow H^{n}(X;A)$ is an isomorphism for every $n$ .

Theorem 2.17.

([2]) A map of pro-spaces $f:X\rightarrow Y$ is a $\mathcal{C}$ -equivalence if and only if $\widehat{f}:\widehat{X}\rightarrow\widehat{Y}$ is a weak equivalence.

In particular, the $\mathcal{C}$ -completion $X\rightarrow\widehat{X}$ is a $\mathcal{C}$ -equivalence.

3 Sites and Hypercoverings

In this chapter, we review the definition of sites and Artin-Mazur’s definition of hypercoverings for a site. We also revisit the necessary lemmas used for our main result.

Definition 3.1.

A site is a category C with a distinguised set of families of morphisms $(U_{i}\rightarrow U)_{i\in I}$ for each object $U$ , which is called the set of coverings of $U$ , such that

(1) $(U\xrightarrow{1}U)$ is a covering for each object $U$ ;

(2) for each covering $(U_{i}\rightarrow U)_{i\in I}$ and each morphism $V\rightarrow U$ , the pullback $U_{i}\times_{U}V$ exists and $(U_{i}\times_{U}V\rightarrow V)_{i\in I}$ is a covering of $V$ ;

(3) for any coverings $(U_{i}\rightarrow U)_{i\in I}$ and $(V_{ij}\rightarrow U_{i})_{j\in J_{i}}$ for each $i\in I$ , the family $(V_{ij}\rightarrow U_{i}\rightarrow U)_{ij}$ is also a covering of $U$ .

For simplicity, we always assume that the underlying category of a site admits finite limits and finite coproducts.

Example 3.2.

The set category $\mathbf{Set}$ has a natural site structure, where for each set $S$ the covering set consists of all such family of maps $(S_{i}\rightarrow S)_{i\in I}$ that the union of images is $S$ .

Example 3.3.

Let $X$ be a topological space. The category of its open subsets $\mathbf{Op}(X)$ is a site. Indeed, a covering in the site $\mathbf{Op}(X)$ is an open cover over an open subset.

Example 3.4.

Let $X$ be a scheme. The étale site $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ over $X$ consists of all étale morphisms $U\rightarrow X$ , where the coverings are the surjective families. If $X$ is quasi-compact, one can take the coverings to be finite surjective families.

Example 3.5.

Let $G$ be a profinite group. The category $\operatorname{Fin}(G)$ of finite continuous $G$ -sets is a site.

Definition 3.6.

A morphism of sites $\widetilde{F}:\textbf{C}_{2}\rightarrow\textbf{C}_{1}$ is a functor $F:\textbf{C}_{1}\rightarrow\textbf{C}_{2}$ which preserves finite limits, arbitrary colimits and the coverings.

Definition 3.7.

A point of a site C is a morphism of sites $\widetilde{P}:\mathbf{Set}\rightarrow\textbf{C}$ . In particular, the image of the terminal object $1_{\textbf{C}}$ of C is the one-element set.

A pointed simplicial object $K_{*}$ of a pointed site $(\textbf{C},\widetilde{P})$ is a simplicial object so that $P(K_{*})$ is a pointed simplicial set.

Artin-Mazur defined hycoverings of a site so that they can further define a pro homotopy type for a ‘nice’ site.

Definition 3.8.

A hypercovering $K_{*}$ of a (pointed) site C is a (pointed) simplicial object of C such that

(1) $K_{0}\rightarrow 1_{\textbf{C}}$ is a covering, where $1_{\textbf{C}}$ is the terminal object of C;

(2) the canonical morphism $K_{n+1}\rightarrow(\operatorname{Cosk}_{n}K)_{n+1}$ is a covering for any $n\geq 0$ , where $\operatorname{Cosk}_{n}$ is the $n$ -th coskeleton.

A simplicial morphism of hypercoverings $K_{*}\rightarrow K^{\prime}_{*}$ is called a refinement if for each level $n$ the map $K_{n}\rightarrow K^{\prime}_{n}$ is a covering.

Let $X$ be an object of C and $S$ be a finite set. Define the object $X\times S$ of C by $\bigsqcup_{S}X$ .

Let $I_{*}$ be the simplicial set of the unit interval. Then for any simplicial object $K_{*}$ of C we can form the simplicial object $K_{*}\times I_{*}$ by $(K_{*}\times I_{*})_{n}=K_{n}\times I_{n}$ .

Two simplicial maps $f,g:K_{*}\rightarrow K^{\prime}_{*}$ of simplicial objects are strictly homotopic if there is a map $F:K_{*}\times I_{*}\rightarrow K^{\prime}_{*}$ connecting them, i.e., $F\circ j_{0}=f$ and $F\circ j_{1}=g$ , where $j_{0},j_{1}:K_{*}\rightarrow K_{*}\times I_{*}$ are induced by the maps $[0],[1]:\operatorname{pt}\rightarrow I_{*}$ . Call $f$ and $g$ homotopic if they are connected by a finite chain of strict homotopies.

Let $HR(\textbf{C})$ be the category of hypercoverings of the (pointed) site C, whose morphisms are homotopy classes of simplicial morphisms.

Lemma 3.9.

$HR(\textbf{C})$ is a cofiltering category.

Definition 3.10.

An object $X$ of a site C is connected if it is not a nontrivial coproduct in C. A site C is locally connected if each object is a coproduct of some connected objects, where each connected object in the coproduct is called a connected component. Call a locally connected site C connected if its terminal object is connected.

There is a natural connected component functor $\pi:\textbf{C}\rightarrow\mathbf{Set}$ for a locally connected site C defined by mapping an object to the index set of its connected components. Then for any hypercovering $K_{*}$ of C, $\pi(K_{*})$ is a simplicial set. If C is pointed, then $\pi(K_{*})$ is a pointed/based simplicial set; if C is connected, then the simplicial set $\pi(K_{*})$ is connected.

Since $HR(\textbf{C})$ is cofiltering, we get a pro-system of (homotopy) simplicial sets $\pi C=\{\pi(K_{*})\}_{K_{*}\in HR(\textbf{C})}$ .

Definition 3.11.

Let C be a pointed connected site. The pro homotopy type of C is defined by the pro-object $\pi C$ in $\textbf{H}_{0}$ . Define the homotopy group $\pi_{n}(\textbf{C})$ by the pro-group $\{\pi_{n}\pi(K_{*})\}_{K_{*}\in HR(\textbf{C})}$ .

Example 3.12.

Suppose $X$ is a pointed connected topological space. The ordinary topology site $\mathbf{Op}(X)$ is also pointed. Suppose any open cover of $X$ admits a refinement of good covers, i.e., any finite intersection of connected opens is contractible. Then the pro-space $\pi\mathbf{Op}(X)$ is weak equivalent to the singular complex $\operatorname{Sing}(X)$ .

Let us skip the definition of fibered categories and only define the descent data in the form that we will use.

For each object $X$ of a site C, let $\mathbf{F}(X)$ be the small category of objects

\{X\times S|S\,\,\text{is a finite set}\}

where morphisms are of the form $X\times S\rightarrow X\times S^{\prime}$ so that the following diagram commutes.

Any morphism $f:X\rightarrow Y$ in C induces a natural functor $f^{*}:\mathbf{F}(Y)\rightarrow\mathbf{F}(X)$ .

Definition 3.13.

Let $K_{*}$ be a hypercovering of a site C. A locally constant covering (or a descent data) on $K_{*}$ is an object $\alpha$ of $\mathbf{F}(K_{0})$ together with an isomorphism $\phi:\partial^{*}_{0}\alpha\xrightarrow{\simeq}\partial^{*}_{1}\alpha$ in $\mathbf{F}(K_{1})$ such that $\partial^{*}_{1}\phi=\partial^{*}_{2}\phi\circ\partial^{*}_{0}\phi$ in $\mathbf{F}(K_{2})$ .

If C is locally connected, then a locally constant covering consists of a hypercovering $K_{*}$ , a finite set $S$ and a $1$ -cocycle $\sigma$ of $\pi(K_{*})$ with values in the symmetric group $\operatorname{Sym}(S)$ . Two locally constant coverings $(K_{*},S,\sigma)$ and $(K^{\prime}_{*},S^{\prime},\sigma^{\prime})$ are isomorphic if $S=S^{\prime}$ and there exists a common refinement $K^{\prime\prime}$ with $\phi_{0}:K^{\prime\prime}\rightarrow K$ and $\phi_{1}:K^{\prime\prime}\rightarrow K^{\prime}$ such that $\phi_{0}^{*}\sigma$ and $\phi_{1}^{*}\sigma^{\prime}$ are cohomologous.

Lemma 3.14.

Let C be a locally connected site and let $K_{*}$ be a hypercovering. The set of isomorphism classes of locally constant coverings $(K_{*},S,\sigma)$ is bijective to the set of isomorphism classes of simplicial covering sets of $\pi(K_{*})$ .

Let $G$ be a finite group. Define a principal bundle over C with fiber $G$ by a locally constant sheaf with stalk $|G|$ left acted by $G$ over a site C, namely, a locally constant covering $(K_{*},|G|,\sigma)$ with $\sigma\in G\subset\operatorname{Sym}(|G|)$ . Hence,

Lemma 3.15.

Let C be a locally connected site and let $G$ be a finite group. The set of isomorphism classes of principal bundles over C with fiber $G$ is bijective to $\operatorname{Hom}(\pi_{1}\textbf{C},G)$ .

Lemma 3.16.

Let C be a connected pointed site and let $A$ be a finite abelian group. Any locally constant sheaf $\mathfrak{A}$ with stalk $A$ induces a local system $\widetilde{A}$ on the pro-space $\pi\textbf{C}$ , then there is a canonical isomorphism

H^{*}(\textbf{C};\mathfrak{A})\simeq H^{*}(\pi\textbf{C};\widetilde{A})

Finally, let us review the results of étale homotopy theory for schemes. Let $\mathcal{C}$ be the class of finite groups.

Theorem 3.17.

([2]) Let $X$ be a pointed connected geometrically unibranched Noetherian scheme. Then the homotopy type $X_{\operatorname{\acute{e}t}}$ of the étale site $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ is a pro $\mathcal{C}$ -space, i.e., an object of $\mathcal{C}\textbf{H}_{0}$ .

The proof is based on the following key lemma.

Lemma 3.18.

Let $G$ be a profinite group. Let $K_{*}$ be a hypercovering of the site $\operatorname{Fin}(G)$ . Then $\pi_{n}\pi(K_{*})$ is a finite group for each $n$ .

For a scheme $X$ over $\mathbb{C}$ of finite type, let $X_{\operatorname{cl}}$ be the complex algebraic set with analytic topology.

Theorem 3.19.

(Generalized Riemann Existence Theorem)

Let $X$ be a pointed connected finite type scheme over $\mathbb{C}$ . Then there is a canonical map $X_{\operatorname{cl}}\rightarrow X_{\operatorname{\acute{e}t}}$ , which induces an isomorphism in the category $\operatorname{Pro}(\textbf{H}_{0})$ after profinite completion.

Artin-Mazur first proved that $X_{\operatorname{cl}}\rightarrow X_{\operatorname{\acute{e}t}}$ is a C-equivalence. To show that the map is indeed a profinite homotopy equivalence, the followings are needed.

Definition 3.20.

Let $\mathcal{C}$ be a class of group and let C be a site. An object $X$ of C has $\mathcal{C}$ -dimension at most $d$ if for any locally constant sheaf $\mathfrak{A}$ of abelian groups over C, $H^{n}(X;\mathfrak{A})=0$ for each $n>d$ . C has $\mathcal{C}$ -dimension at most $d$ if for each object $X$ there is a covering $Y$ over $X$ having $\mathcal{C}$ -dimension at most $d$ .

Let $f$ be a pointed morphism of pointed connected sites $\textbf{C}\rightarrow\textbf{C}^{\prime}$ induced by the functor $F:\textbf{C}^{\prime}\rightarrow\textbf{C}$ . Then for any hypercovering $K_{*}$ of $\textbf{C}^{\prime}$ , consider all maps $L_{*}\rightarrow F(K_{*})$ of hypercoverings in C. They induce a morphism of pro-spaces

\pi(f):\pi\textbf{C}=\{\pi(L_{*})\}_{L_{*}\in HR(\textbf{C})}\rightarrow\{\pi(K_{*})\}_{K_{*}\in HR(\textbf{C}^{\prime})}=\pi\textbf{C}^{\prime}

Lemma 3.21.

Let $\mathcal{C}$ be a complete class of groups. Let C and $\textbf{C}^{\prime}$ be pointed connected sites of dimension at most $d$ for some $d$ . Let $f$ be a pointed morphism of pointed connected sites $\textbf{C}\rightarrow\textbf{C}^{\prime}$ . If $\pi(f)$ is a $\mathcal{C}$ -equivalence, then the map $\widehat{\pi(f)}$ induced by $\mathcal{C}$ -completion is an isomorphism in the category $\textbf{H}_{0}$ .

4 Simplicial Pseudomanifolds

Definition 4.1.

A piecewise linear pseudomanifold $X$ of dimension $n$ is a compact polyhedron so that there exists a finite triangulation on $X$ satisfying that

(1) each simplex is a face of some $n$ -simplex;

(2) each $(n-1)$ -simplex is the face of precisely two $n$ -simplices.

Call a pseudomanifold $X$ normal if the link of each $i$ -simplex is connected for $i<n-1$ .

Let $X$ be a pseudomanifold of dimension $n$ with a fixed triangulation $T$ . Let $T^{\prime}$ be the barycentric subdivision of $T$ . Each simplex of $T^{\prime}$ is uniquely represented by a sequence $(\sigma_{0},\sigma_{1},\cdots,\sigma_{k})$ , where each $\sigma_{i}$ is a simplex of $T$ and each $\sigma_{i+1}$ is a face of $\sigma_{i}$ .

An $i$ -dimensional dual cone $C^{i}(\sigma^{n-i})$ of $X$ associated to a simplex $\sigma^{n-i}\in T$ is defined by the union of all the closed simplices in $T^{\prime}$ like $(\sigma_{0},\sigma_{1},\cdots,\sigma_{k}=\sigma^{n-i})$ .

The link $L(\sigma^{n-i})$ of $\sigma^{n-i}$ is the subcomplex consisting of the simplices $(\sigma_{0},\sigma_{1},\cdots,\sigma_{k}\neq\sigma^{n-i}))$ in $C^{i}(\sigma^{n-i})$ .

The $i$ -skeleton of $X$ is the union of all simplices of dimension at most $i$ and the $i$ -coskeleton of $X$ is the union of all dual cones of dimension at most $i$ .

Notice that the $i$ -skeleton intersects the $(n-i)$ -coskeleton transversally.

It is obvious that the link of each codimension $1$ simplex is $S^{0}$ and the link of each codimension $2$ simplex is a finite number of $S^{1}$ .

Proposition 4.2.

The link of each codimension at least $2$ simplex of a pseudomanifold is also a pseudomanifold.

Proof.

Let $\tau^{n-i}$ be a simplex of the triangulation $T$ of $X$ with $i\geq 2$ .

Obviously, each simplex in the link of $L(\tau)$ is contained in some $(i-1)$ -dimensional simplex of $T^{\prime}$ like $(\sigma^{n}_{0},\sigma^{n-1}_{1},\cdots,\sigma^{n-i+1}_{i-1})$ , where $\tau$ is a face of $\sigma^{n-i+1}_{i-1}$ .

Consider an $(i-2)$ -simplex $(\sigma_{0},\sigma_{1},\cdots,\sigma_{i-2})$ of $L(\tau)$ . Either $\sigma_{0}$ is some $n$ -simplex $\alpha^{n}$ of $X$ or $\sigma_{0}$ is some $(n-1)$ -simplex $\beta^{n-1}$ .

For the first case, $(\sigma_{0},\sigma_{1},\cdots,\sigma_{i-2})=({\alpha^{n},\cdots,\alpha^{n-j},\alpha^{n-j-2},\cdots,\alpha^{n-i+1}})$ for some $j$ . Since $\alpha^{n-j-2}$ is contained in only two faces of $\alpha^{n-j}$ , $(\sigma_{0},\sigma_{1},\cdots,\sigma_{i-2})$ is also contained in two simplices of $L(\tau)$ .

For the second case, $(\sigma_{0},\sigma_{1},\cdots,\sigma_{i-2})=({\beta^{n-1},\cdots,\beta^{n-i+1}})$ . Because $X$ is a pseudomanifold, $\beta^{n-1}$ is the face of two simplicies in $T$ . So $(\sigma_{0},\sigma_{1},\cdots,\sigma_{i-2})$ is also contained in two simplices of $L(\tau)$ . ∎

Let $B$ be a subpolyhedron of a pseudomanifold $X$ . Let $C(B,X)$ be the union of simplices in $T^{\prime}$ disjoint from $B$ . Notice that $C(B,X)$ is also the union of dual cones that is disjoint from $B$ .

Lemma 4.3.

$X-B$ contracts to $C(B,X)$ .

Proof.

Do induction on the dimension of dual cones, as follows. Let $CT^{(i)}$ be the $i$ -coskeleton of $T$ . Suppose that $X-B$ contracts to $CT^{(i-1)}-B$ already. Consider an $i$ -dimensional dual cone $C^{i}(\sigma)$ . If it does not intersect $B$ , then $C^{i}\subset C(B,X)$ . Otherwise, $\sigma$ is a simplex of $B$ and the intersection $C^{i}(\sigma)\bigcap B$ consists of the intersections like $C^{i}(\sigma)\bigcap\tau$ , where $\tau$ ranges over simplices of $B$ that contains $\sigma$ . Then $C^{i}(\sigma)\bigcap B$ is a cone of $L(\sigma)\bigcap B$ . Let us contract $C^{i}(\sigma)$ minus the cone point along the radial direction of the cone. Then $C^{i}(\sigma)\bigcap B$ minus the cone point contracts to $L(\sigma)\bigcap B$ and the complement of $C^{i}(\sigma)\bigcap B$ in $C^{i}(\sigma)$ contracts to $L(\sigma)-B$ . ∎

In particular,

Corollary 4.4.

The complement of $i$ -skeleton contracts to $(n-i-1)$ -coskeleton.

On the other hand, let $D$ be a full subcomplex of $T^{\prime}$ so that $D$ consists of dual cones. Let $S(D,X)$ be the union of simplicies of $T$ that does not intersect $D$ . Notice that each simplex is a cone over its boundary about its barycenter and the barycentric subdivision respects the cone structure. Apply the same argument for the skeletons and we get

Lemma 4.5.

$X-D$ contracts to $S(D,X)$ .

Corollary 4.6.

The complement of $i$ -coskeleton contracts to $(n-i-1)$ -skeleton.

The lemmas are also true for more general cases, such as finite simplicial complexes.

Definition 4.7.

A compact polyhedron $X$ is a pseudomanifold with boundary $\partial X$ of dimension $n$ if there exists a finite triangulation such that

(1) each simplex is a face of asome $n$ -simplex;

(2) each $(n-1)$ -simplex is the face of at most two $n$ -simplices.

(3) if we define $\partial X$ by the union of all such $(n-1)$ -simplicies that are not contained in two $n$ -simpleices, $\partial X$ is a pseudomanifold of dimension $(n-1)$ .

Call $X-\partial X$ the interior of $X$ .

Similarly, we can also define dual cones and links for a pseudomanifold with boundary and prove the following.

Proposition 4.8.

The link of each codimension at least $2$ simplex $\sigma$ of a pseudomanifold $X$ with boundary is a pseudomanifold with boundary if $\sigma\subset\partial X$ , or a pseudomanifold otherwise.

Likewise, 4.5 and 4.3 are also true.

Recall the definition of regular neighborhoods. Let $B$ be a full subcomplex of some triangulation $T$ of $X^{n}$ . Define a regular neighborhood $N(B,X)$ of $B$ by $\overline{X-C(X,B)}$ . Indeed, $N(B,X)$ consists of all closed dual cones that have nonempty intersetion with $B$ .

Lemma 4.9.

$N(B,X)$ is a pseudomanifold with boundary of dimension $n$ , where $\partial N(B,X)$ consists of dual cones that does not intersect $B$ , namely, $\partial N(B,X)=N(B,X)\bigcap C(B,X)$ . In particular, $\partial N(B,X)=\emptyset$ iff $B=X$ .

Proof.

Each simplex of $N(B,X)$ is contained in some $n$ -simplex, since $N(B,X)$ is made of dual cones and each of them is contained in the dual cone of a vertex of $B$ .

Each $(n-1)$ -simplex in $N(B,X)$ is contained in either an $n$ dual cone or an $(n-1)$ dual cone in $N(B,X)$ . For the first case, the $(n-1)$ -simplex must be contained in two $n$ -simplices and it intersects $B$ at the cone point. For the second case, it suffices that each $(n-1)$ dual cone of $N(B,X)$ is contained in one or two $n$ -dual cones. Since the $(n-1)$ dual cone must be the dual cone of some $1$ -simplex of $T$ and the $1$ -simplex is either in $B$ or not in $B$ . If it is in $B$ , then the $(n-1)$ dual cone is contained in the two $n$ dual cones of the boundary of the $1$ -simplex and the $(n-1)$ dual cone is not in $\partial N(B,X)$ . Otherwise, one vertex of the $1$ -simplex is in $B$ and the other vertex is not because $B$ is full in $T$ . Then the $(n-1)$ dual cone is contained in one $n$ dual cone in $B$ and it is in $\partial N(B,X)$ . ∎

The argument in the proof also shows that

Lemma 4.10.

If $B\neq X$ and $B$ is full, then $C(B,X)$ is also a pseudomanifold with boundary $\partial N(B,X)$ .

Lemma 4.11.

If $B$ is full in $X$ and $B\neq X$ , then $\partial N(B,X)$ is collared both in $N(B,X)$ and $C(B,X)$ .

Proof.

Due to the compactness, it suffices that $\partial N(B,X)$ is locally collared in both $N(B,X)$ and $C(B,X)$ ([7]). Any point $x\in\partial N(B,X)$ is contained in the interior of some simplex $\sigma^{i}$ of $T$ . Since $B$ is full, $\sigma^{i}$ has some vertices in $B$ and the other vertices are not in $B$ . Let $\alpha$ be the maximal face of $\sigma^{i}$ contained in $B$ and let $\beta$ be the maximal face of $\sigma^{i}$ that does not intersect $B$ . Then $\sigma^{i}$ is the join $\alpha*\beta$ . Hence a neighborhood of $x$ in $\partial N(B,X)$ is isomorphic to $\alpha\times\beta\times C(\sigma^{i})$ and the join product gives the collaring of $\alpha\times\beta\times C(\sigma^{i})$ in both $N(B,X)$ and $C(B,X)$ . ∎

5 Branched Covering

Definition 5.1.

Let $X$ and $Y$ be pseudomanifolds. A $k$ -fold branched covering map consists of a piecewise linear map $f:Y\rightarrow X$ and a closed sub-polyhedron $B\subset Y$ of codimension at least $2$ such that

(1) the preimage of each point $x\in X$ is a space of finitely many points;

(2) the restriction map $Y-B\rightarrow X-f(B)$ is a $k$ -fold covering map.

The sub-polyhedron $B\subset Y$ is called the branched part and $Y-B$ is called the unbranched part.

Example 5.2.

The identity map $X\rightarrow X$ with an arbitrary sub-polyhedron $B\subset X$ is a branched covering map.

Proposition 5.3.

Let $X$ be a pseudomanifold and $V$ be a closed sub-polyhedron of codimension at least $2$ . Let $f_{1}:Y_{1}\rightarrow X-V$ be a finite covering map. Then there exists a branched covering map $f:Y\rightarrow X$ extending $f_{1}$ with the branched part $f^{-1}(V)$ .

Indeed, there is an initial branched covering map $f:Y\rightarrow X$ extending $f_{1}$ in the sense that for any other branched covering map $f^{\prime}:Y^{\prime}\rightarrow X$ extending $f_{1}$ there is a $1$ -fold branched covering map $g:Y\rightarrow Y^{\prime}$ such that $f=g\circ f^{\prime}$ .

Proof.

Give $X$ a triangulation such that $V$ is a subcomplex. We may assume the codimension of $V$ is $2$ because for other cases the argument is the same. We are going to inductively construct the initial branched covering $f:Y\rightarrow X$ .

Let $V_{k}$ be the $(n-k)$ -skeleton of $V$ , where $n$ is the dimension of $X$ . Suppose we already construct the ‘initial’ branched covering $f_{k-1}:Y_{k-1}\rightarrow X-V_{k-1}$ for for some $k>1$ .

Let $\{\sigma^{n-k}_{i}\}$ be the set of all $(n-k)$ -simplices of $V$ . For each $\sigma^{n-k}_{i}$ , its link is a disjoint union of connected polyhedra $\bigsqcup_{l}L_{il}$ . For each $L_{il}$ , the preimage $f^{-1}_{k-1}(L_{il})$ is a disjoint union of connected polyhedra $\bigsqcup_{j}L^{\prime}_{ilj}$ . Then take the union of $Y_{k-1}$ with $\operatorname{Int}(\sigma^{n-k}_{ilj})\times C(L^{\prime}_{ilj})$ for all $i,l,j$ , where $C(L^{\prime}_{ilj})$ is the cone of $L^{\prime}_{ilj}$ . Let $Y_{k}$ be the union and extend $f_{k-1}$ to $f_{k}:Y_{k}\rightarrow X-V_{k}$ by mapping each $\operatorname{Int}(\sigma^{n-k}_{ilj})$ onto $\operatorname{Int}(\sigma^{n-k}_{i})$ . ∎

Definition 5.4.

Call such an initial branched covering map $f:Y\rightarrow X$ in 5.3 a normal branched covering map.

Remark 5.5.

With the same notation as in the proof, notice that the restricted map $L^{\prime}_{ilj}\rightarrow L_{il}$ between components of links is also a normal branched covering. In particular, when $k=2$ , each link component $L_{il}$ is piecewise linear homeomorphic to $S^{1}$ and the restricted map $L^{\prime}_{ilj}\rightarrow L_{il}$ is a finite covering map of $S^{1}$ .

Definition 5.6.

Let $X$ be a pseudomanifold. Define the étale site $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ of $X$ as follows. On the category level, the objects are normal branched covering maps $(f,B)$ , while a morphism $(f,B)\rightarrow(f^{\prime},B^{\prime})$ consists of a commutative diagram such that $B^{\prime}\subset\phi(B)$ and $(\phi,B)$ is also a normal branched covering map

A covering of $(f:Y\rightarrow X,B)$ is a finite collection of morphisms $\{\phi_{i}:(Y_{i},f_{i},B_{i})\rightarrow(Y,f,B)\}_{i\in I}$ such that $\bigcup_{i}\phi_{i}(Y_{i}-B_{i})=Y-B$ .

Remark 5.7.

5.3 implies that $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ admits all finite limits. Obviously, $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ also has all finite coproducts and $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ is connected if $X$ is connected.

6 Main Result

In this chapter, we prove a similar theorem for pseudomanifolds as the generalized Riemann existence theorem for complex varieties.

Theorem 6.1.

(generalized Riemann existence theorem for pseudomanifolds)

If $X$ is a pointed connected pseudomanifold, then $X_{\operatorname{\acute{e}t}}$ is isomorphic to the profinite completion of $X$ in the category $\operatorname{Pro}(\textbf{H}_{0})$ .

Lemma 6.2.

Let $K_{*}$ be a hypercovering of $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ . Then $\pi(K_{*})$ is an object of $\mathcal{C}\textbf{H}_{0}$ , i.e., its homotopy group $\pi_{n}\pi(K_{*})$ is a finite group for each $n$ .

Proof.

Change of the basepoint of $X$ does not change the result. Since the branched part of all branched covering maps in $K_{*}$ is countable. So we may change the basepoint of $X$ to the complement of the images of branched part.

The homotopy group $\pi_{n}\pi(K_{*})$ for some fixed $n$ is not affected by a change of skeletons of degree above $n+2$ . Hence, we may assume $K_{*}=\operatorname{Cosk}_{n}(K_{*})$ .

Hence there are only finitely many connected normal branched coverings in $K_{*}$ . Let us remove the image of the union of all branched partsand let $X^{\prime}$ be the complement. Consider the restriction of branched covering maps on the preimages of $X^{\prime}$ and they are all finite covering maps of $X^{\prime}$ .

Let $G$ be the fundamental groups of $X^{\prime}$ and let $\widehat{G}$ be the profinite completion of $G$ . Consider the preimage of the basepoint of $X^{\prime}$ . We get a hypercovering $H_{*}$ of the site $\operatorname{Fin}(\widehat{G})$ of finite continuous $\widehat{G}$ -sets. Notice that each coonected component of $K_{i}$ corresponds to a connected component of $\operatorname{Fin}(G)$ . Hence, $\pi(K_{*})=\pi(H_{*})$ . Then the lemma follows from 3.18. ∎

Let $\textbf{S}_{\operatorname{cl}}(X)$ be the site of open subsets of $X$ . To establish a connection between $\textbf{S}_{\operatorname{cl}}(X)$ and $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ , we need a common refinement. Let $\textbf{S}^{\prime}(X)$ be the site consisting of finite covering maps onto some open subset of $X$ . Then we have morphisms of pointed sites

\textbf{S}_{\operatorname{cl}}(X)\leftarrow\textbf{S}^{\prime}(X)\xrightarrow{f}\textbf{S}_{\operatorname{\acute{e}t}}(X)

Notice that each covering of $S^{\prime}(X)$ is dominated by a covering of $S_{\operatorname{cl}}(X)$ , i.e., we can cover a finite covering map by homeorphisms. Hence, $\pi(\textbf{S}^{\prime}(X))\rightarrow\pi(\textbf{S}_{\operatorname{cl}}(X))\rightarrow\operatorname{Sing}(X)$ is a weak equivalence of pro-spaces.

Let $G$ be a finite group. Any principal bundle $\mathfrak{G}$ with fiber $G$ over $\pi(\textbf{S}_{\operatorname{\acute{e}t}}(X))$ is also a principal bundle over $\textbf{S}^{\prime}(X)$ . So it induces a homomorphism $\pi_{1}(X)\rightarrow G$ . On the other hand, the kernel of any homomorphism $\pi_{1}(X)\rightarrow G$ corresponds to a finite covering space $X^{\prime}$ of $X$ and hence the trivial bundle over $X^{\prime}$ with fiber $G$ gives a principal bundle $\mathfrak{G}$ with fiber $G$ over $\pi(\textbf{S}_{\operatorname{\acute{e}t}}(X))$ . Due to 3.15, we get that

Lemma 6.3.

There is a natural bijection between $\operatorname{Hom}(\pi_{1}X,G)$ and $\operatorname{Hom}(\pi_{1}\pi(\textbf{S}_{\operatorname{\acute{e}t}}(X)),G)$ for any finite group $G$ .

Corollary 6.4.

(Comparison of Fundamental Groups)

\widehat{\pi_{1}X}\simeq\pi_{1}\pi(\textbf{S}_{\operatorname{\acute{e}t}}(X))

Let $A$ be a finite abelian group. Let $\mathfrak{A}$ be a locally constant sheaf with stalk $A$ on $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ , which induces a local system $\widetilde{A}$ on $X$ .

Proposition 6.5.

(Comparison of Cohomologies)

For any $q$ ,

H^{q}(X;\widetilde{A})\simeq H^{q}(\textbf{S}_{\operatorname{\acute{e}t}}(X);\mathfrak{A})

Proof.

We use the same symbol $\widetilde{A}$ to represent the induced locally constant sheaf on $\textbf{S}^{\prime}(X)$ . Consider the Leray spectral sequence

H^{q}(\textbf{S}_{\operatorname{\acute{e}t}}(X),R^{r}f_{*}\widetilde{A})\Rightarrow H^{q+r}(\textbf{S}^{\prime}(X),\widetilde{A})

Then the goal is to show that $R^{r}f_{*}\widetilde{A}=0$ for all $r\geq 1$ .

Notice that the sheaf $R^{r}f_{*}\widetilde{A}$ over $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ is induced by the presheaf which associates to each normal branched covering map $(Y\rightarrow X,B)$ the abelian group $H^{r}(Y-B;\widetilde{A})$ . Thus, we are left with the following statement. ∎

Lemma 6.6.

For any normal branched covering $(Y\rightarrow X,B)$ and for any element $t$ of $H^{r}(Y-B;\widetilde{A})$ with $r\geq 1$ , there exists a covering $\{Y_{i}\rightarrow Y,B_{i}\}$ such that $t$ vanishes in $H^{r}(Y_{i}-B_{i};\widetilde{A})$ for each $i$ .

Proof.

Since $\widetilde{A}$ is a sheaf of finite abelian groups, we can pass to a finite covering of $X$ such that $\widetilde{A}$ is a constant sheaf. So we will assume that $\widetilde{A}$ is a constant sheaf over $\textbf{S}^{\prime}(X)$ .

When $r=1$ , an element $t\in H^{1}(Y-B;\mathcal{A})$ represents a homomorphism $\pi_{1}(Y-B)\rightarrow A$ . Take the covering space of $Y-B$ corresponding to the kernel of the homomorphism. It is a finite covering space and the pullback of $t$ to the covering space is zero. We use 5.3 to complete it to be a normal branched covering over $Y$ .

When $r>1$ , it suffices to find a finite open cover $\{V_{i}\}$ of $Y-B$ satisfying that

(1) each $V_{i}$ is a $K(G_{i},1)$ space, where each $G_{i}$ has enough finite index subgroups, i.e., for any $d>0$ there is some subgroup $N$ of $G_{i}$ such that $d$ divides the index of $N$ ;

(2) $Y-B-V_{i}$ is a codimension at least $2$ subpolyhedron of $Y$ .

Pass to some covering space of $V_{i}$ so that the order of $t$ divides the number of fiber points. Then $t=0$ when lifting to the covering space. Use 5.3 again to complete it to a branched covering map $Y_{i}\rightarrow Y$ .

The claim is implied by the following two lemmas.

∎

Lemma 6.7.

Any pseudomanifold $Y$ admits a finite open cover $\{V_{i}\}$ such that each $Y-V_{i}$ is a codimension $2$ closed subpolyhedron of $Y$ and each $V_{i}$ is homotopy equivalent to a finite graph.

Proof.

Give $Y$ a finite triangulation. Let $B_{0}$ be the codimension $2$ skeleton in $Y$ and let $V_{0}=Y-B_{0}$ .

Now consider the barycentric subdivision of the triangulation of $Y$ with respect to a choice of barycenters. Let $B_{1}$ be the codimension $2$ coskeleton in $Y$ and $V_{1}=Y-B_{1}$ . Then $B_{0}$ and $B_{1}$ intersects transversally and their intersection is a codimension $4$ subpolyheadron.

Choose a second set of barycenters, disjoint from the first set, such that the dual cones of the second subdivision intersects the dual cones of the first subdivision transversally. Set $B_{2}$ to be codimension $2$ coskeleton of the second barycentric subdivision in $Y$ and let $V_{2}=Y-B_{2}$ . Then the intersection of $B_{0},B_{1},B_{2}$ is a codimension $6$ subpolyheadron.

Keep doing this. After finite steps the intersection of $B_{i}$ ’s is empty.

4.5 and 4.3 shows that each $V_{i}$ is either homotopy equivalent to the $1$ -skeleton or $1$ -coskeleton of $Y$ . ∎

Lemma 6.8.

Let $Y$ be a pseudomanifold of dimension $n$ and let $B$ be a codimension at least $2$ closed subpolyhedron of $Y$ . Then there exists a finite open cover $\{V_{i}\}$ of $Y-B$ such that each $Y-B-V_{i}$ is a codimension $2$ closed subpolyhedron of $Y$ and each $V_{i}$ is homotopy equivalent to a finite graph.

Proof.

Assume that $B\neq\emptyset$ and give $Y$ a triangulation so that $B$ is a full subcomplex.

With the same notation as before, we have proved that both $C(B,Y)$ and $N(B,Y)$ are pseudomanifolds of dimension $n$ with a common boundary $\partial N(B,Y)$ .

Let $B_{0}$ be the union of $\partial N(B,Y)$ and the codimension $2$ skeleton of $C(B,Y)$ . Let $V_{0}=C(B,Y)-B_{0}$ . 4.3 implies that $V_{0}$ contracts to the union of $1$ -dimensional coskeletons whose interiors have empty intersection with $\partial N(B,Y)$ .

Let $A_{1}$ be the codimension $2$ coskeleton of $C(Y,B)$ . Let $B_{1}=A_{1}\bigcup\partial N(B,Y)$ and let $V_{1}=C(B,Y)-B_{1}$ . We have shown that $\partial N(B,Y)$ is collared in $C(B,Y)$ . With the same argument, the pair $A_{1}\bigcap\partial N(B,Y)$ is also collared in $A_{1}$ . Hence the pair $(C(B,Y),V_{1})$ contracts to a subspace pair which is piecewise linear homeomorphic to $(C(B,Y),C(B,Y)-A_{1})$ . 4.5 implies that $C(B,Y)-A_{1}$ contracts to the $1$ skeleton of $C(B,Y)$ .

Now apply the same argument as the previous proof. We can vary the barycenters of $Y^{\prime}$ to create finitely many $B_{i}$ ’s so that the intersection of $B_{i}$ ’s is empty. Let $V_{i}=Y^{\prime}-B_{i}$ .

At last, the proof is done due to the fact that $Y-B$ is piecewise-linear isomorphic to $C(B,Y)-\partial N(B,Y)$ ([7]). ∎

Lastly, let us finish the proof of the main theorem.

Proof of Theorem 6.1.

With the previous lemmas and 3.16, we have proved that the morphism of sites $\textbf{S}_{\operatorname{cl}}(X)\leftarrow\textbf{S}^{\prime}(X)\xrightarrow{f}\textbf{S}_{\operatorname{\acute{e}t}}(X)$ induces a $\mathcal{C}$ -equivalence between $X_{\operatorname{\acute{e}t}}$ and $X$ , i.e., a weak equivalence between $X_{\operatorname{\acute{e}t}}$ and $\widehat{X}$ . It remains to prove that the sites $\textbf{S}_{\operatorname{cl}}(X)$ and $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ are both of local $\mathcal{C}$ -dimension at most $n$ , where $n$ is the dimension of $X$ . This is obvious for the site $\textbf{S}_{\operatorname{cl}}(X)$ .

Now let $(f:Y\rightarrow X,B)$ be any normal branched covering map and let $\mathfrak{A}$ be a locally constant sheaf on $\textbf{S}_{\operatorname{\acute{e}t}}(X)$ with stalk an finite abelian group $A$ . It is equivalent to a local system $\widetilde{A}$ on $X$ . We have shown that $R^{r}f_{*}\widetilde{A}=0$ for $r$ positive. The Leray spectral sequence also implies that $H^{*}_{\textbf{S}_{\operatorname{\acute{e}t}}(X)}((f,B);\mathfrak{A})\simeq H^{*}_{\textbf{S}^{\prime}(X)}((f,B);\widetilde{A})$ . But $H^{*}_{\textbf{S}^{\prime}(X)}((f,B);\widetilde{A})\simeq H^{*}(Y-B;\widetilde{A})$ . Thus it is $0$ for degree larger than $n$ . ∎

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