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Artin algebraization for pairs with applications to the local structure of stacks and Ferrand pushouts

Published online by Cambridge University Press:  01 February 2024

Jarod Alper
Affiliation:
Department of Mathematics, University of Washington, Box 354350, Seattle, WA 98195-4350, USA; E-mail: [email protected]
Jack Hall
Affiliation:
School of Mathematics & Statistics, The University of Melbourne, Parkville, VIC 3010, Australia; E-mail: [email protected]
Daniel Halpern-Leistner
Affiliation:
Department of Mathematics, Cornell University, 310 Mallot Hall, Ithaca, NY 14853, USA; E-mail: [email protected]
David Rydh
Affiliation:
KTH Royal Institute of Technology, Department of Mathematics, SE-100 44 Stockholm Sweden; E-mail: [email protected]

Abstract

We give a variant of Artin algebraization along closed subschemes and closed substacks. Our main application is the existence of étale, smooth or syntomic neighborhoods of closed subschemes and closed substacks. In particular, we prove local structure theorems for stacks and their derived counterparts and the existence of henselizations along linearly fundamental closed substacks. These results establish the existence of Ferrand pushouts, which answers positively a question of Temkin–Tyomkin.

Type
Algebraic and Complex Geometry
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1. Introduction

The main technical result of this paper is a generalization of Artin’s algebraization theorem [Reference ArtinArt69, Thm. 1.6]: from algebraizations of complete local rings to algebraizations of rings complete along an ideal. It is proven using Artin approximation over henselian pairs following the approach of [Reference Conrad and de JongCJ02] and [Reference Alper, Hall and RydhAHR20, App. A].

Theorem 1.1 (Artin algebraization for pairs)

Let S be an excellent affine scheme, and let $\mathscr {X}$ be a category fibered in groupoids, locally of finite presentation over S. Let Z be an affine scheme over S, complete along a closed subscheme $Z_0$ . Assume that $Z_0\to S$ is of finite type. Let $\eta \colon Z\to \mathscr {X}$ be a morphism, formally versal at $Z_0$ . Then there exist

  1. (1) an affine scheme W of finite type over S,

  2. (2) a closed subscheme $W_0\hookrightarrow W$ ,

  3. (3) a morphism $\xi \colon W\to \mathscr {X}$ over S and

  4. (4) a morphism $\varphi \colon (Z,Z_0)\to (W,W_0)$ over S

such that the induced morphism $\widehat {\varphi }\colon Z\to \widehat {W}$ is an isomorphism and the isomorphism $\varphi _n\colon Z_n\to W_n$ on infinitesimal neighborhoods is compatible with $\eta $ and $\xi $ for every n.

We prove a more general version when Z is a stack in Theorem 2.3. This generalizes [Reference Alper, Hall and RydhAHR20, App. A] and is used to establish a local structure theorem for stacks (Theorem 1.3). We will return to this shortly.

Application: Étale neighborhoods of affine subschemes

As an application of Theorem 1.1, we have the existence of affine étale neighborhoods.

Theorem 1.2 (Affine étale neighborhoods)

Let $\mathscr {X}$ be a quasi-separated algebraic stack with affine stabilizers, and consider a diagram

where $\mathscr {X}_0\hookrightarrow \mathscr {X}$ is a closed immersion and $f_0\colon W_0\to \mathscr {X}_0$ is an étale (resp. smooth) morphism with $W_0$ affine. Then there exist an affine scheme W and an étale (resp. smooth) morphism $f\colon W\to \mathscr {X}$ such that $f|_{\mathscr {X}_0}=f_0$ .

If $\mathscr {X}$ is an affine scheme, then Theorem 1.2 is [SP, 04D1] ( $f_0$ étale) and [Reference ElkikElk73, Thm. 6] ( $f_0$ smooth). For nonaffine schemes and algebraic spaces, these results are new and answer positively a question of Temkin and Tyomkin [Reference Temkin and TyomkinTT16, Qstn. 5.3].

Application: Local structure of stacks

We now generalize Theorem 1.2 from extending affine étale neighborhoods to extending linearly fundamental étale neighborhoods. By definition, an algebraic stack $\mathscr {X}$ is fundamental if there is an affine morphism $\mathscr {X} \to B\mathrm {GL}_{n, \mathbb {Z}}$ for some n, and linearly fundamental if it is fundamental and cohomologically affine; see [Reference Alper, Hall and RydhAHR19, §2.2] for further discussion.

In order to formulate mixed-characteristic versions of the local structure results, we recall from [Reference Alper, Hall and RydhAHR19, §7] the following conditions on an algebraic stack $\mathscr {X}$ .

  • (FC) There is only a finite number of different characteristics in $\mathscr {X}$ .

  • (PC) Every closed point of $\mathscr {X}$ has positive characteristic.

  • (N) Every closed point of $\mathscr {X}$ has a nice stabilizer [Reference Hall and RydhHR15, Defn. 1.1] (i.e., is an extension of a finite linearly reductive group scheme by an algebraic group of multiplicative type).

If $\mathscr {X}$ is linearly fundamental, then (PC) $\implies $ (N) as linearly reductive group schemes in positive characteristic are nice [Reference NagataNag62], [Reference Hall and RydhHR15, Thm. 1.2]. The condition that we often impose will be of the following form for some morphism of stacks $\mathscr {W}_0\to \mathscr {X}$ : Assume either that $\mathscr {W}_0$ satisfies (N), or $\mathscr {X}$ satisfies (FC).

We also remind the reader of another type of algebraic stack from [Reference Alper, Hall and RydhAHR19, §2.2]: An algebraic stack $\mathscr {X}$ is nicely fundamental if it admits an affine morphism to $B_SQ$ , where $Q \to S$ is a nice and embeddable group scheme over S. It follows that nicely fundamental stacks are linearly fundamental.

Theorem 1.3 (Local structure of stacks)

Let S be an excellent algebraic space, and let $\mathscr {X}$ be an algebraic stack, quasi-separated and locally of finite presentation over S with affine stabilizer groups. Consider a diagram

where $\mathscr {X}_0\hookrightarrow \mathscr {X}$ is a closed immersion and $f_0\colon \mathscr {W}_0\to \mathscr {X}_0$ is a morphism of algebraic stacks with $\mathscr {W}_0$ linearly fundamental.

  1. (1) If $f_0$ is smooth (resp. étale), then there exists a smooth (resp. étale) morphism $f\colon \mathscr {W}\to \mathscr {X}$ such that $\mathscr {W}$ is fundamental and $f|_{\mathscr {X}_0}\simeq f_0$ .

  2. (2) Assume that $\mathscr {W}_0$ satisfies (PC) or (N) or $\mathscr {X}_0$ satisfies (FC). If $f_0$ is syntomic and $\mathscr {X}_0$ has the resolution property, then there exists a syntomic morphism $f\colon \mathscr {W}\to \mathscr {X}$ such that $\mathscr {W}$ is fundamental and $f|_{\mathscr {X}_0}\cong f_0$ .

Syntomic means flat and locally of finite presentation, with fibers that are local complete intersections. An important example in our context is that any morphism $BG\to \mathscr {G}_x$ is smooth in characteristic zero but merely syntomic in positive characteristic.

For further refinements on $\mathscr {W}$ , see Theorems 1.5 and 1.6 below and [Reference Alper, Hall and RydhAHR19, §8.1, §8.3]. For a non-Noetherian version, see Theorem 5.1. We also have the following result.

Theorem 1.4 (Local structure of stacks at nonclosed points)

Let $\mathscr {X}$ be a quasi-separated algebraic stack with affine stabilizer groups. Let $x\in |\mathscr {X}|$ be a point with residual gerbe $\mathscr {G}_x$ , and let $f_0\colon \mathscr {W}_0\to \mathscr {G}_x$ be a syntomic (resp. smooth, resp. étale) morphism with $\mathscr {W}_0$ linearly fundamental. Then there exists a syntomic (resp. smooth, resp. étale) morphism $f\colon \mathscr {W}\to \mathscr {X}$ such that $\mathscr {W}$ is fundamental and $f|_{\mathscr {G}_x}\cong f_0$ .

We give a more general version for pro-affine-immersions in Theorem 5.8. Note that the inclusions $\mathscr {X}_0 \hookrightarrow \mathscr {X}$ of a closed substack in Theorem 1.3 and $\mathscr {G}_x \hookrightarrow \mathscr {X}$ of a residual gerbe in Theorem 1.4 are both pro-affine-immersions. We also have refinements on the local charts (cf. [Reference Alper, Hall and RydhAHR19, Prop. 5.7 and Cor. 8.7]).

Theorem 1.5 (Refinement 1)

Let $\mathscr {W}$ be a fundamental stack. Let $\mathscr {W}_0\hookrightarrow \mathscr {W}$ be a pro-affine-immersion. Assume that $\mathscr {W}_0$ is linearly fundamental and satisfies (PC), (N) or (FC). If $g\colon \mathscr {W}\to \mathscr {X}$ is a morphism to an algebraic stack with affine (resp. separated) diagonal, such that $g|_{\mathscr {W}_0}$ is representable, then there exists an étale neighborhood $\mathscr {W}'\to \mathscr {W}$ of $\mathscr {W}_0$ such that $\mathscr {W}'$ is fundamental and $g|_{\mathscr {W}'}$ is affine (resp. representable).

Theorem 1.6 (Refinement 2)

Let $\mathscr {W}$ be a fundamental stack and $\mathscr {W}_0\hookrightarrow \mathscr {W}$ be a pro-affine-immersion. Assume that $\mathscr {W}_0$ is linearly fundamental and that either $\mathscr {W}_0$ satisfies (PC), (N) or $\mathscr {W}$ satisfies (FC). Then there exists an étale neighborhood $\mathscr {W}'\to \mathscr {W}$ of $\mathscr {W}_0$ such that $\mathscr {W}'$ is linearly fundamental. Moreover,

  1. (1) If $\mathscr {W}_0=[\operatorname {\mathrm {Spec}} A_0/G_0]$ , where $G_0$ is a linearly reductive (resp. nice) and embeddable group scheme over the good moduli space $W_0$ , then we can arrange so that $\mathscr {W}'=[\operatorname {\mathrm {Spec}} A/G]$ , where G is a linearly reductive (resp. nice) and embeddable group scheme over the good moduli space $W'$ , such that $G|_{W_0} \cong G_0$ .

  2. (2) Suppose that $\mathscr {W}$ is defined over a base algebraic space S and that $G\to S$ is an affine flat group scheme of finite presentation. If $\mathscr {W}_0=[\operatorname {\mathrm {Spec}} A_0/G]$ , then we can arrange so that $\mathscr {W}'=[\operatorname {\mathrm {Spec}} A/G]$ .

Application: Henselizations

The henselization of an algebraic stack $\mathscr {X}$ along a morphism $\nu \colon \mathscr {W} \to \mathscr {X}$ is an initial object in the 2-category of 2-commutative diagrams

where $f \colon \mathscr {X}' \to \mathscr {X}$ is pro-étale. Recall that $f \colon \mathscr {X}' \to \mathscr {X}$ is called pro-étale if it is an inverse limit of quasi-separated étale neighborhoods $\mathscr {X}_\lambda \to \mathscr {X}$ such that the transition maps $\mathscr {X}_\lambda \to \mathscr {X}_\mu $ are affine for all sufficiently large $\lambda \geq \mu $ . Note that we do not require that f is representable or separated.

Theorem 1.7 (Existence of henselizations)

Let $\mathscr {X}$ be a quasi-separated algebraic stack with affine stabilizers. Let $\nu \colon \mathscr {X}_0 \hookrightarrow \mathscr {X}$ either be the inclusion of a closed substack satisfying (PC), (N) or (FC); or the inclusion of a residual gerbe. If $\mathscr {X}_0$ is linearly fundamental, then the henselization $\mathscr {X}_{\nu }^{h}$ of $\mathscr {X}$ along $\nu $ exists. Moreover, $\mathscr {X}_{\nu }^{h}$ is linearly fundamental and $(\mathscr {X}_{\nu }^{h}, \mathscr {X}_0)$ is a henselian pair.

When $\mathscr {X}$ is an affine scheme, then Theorem 1.7 is [Reference RaynaudRay70, Ch. XI, Thm. 2]. The result is new for nonaffine schemes and algebraic spaces. It is also closely related to, but does not settle, conjectures of Greco and Strano on henselian schemes [Reference Greco and StranoGS81, Conj. A, B and C].

Note that there are no analogous results for open neighborhoods: There are schemes with affine closed subschemes that do not admit affine neighborhoods. Indeed, there is a separated scheme with two closed points that does not admit an affine open neighborhood and such that the semilocalization at the two points does not exist. See Appendix A.

Application: Ferrand pushouts

As an application of Theorem 1.2, we can prove that Ferrand pushouts [Reference FerrandFer03, Reference Temkin and TyomkinTT16] exist for algebraic spaces and algebraic stacks. In the affine case, these are Milnor squares [Reference MilnorMil71, §2] and it follows that these are pushouts in the category of quasi-separated algebraic stacks.

Theorem 1.8 (Existence of Ferrand pushouts)

Consider a diagram

of quasi-separated algebraic stacks, where i is a closed immersion and f is affine. Then the pushout $\mathscr {Y}$ exists in the category of quasi-separated algebraic stacks and is a geometric pushout. If $\mathscr {X}_0$ , $\mathscr {Y}_0$ and $\mathscr {X}$ are Deligne–Mumford stacks (resp. algebraic spaces, resp. affine schemes), then so is $\mathscr {Y}$ .

Theorem 1.8 generalizes the main theorem of [Reference Temkin and TyomkinTT16], where certain pushouts of algebraic spaces are proven to exist.

Application: Nisnevich neighborhoods

The following application is used in [Reference Hoyois and KrishnaHK19] and is a simple consequence of the local structure at nonclosed points (Theorem 1.4).

Theorem 1.9 (Nisnevich neighborhoods of stacks with nice stabilizers)

Let $\mathscr {X}$ be a quasi-compact and quasi-separated algebraic stack such that every, not necessarily closed, point of $\mathscr {X}$ has a nice stabilizer group. Then there is a Nisnevich covering $f\colon \mathscr {W}\to \mathscr {X}$ , where $\mathscr {W}$ is nicely fundamental. That is,

  1. (1) f is étale and for every, not necessarily closed, point $x\in |\mathscr {X}|$ the restriction $f|_{\mathscr {G}_x}$ has a section.

  2. (2) $\mathscr {W}$ admits an affine good moduli space W and there is a nice embeddable group scheme $G\to W$ such that $\mathscr {W}=[\operatorname {\mathrm {Spec}} A/G]$ .

If $\mathscr {X}$ has affine (resp. separated) diagonal, then we can arrange that f is affine (resp. representable).

Remark 1.10. When $\mathscr {X}$ is an algebraic stack with a good moduli space such that every point of characteristic zero has an open neighborhood of characteristic zero, then $\mathscr {X}$ has a strong Nisnevich neighborhood of the form $[\operatorname {\mathrm {Spec}} A/G]$ with G linearly reductive [Reference Alper, Hall and RydhAHR19, Thm. 6.1]. Here, strong means that the Nisnevich neighborhood is a pullback from a Nisnevich cover of the good moduli space. Note that the condition that $\mathscr {X}$ admits a good moduli space implies that every closed point has linearly reductive stabilizer.

In the case of linearly reductive stabilizers at closed points, we have the following result.

Theorem 1.11 (Nisnevich neighborhoods of stacks with linearly reductive stabilizers at closed points)

Let $\mathscr {X}$ be a quasi-compact and quasi-separated algebraic stack with affine stabilizers and linearly reductive stabilizers at closed points. Assume that $\mathscr {X}$ has separated (resp. quasi-affine, resp. affine) diagonal. Then there is a Nisnevich covering $f\colon [V/\mathrm {GL}_m] \to \mathscr {X}$ , where V is a quasi-compact separated algebraic space (resp. quasi-affine scheme, resp. affine scheme). In general, the morphism f is not representable but if $\mathscr {X}$ has affine diagonal we can also arrange so that f is affine.

When $\mathscr {X}$ has affine diagonal, the Nisnevich covering is fundamental but not always linearly fundamental. If $\mathscr {X}$ is the stack quotient of the nonseparated affine line by $\mathbb {Z}/2\mathbb {Z} \times \mathbb {G}_m$ [Reference Alper, Hall and RydhAHR20, Ex. 5.2], then the unique closed point has stabilizer $\mathbb {G}_m$ whereas the open point has stabilizer $\mathbb {Z}/2\mathbb {Z}$ . Every Nisnevich covering will thus have a point with stabilizer $\mathbb {Z}/2\mathbb {Z}$ and such stacks are not linearly fundamental in characteristic $2$ .

Application: Compact generation

Let $\mathscr {X}$ be a quasi-compact and quasi-separated algebraic stack and consider its unbounded derived category of $\mathcal {O}_{\mathscr {X}}$ -modules with quasi-coherent cohomology sheaves $\mathrm {D}_{\mathsf {QCoh}}(\mathscr {X})$ . A vexing question over the years has been whether the category $\mathrm {D}_{\mathsf {QCoh}}(\mathscr {X})$ is compactly generated. In this situation, this is equivalent to finding a set of perfect complexes $\{P_\lambda \}_{\lambda \in \Lambda }$ on $\mathscr {X}$ such that

  1. (a) if $M \in \mathrm {D}_{\mathsf {QCoh}}(\mathscr {X})$ and $\operatorname {\mathrm {Hom}}_{\mathcal {O}_{\mathscr {X}}}(P_\lambda ,M) = 0$ for all $\lambda \in \Lambda $ , then $M = 0$ and

  2. (b) the functor $\operatorname {\mathrm {Hom}}_{\mathscr {X}}(P_\lambda ,-) \colon \mathrm {D}_{\mathsf {QCoh}}(\mathscr {X}) \to \mathsf {Ab}$ preserves small coproducts for all $\lambda \in \Lambda $ .

For schemes, definitive positive results go back to the pioneering work of [Reference Thomason and TrobaughTT90, Reference NeemanNee96]. For a thorough discussion on the subtleties of this question for algebraic stacks, we refer the interested reader to [Reference Hall and RydhHR17, Reference Hall, Neeman and RydhHNR19].

A lot of progress was made on this question for stacks in [Reference Alper, Hall and RydhAHR20, Thm. 5.1] and [Reference Alper, Hall and RydhAHR19, Prop. 6.14], however. More precisely, [Reference Alper, Hall and RydhAHR20, Thm. 5.1] established compact generation provided that $\mathscr {X}$ had affine diagonal and the identity component $G_x^0$ of the stabilizer groups $G_x$ of $\mathscr {X}$ at all closed points x of $\mathscr {X}$ were linearly reductive. It was shown in [Reference Hall, Neeman and RydhHNR19, Thm. 1.1], however, that if $\mathscr {X}$ had a point of positive characteristic y such that the reduced identity component $(G_y)_{\mathrm {red}}^0$ was not a torus, then $\mathrm {D}_{\mathsf {QCoh}}(\mathscr {X})$ was not compactly generated. In the following theorem we eliminate this discrepancy and give the following characterization of algebraic stacks in positive characteristic that have compactly generated derived categories.

Theorem 1.12. (Compact generation in positive characteristic)

Let $\mathscr {X}$ be a quasi-compact algebraic stack with affine diagonal satisfying (PC). The following conditions are equivalent.

  1. (1) $\mathscr {X}$ is $\aleph _0$ -crisp [Reference Hall and RydhHR17, Defn. 8.1].

  2. (2) $\mathrm {D}_{\mathsf {QCoh}}(\mathscr {X})$ is compactly generated and for every closed subset $Z \subseteq |\mathscr {X}|$ with quasi-compact complement, there exists a perfect complex P on $\mathscr {X}$ with $\mathrm {supp}(P) = Z$ .

  3. (3) $\mathrm {D}_{\mathsf {QCoh}}(\mathscr {X})$ is compactly generated.

  4. (4) For every point x of $\mathscr {X}$ , the reduced identity component $(G_x)_{\mathrm {red}}^0$ of the stabilizer $G_x$ at x is a torus.

  5. (5) For every closed point x of $\mathscr {X}$ , the reduced identity component $(G_x)_{\mathrm {red}}^0$ of the stabilizer $G_x$ at x is a torus.

We will prove Theorem 1.12 immediately after the non-Noetherian local structure Theorem 5.1, and make use of the refinements established in [Reference Alper, Hall and RydhAHR19].

Application: Local structure theorem of derived algebraic stacks

We now come to the derived versions of our local structure results. Recall that a morphism f of derived stacks is quasi-smooth if f is locally of finite presentation and its cotangent complex $\mathbb {L}_f$ has Tor-amplitude $\leq 1$ . This is the analogue of local complete intersection maps in derived algebraic geometry.

Theorem 1.13 (Local structure of derived stacks)

Let $\mathscr {X}$ be a quasi-separated algebraic derived $1$ -stack with affine stabilizers. Let $\mathscr {X}_0\hookrightarrow \mathscr {X}$ be a closed substack, and let $f_0\colon \mathscr {W}_0\to \mathscr {X}_0$ be a morphism with $(\mathscr {W}_0)_{\mathrm {cl}}$ linearly fundamental. Assume one of the following conditions:

  1. (1) $\mathscr {W}_0$ satisfies (PC) or (N), or

  2. (2) $\mathscr {X}_0$ satisfies (FC).

Then

  1. (a) If $f_0$ is smooth (resp. étale), then there exists a smooth (resp. étale) morphism $f\colon \mathscr {W}\to \mathscr {X}$ such that $\mathscr {W}$ is fundamental and $f|_{\mathscr {X}_0}\cong f_0$ .

  2. (b) Assume that $(\mathscr {X}_0)_{\mathrm {cl}}$ has the resolution property. If $f_0$ is quasi-smooth, then there exists a quasi-smooth morphism $f\colon \mathscr {W}\to \mathscr {X}$ such that $\mathscr {W}$ is fundamental and $f|_{\mathscr {X}_0}\cong f_0$ (here the restriction denotes the derived pullback).

It follows from Proposition 6.1 that $\mathscr {X}$ is linearly fundamental if and only if the underlying classical stack $\mathscr {X}_{\mathrm {cl}}$ is linearly fundamental. See Section 6 for further discussion.

Application: Local structure of a $\Theta $ -stratum

Let $\mathscr {S}$ be a quasi-separated algebraic stack, and let $\mathscr {X}$ be an algebraic stack, quasi-separated and locally of finite presentation over $\mathscr {S}$ with affine stabilizers relative to $\mathscr {S}$ . Let $\Theta := [\mathbb {A}^1 / \mathbb {G}_m]$ ; then the mapping stack $\mathrm {Filt}(\mathscr {X}):=\underline {\operatorname {\mathrm {Map}}}_{\mathscr {S}}(\Theta _{\mathscr {S}},\mathscr {X})$ is also algebraic, locally of finite presentation, quasi-separated and has affine stabilizers relative to $\mathscr {S}$ [Reference Halpern-LeistnerHL14, Prop. 1.1.2]. A $\Theta $ -stratum in $\mathscr {X}$ is by definition an open and closed substack $\mathscr {Y} \subset \mathrm {Filt}(\mathscr {X})$ such that the morphism $\mathscr {Y} \to \mathscr {X}$ defined by restricting to $1 \in \Theta $ is a closed immersion so that we may also regard $\mathscr {Y}$ as a closed substack of $\mathscr {X}$ (see [Reference Halpern-LeistnerHL14, Defn. 2.1.1]).

Stratifications by closed substacks of this kind arise in geometric invariant theory, as well as on moduli stacks such as the moduli of torsion-free sheaves on a projective scheme. In [Reference Alper, Halpern-Leistner and HeinlothAHLH23, Lem. 6.11], the following local structure result was established using our Theorem 5.1, and it is key to proving the semistable reduction theorem [Reference Alper, Halpern-Leistner and HeinlothAHLH23, Thm. 6.3].

Proposition 1.14. Let S be a Noetherian algebraic space. Let $\mathscr {X}$ be an algebraic stack of finite type over S with affine diagonal over S. If $\mathscr {Y} \hookrightarrow \mathscr {X}$ is a $\Theta $ -stratum, then there is a smooth representable morphism $p \colon [\operatorname {\mathrm {Spec}}(A)/\mathbb {G}_m] \to \mathscr {X}$ such that $\mathscr {Y}$ is contained in the image of p, and $p^{-1}(\mathscr {Y})$ is the $\Theta $ -stratum

$$\begin{align*}p^{-1}(\mathscr{Y}) = [\operatorname{\mathrm{Spec}}(A/I_+)/\mathbb{G}_m] \hookrightarrow [\operatorname{\mathrm{Spec}}(A)/\mathbb{G}_m], \end{align*}$$

where $I_+ \subset A$ is the ideal generated by elements of positive degree.

2. Artin algebraization

In this section, we prove Artin’s algebraization theorem for linearly fundamental pairs (Theorem 2.3) which establishes Theorem 1.1 as a special case. In order to state the theorem, we will need the following terminology.

Definition 2.1. A pair $(\mathscr {X},\mathscr {X}_0)$ consists of an algebraic stack $\mathscr {X}$ and a closed substack $\mathscr {X}_0$ . We let $\mathcal {I}_{\mathscr {X}}$ denote the ideal defining $\mathscr {X}_0$ and let $\mathscr {X}_n$ denote the nth infinitesimal neighborhood of $\mathscr {X}_0$ , that is, the closed substack defined by $\mathcal {I}_{\mathscr {X}}^{n+1}$ . We say that a pair $(\mathscr {X}, \mathscr {X}_0)$ has a given property $\mathcal {P}$ (e.g., linearly fundamental) if both $\mathscr {X}$ and $\mathscr {X}_0$ have $\mathcal {P}$ .

A morphism of pairs $(\mathscr {X},\mathscr {X}_0)\to (\mathscr {Y},\mathscr {Y}_0)$ is a morphism $f\colon \mathscr {X}\to \mathscr {Y}$ such that $\mathscr {X}_0\hookrightarrow f^{-1}(\mathscr {Y}_0)$ , or equivalently, $f^{-1}\mathcal {I}_{\mathscr {Y}}\subseteq \mathcal {I}_{\mathscr {X}}$ . For any $n\geq 0$ , we let $f_n\colon \mathscr {X}_n\to \mathscr {Y}_n$ denote the induced morphism. We say that f is adic if $\mathscr {X}_0=f^{-1}(\mathscr {Y}_0)$ .

Note that if f is adic, then $\mathscr {X}_n=f^{-1}(\mathscr {Y}_n)$ for all n.

Definition 2.2. Let $f\colon \mathscr {Z} \to \mathscr {X}$ be a morphism of functors or stacks (e.g., schemes or algebraic spaces). Let T be an algebraic stack and $T\to \mathscr {Z}$ a morphism. We say that f is formally versal at T if the following condition holds: For all nilpotent immersions $T\hookrightarrow T'\hookrightarrow T"$ and $2$ -commutative diagrams of solid arrows

there exist a lift $T"\to \mathscr {Z}$ and $2$ -morphisms that make the whole diagram $2$ -commutative.

Our main theorem is the following result, which generalizes [Reference Alper, Hall and RydhAHR20, Cor. A.19] and [Reference Alper, Hall and RydhAHR19, Thm. 5.6].

Theorem 2.3 (Algebraization of linearly fundamental pairs)

Let S be an excellent affine scheme. Let $\mathscr {X}$ be an algebraic stack, locally of finite type over S with quasi-separated diagonal. Let $(\mathscr {Z},\mathscr {Z}_0)$ be a complete linearly fundamental pair (Definition 2.5) over S such that $\mathscr {Z}_0$ is of finite type over S. Let $\eta \colon \mathscr {Z}\to \mathscr {X}$ be a morphism, formally versal at $\mathscr {Z}_0$ . Then there exist

  1. (1) a fundamental pair $(\mathscr {W},\mathscr {W}_0)$ such that $\mathscr {W}\to S$ is of finite type and $\mathscr {W}_0$ is linearly fundamental;

  2. (2) a morphism $\varphi \colon (\mathscr {Z},\mathscr {Z}_0)\to (\mathscr {W},\mathscr {W}_0)$ such that $\varphi _n\colon \mathscr {Z}_n \to \mathscr {W}_n$ is an isomorphism for all $n \geq 0$ ; and

  3. (3) a $2$ -commutative diagram over S

In particular, the induced map $\widehat {\varphi }\colon \mathscr {Z} \to \widehat {\mathscr {W}}$ is an isomorphism and $\xi $ is smooth in a neighborhood of $\mathscr {W}_0$ .

Remark 2.4. Most of the statement of the theorem remains valid, with the same proof, when $\mathscr {X}$ is an arbitrary category fibered in groupoids that is locally of finite presentation over S. The only difference is that instead of a $2$ -isomorphism $\xi \circ \varphi \simeq \eta $ , one only obtains a compatible family of $2$ -isomorphisms $\xi \circ \varphi |_{\mathscr {Z}_n} \simeq \eta |_{\mathscr {Z}_n}$ for all $n\geq 0$ .

We prove this theorem at the end of the section after discussing some background material on pairs. We first explain how this theorem implies Theorem 1.1.

Proof of Theorem 1.1

Applying Theorem 2.3 and Remark 2.4 with $(\mathscr {Z}, \mathscr {Z}_0) := (Z, Z_0)$ gives a fundamental pair $(\mathscr {W}, \mathscr {W}_0)$ with $\mathscr {W}_0 \cong Z_0$ . Since $Z_0$ is affine, we may apply [Reference Alper, Hall and RydhAHR19, Prop. 5.7] to the morphism $\mathscr {W} \to S$ to conclude that there is an affine open neighborhood $U \subset \mathscr {W}$ of $Z_0$ . Replacing $(\mathscr {W}, \mathscr {W}_0)$ with $(U, Z_0)$ gives the result.

2.1. Coherently complete pairs

The following definition was introduced in [Reference Alper, Hall and RydhAHR20] and was further studied in [Reference Alper, Hall and RydhAHR19].

Definition 2.5. We say that a pair $(\mathscr {X},\mathscr {X}_0)$ is complete, or that $\mathscr {X}$ is coherently complete along $\mathscr {X}_0$ , if $\mathscr {X}$ is Noetherian with affine diagonal and the induced functor $\mathsf {Coh}(\mathscr {X})\to \varprojlim _n \mathsf {Coh}(\mathscr {X}_n)$ is an equivalence of abelian categories of coherent sheaves.

By Tannaka duality [Reference Hall and RydhHR19], we have that $\mathscr {X}$ is the colimit of $\{\mathscr {X}_n\}_{n\geq 0}$ in the category of Noetherian stacks with quasi-affine diagonal and also in the category of Noetherian stacks with affine stabilizers if $\mathscr {X}_0$ is quasi-excellent.

Let $(\mathscr {X},\mathscr {X}_0)$ be a linearly fundamental Noetherian pair. The good moduli space X is a Noetherian affine scheme and $\pi \colon \mathscr {X}\to X$ is of finite type. This gives a morphism of pairs $(\mathscr {X},\mathscr {X}_0)\to (X,X_0)$ , where $X_0=\pi (\mathscr {X}_0)$ . The pair $(\mathscr {X},\mathscr {X}_0)$ is complete if and only if $(X,X_0)$ is complete [Reference Alper, Hall and RydhAHR19, Thm. 1.6]. The latter simply means that if $X=\operatorname {\mathrm {Spec}} A$ and $X_0=\operatorname {\mathrm {Spec}} A/I$ , then A is I-adically complete.

If $(\mathscr {X},\mathscr {X}_0)$ is a fundamental Noetherian pair such that $\mathscr {X}_0$ is linearly fundamental, then $(\widehat {\mathscr {X}},\mathscr {X}_0)$ is a complete linearly fundamental pair, where $\widehat {\mathscr {X}}=\mathscr {X}\times _X \widehat {X}$ and $\widehat {X}=\operatorname {\mathrm {Spec}} \widehat {A}$ is the I-adic completion. Indeed, the completion factors through the Zariskification $\mathscr {X}\times _X \operatorname {\mathrm {Spec}} \bigl ( (1+I)^{-1}A \bigr )$ , which is linearly fundamental by [Reference Alper, Hall and RydhAHR19, Cor. 6.10].

2.2. Preliminary results on pairs

In this section, we provide criteria to check that a morphism of pairs is a closed immersion or isomorphism (Proposition 2.9) or is formally versal (Lemma 2.10).

Lemma 2.6 [Reference VasconcelosVas69, Prop. 1.2]

Let A be a ring and let $\phi \colon M\to N$ be a surjective homomorphism of finitely generated A-modules. If there exists an A-module isomorphism $M\cong N$ , then $\phi $ is an isomorphism.

Proof. We identify N with M and treat $\phi $ as an endomorphism of M. Then M is also a module over $A[t]$ where $tx=\phi (x)$ for $x\in M$ . Since $\phi $ is surjective $tM=M$ and Nakayama’s lemma tells us that there is an element $a\in A[t]$ such that $(1-at)M=0$ . That is, $\phi $ has inverse given by $\phi ^{-1}(x)=ax$ .

Lemma 2.7. Suppose that $I\subseteq R$ is an ideal and $\varphi \colon R\to S$ is a surjective homomorphism of Noetherian rings. If there is an abstract isomorphism of graded $R/I$ -modules $\operatorname {\mathrm {Gr}}_I R\to \operatorname {\mathrm {Gr}}_{IS} S$ and R is separated for the I-adic topology, then $\varphi $ is an isomorphism.

Proof. Since $\varphi $ is surjective, it induces a surjection $\operatorname {\mathrm {Gr}}_n \varphi \colon I^n/I^{n+1}\to I^nS/I^{n+1}S$ of finitely generated $R/I$ -modules. By assumption, there is an abstract isomorphism $I^n/I^{n+1}\to I^nS/I^{n+1}S$ of $R/I$ -modules, so $\operatorname {\mathrm {Gr}}_n \varphi $ is an isomorphism by Lemma 2.6.

We have induced morphisms of exact sequences

and it follows that $\varphi _d\colon R/I^d\to S/I^dS$ is an isomorphism for every $d\geq 0$ by induction on d. In particular, $\ker \varphi \subseteq I^d$ for all $d\geq 0$ . But R is separated for the I-adic topology, so $\ker \varphi \subseteq \bigcap _{d\geq 0} I^d = (0)$ and the result follows.

The following results generalize [Reference Alper, Hall and RydhAHR20, Props. A.8 and A.10] from the local case.

Proposition 2.8. Let $f\colon (\mathscr {X},\mathscr {X}_0)\to (\mathscr {Y},\mathscr {Y}_0)$ be a morphism of Noetherian pairs.

  1. (1) If $f_1$ is a closed immersion, then so is $f_n$ for every $n\geq 0$ .

  2. (2) If $f_1$ is a closed immersion and $f_0$ is an isomorphism, then $f_n$ is adic for every $n\geq 0$ .

  3. (3) If $f_1$ is a closed immersion and there exists an isomorphism of graded $\mathcal {O}_{\mathscr {Y}_0}$ -modules $\psi \colon \operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {Y}}}(\mathcal {O}_{\mathscr {Y}})\to (f_0)_*\operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {X}}}(\mathcal {O}_{\mathscr {X}})$ , then $f_n$ is an isomorphism for every $n\geq 0$ .

Proof. We can replace f with $f_n$ . The first part is then [Reference Alper, Hall and RydhAHR19, Lem. 4.10]: The question is local and reduces to the affine case where it follows from Nakayama’s lemma. For the second part, we have seen that $f_n$ is a closed immersion and then it is adic if and only if $f_0$ is an isomorphism. The third part is also local and thus follows from Lemma 2.7.

Proposition 2.9. Let $f\colon (\mathscr {X},\mathscr {X}_0)\to (\mathscr {Y},\mathscr {Y}_0)$ be a morphism of complete pairs such that $f_0$ is an isomorphism.

  1. (1) f is a closed immersion if and only if $f_1$ is a closed immersion.

  2. (2) f is an isomorphism if and only if $f_1$ is a closed immersion and there exists an isomorphism $\psi \colon \operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {Y}}}(\mathcal {O}_{\mathscr {Y}}) \to (f_0)_*\operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {X}}}(\mathcal {O}_{\mathscr {X}})$ of graded $\mathcal {O}_{\mathscr {Y}_0}$ -modules.

Proof. The conditions are clearly necessary. Conversely, if the conditions of (1) (resp. (2)) hold, then $f_n$ is adic and a closed immersion (resp. an isomorphism) for every $n\geq 0$ by Proposition 2.8. Since $f_n$ is adic, we have that $f_n^{-1}(\mathscr {Y}_m)=\mathscr {X}_m$ for all $m\leq n$ . Since $\mathscr {Y}$ is coherently complete along $\mathscr {Y}_0$ , we obtain a closed substack $\mathscr {Z}\hookrightarrow \mathscr {Y}$ such that $\mathscr {Z}\times _{\mathscr {Y}} \mathscr {Y}_n=\mathscr {X}_n$ for all $n\geq 0$ . Under condition (2), we have that $\mathscr {Z}=\mathscr {Y}$ . Finally, since $(\mathscr {X},\mathscr {X}_0)$ is complete, we have by Tannaka duality a unique isomorphism $\mathscr {X}\to \mathscr {Z}$ over $\mathscr {Y}$ .

Let X be a quasi-compact and quasi-separated algebraic stack. Recall [Reference Hall and RydhHR17, Defn. 2.1] that X is said to have cohomological dimension $0$ if $\mathrm {H}^i(X,M) = 0$ for all $i>0$ and quasi-coherent $\mathcal {O}_X$ -modules M. Affine schemes have cohomological dimension $0$ . More generally, cohomologically affine algebraic stacks that have affine diagonal or are Noetherian and affine-pointed also have cohomological dimension $0$ [Reference Hall, Neeman and RydhHNR19, Thm. C.1].

Lemma 2.10. Let $f\colon (\mathscr {Z},\mathscr {Z}_0) \to (\mathscr {X},\mathscr {X}_0)$ be a morphism of locally Noetherian pairs. If $f_n\colon \mathscr {Z}_n \to \mathscr {X}_n$ is smooth for all $n\geq 0$ , then f is formally versal at any morphism $T \to \mathscr {Z}$ from a quasi-compact and quasi-separated algebraic stack T of cohomological dimension $0$ whose set theoretic image is contained in $|\mathscr {Z}_0|$ .

Proof. The lifting criterion in Definition 2.2 is equivalent to the same criterion for the map $f_n\colon \mathscr {Z}_n \to \mathscr {X}_n$ for $n \gg 0$ large enough that $\mathscr {Z}_n$ contains the image of $T'$ and $\mathscr {X}_n$ contains the image of $T"$ , so by our hypotheses we may assume that the map f is smooth. First, note that $T'$ has cohomological dimension $0$ because any quasi-coherent $\mathcal {O}_{T'}$ -module admits a finite filtration whose associated graded objects are pushforwards of objects in $\mathsf {QCoh}(T)$ . Also, because we may factor $T' \to T"$ into a sequence of square-zero extensions, it suffices to verify the lifting criterion in the case where $T' \to T"$ is a square-zero extension by some $M \in \mathsf {QCoh}(T')$ . In this case the obstruction to the existence of a dotted arrow is an element in the group $\operatorname {\mathrm {Ext}}^1_{T'}(\mathbb {L}_{\mathscr {Z}/\mathscr {X}}|_{T'},M)$ . Since f is smooth, $\mathbb {L}_{\mathscr {Z}/\mathscr {X}}$ is a perfect complex of Tor-amplitude $[0,1]$ . Hence, the $\operatorname {\mathrm {Ext}}$ group vanishes as $T'$ has cohomological dimension $0$ .

2.3. Proof of Theorem 2.3

First, we establish an important special case of Artin algebraization for pairs.

Lemma 2.11. Let $(S,S_0)$ be an excellent affine pair, let $(T,T_0)$ be a complete affine pair and let $f\colon (T,T_0)\to (S,S_0)$ be a morphism such that $f_0$ is an isomorphism and $f_1$ is a closed immersion. Let $\mathscr {X}$ be a finite type algebraic stack over S, and let $\mathscr {Z}_0 \hookrightarrow \mathscr {Z}:=T \times _S \mathscr {X}$ be a closed substack over $T_0$ . For any $N\geq 0$ , there is an affine étale neighborhood $(S',S^{\prime }_0)\to (S,S_0)$ and a closed substack $\mathscr {W} \hookrightarrow S' \times _S \mathscr {X}$ such that:

  1. (1) The map $T \to S$ factors through $S'$ , and $T_N \to S^{\prime }_N$ is a closed immersion;

  2. (2) $T_N \times _T \mathscr {Z} = S^{\prime }_N \times _{S'} \mathscr {W}$ as closed substacks of $S^{\prime }_N \times _S \mathscr {X}$ . In particular, if $\mathscr {W}_0 := \mathscr {Z}_0 \hookrightarrow \mathscr {W}$ , then the canonical map is an isomorphism $\mathscr {Z}_N \cong \mathscr {W}_N$ and

  3. (3) There is an isomorphism $\operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {Z}}} \mathcal {O}_{\mathscr {Z}} \cong \operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {W}}} \mathcal {O}_{\mathscr {W}}$ of graded modules over $\mathscr {Z}_0 \cong \mathscr {W}_0$ .

Proof. Consider the functor $F\colon \mathsf {Sch}_{/S}^{\mathrm {op}}\to \mathsf {Set}$ , where $F(U\to S)$ is the set of isomorphism classes of complexes of finitely presented quasi-coherent $\mathcal {O}_{U \times _S \mathscr {X}}$ -modules $\mathcal {E}_2\to \mathcal {E}_1\to \mathcal {O}_{U \times _S \mathscr {X}}$ such that $\mathcal {E}_1$ is locally free. This functor is locally of finite presentation.

Let $\widehat {S}$ be the completion of S along $S_0$ . Then $T \to \widehat {S}$ is a closed immersion by Proposition 2.9, because $(T,T_0)$ is complete, $f_0$ is an isomorphism and $f_1$ is a closed immersion. Now let

$$\begin{align*}\mathcal{O}_{\widehat{S}}^{\oplus n} \to \mathcal{O}_{\widehat{S}} \twoheadrightarrow \mathcal{O}_{T} \end{align*}$$

be a presentation of the structure sheaf of $T \hookrightarrow \widehat {S}$ . Pulling back to $\widehat {S} \times _S \mathscr {X}$ we get a resolution

$$\begin{align*}\ker(\beta) \xrightarrow{\alpha} \mathcal{O}_{\widehat{S} \times_S \mathscr{X}}^{\oplus n} \xrightarrow{\beta} \mathcal{O}_{\widehat{S} \times_S \mathscr{X}} \twoheadrightarrow \mathcal{O}_{T \times_S \mathscr{X}}. \end{align*}$$

We regard the pair $(\alpha ,\beta )$ as an element of $F(\widehat {S})$ . Note that by increasing N if necessary, we may assume that both $\alpha $ and $\beta $ satisfy the Artin–Rees condition $\mathrm {(AR)_{N}}$ of [Reference Alper, Hall and RydhAHR20, Def. A.15] with respect to $\mathscr {Z}_0$ .

Let $(S^h,S_0)$ denote the henselization of the pair $(S,S_0)$ . By Artin approximation over henselian pairs [Reference Alper, Hall and RydhAHR19, Thm. 3.4], one can find a class in $F(S^h)$ which restricts to the same class as $(\alpha ,\beta )$ in $F(S_N)$ . Then because $S^h$ is constructed as an inverse limit of étale neighborhoods of $S_0$ , we lift this class in $F(S^h)$ to a class $(\alpha ',\beta ') \in F(S')$ for some étale map $S' \to S$ lying under $S^h$ such that $S' \times _S S_0 \simeq S_0$ .

We now let $\mathscr {W} \hookrightarrow S' \times _S \mathscr {X}$ be the closed substack defined by $\operatorname {\mathrm {im}}(\beta ') \subset \mathcal {O}_{S' \times _S \mathscr {X}}$ . By construction, we have

$$\begin{align*}\mathcal{O}_{\mathscr{W}} \otimes_{\mathcal{O}_{S' \times_S \mathscr{X}}} \mathcal{O}_{S^{\prime}_N} \simeq \operatorname{\mathrm{coker}}(\beta'|_{S^{\prime}_N}) \simeq \mathcal{O}_{T_N \times_S \mathscr{X}} \end{align*}$$

as $\mathcal {O}_{S' \times _S \mathscr {X}}$ -algebras, which is the second condition of the lemma.

Now, consider $(\alpha ,\beta ) \in F(\widehat {S})$ and the restriction of $(\alpha ',\beta ')$ to $F(\widehat {S})$ . Both complexes are isomorphic after tensoring with $\mathcal {O}_{S_N}$ , and by hypothesis the complex defined by $(\alpha ,\beta )$ is exact and satisfies the Artin–Rees criterion $\mathrm {(AR)_{N}}$ , so the refined Artin–Rees theorem [Reference Alper, Hall and RydhAHR20, Thm. A.16] implies that

$$\begin{align*}\operatorname{\mathrm{Gr}}_{\mathcal{I}_{\mathscr{Z}}} \mathcal{O}_{\mathscr{Z}} \cong \operatorname{\mathrm{Gr}}_{\mathcal{I}_{\mathscr{Z}}} (\operatorname{\mathrm{coker}}(\beta)) \cong \operatorname{\mathrm{Gr}}_{\mathcal{I}_{\mathscr{W}}} ( \operatorname{\mathrm{coker}}(\beta')) \cong \operatorname{\mathrm{Gr}}_{\mathcal{I}_{\mathscr{W}}} \mathcal{O}_{\mathscr{W}}.\\[-36pt] \end{align*}$$

The following generalizes [Reference Alper, Hall and RydhAHR20, Thm. A.17].

Proposition 2.12 (Weak Artin algebraization for pairs)

Let S be an excellent affine scheme, and let $\mathscr {X}$ be a category fibered in groupoids, locally of finite presentation over S. Let $(T,T_0)$ be a Noetherian affine pair over S such that $T_0\to S$ is of finite type. Let $(\mathscr {Z},\mathscr {Z}_0)\to (T,T_0)$ be a morphism of finite presentation and let $\eta \colon \mathscr {Z}\to \mathscr {X}$ be a morphism compatible over S. Fix an integer $N \geq 0$ . Then there exist

  1. (1) a pair $(\mathscr {W},\mathscr {W}_0)$ of finite presentation over S, together with a morphism $\xi \colon \mathscr {W}\to \mathscr {X}$ ;

  2. (2) an isomorphism $\mathscr {Z}_N \cong \mathscr {W}_N$ over $\mathscr {X}$ ; and

  3. (3) an isomorphism $\operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {Z}}}\mathcal {O}_{\mathscr {Z}}\cong \operatorname {\mathrm {Gr}}_{\mathcal {I}_{\mathscr {W}}}\mathcal {O}_{\mathscr {W}}$ of graded modules over $\mathscr {Z}_0\cong \mathscr {W}_0$ .

Moreover, if $\mathscr {Z}$ is fundamental, then one can arrange that $\mathscr {W}$ is fundamental.

Proof. It suffices to prove the claims after base change to the completion of T, so we may assume that T is complete along $T_0$ . Now, write

$$ \begin{align*}T = \varprojlim_\lambda T_\lambda,\end{align*} $$

where $T_\lambda $ is a cofiltered system of affine S-schemes of finite type. For $\lambda $ sufficiently large, $T_1 \to T_\lambda $ is a closed immersion. Increasing $\lambda $ if necessary, standard limit methods give us an algebraic stack $\mathscr {Z}_\lambda $ of finite presentation over $T_\lambda $ fitting into a commutative diagram

(1)

It now suffices to replace S with $T_\lambda $ , and $\mathscr {X}$ with $\mathscr {Z}_\lambda $ , and to find a stack over $\mathscr {Z}_\lambda $ meeting the conditions of the theorem. We may therefore assume that $\mathscr {X}$ is algebraic and of finite presentation over S, and that $T_1 \to S$ is a closed immersion, in which case the theorem follows immediately from Lemma 2.11 with $S_0$ as the image of $T_0$ .

Finally, if $\mathscr {Z}$ were fundamental, meaning $\mathscr {Z}$ admits an affine map $f\colon \mathscr {Z} \to B\mathrm {GL}_{n,\mathbb {Z}}$ for some n, then in this case one can simultaneously approximate both the map f and the map $\mathscr {Z} \to \mathscr {X}$ by replacing $\mathscr {X}$ with $\mathscr {X} \times _S (B\mathrm {GL}_{n,S})$ in the argument above. The map $\mathscr {Z} \to B \mathrm {GL}_{n,S}$ is affine, so [Reference RydhRyd15, Thm. C] guarantees that we can arrange for $\mathscr {Z}_\lambda $ in (1) to be affine over $B \mathrm {GL}_{n,S}$ as well. The stack $\mathscr {W}$ constructed in Lemma 2.11 will be affine over $B\mathrm {GL}_{n,S}$ as well, hence fundamental.

We now prove our main algebraization theorem:

Proof of Theorem 2.3

Let T be the good moduli space of $\mathscr {Z}$ and $T_0$ the good moduli space of $\mathscr {Z}_0$ . Choose an $N \geq 1$ . Then $T_0\to S$ is of finite type, so Proposition 2.12 produces a stack $\mathscr {W}$ satisfying the first two conditions of the theorem along with a map $\xi \colon \mathscr {W} \to \mathscr {X}$ and an isomorphism $\psi _N\colon \mathscr {W}_N \cong \mathscr {Z}_N$ over $\mathscr {X}$ .

We would like to extend the isomorphism $\psi _N$ to a compatible sequence of isomorphisms $\psi _n\colon \mathscr {W}_n \to \mathscr {Z}_n$ over $\mathscr {X}$ for all $n\geq N$ . Extending the map $\psi _n$ to $\psi _{n+1}$ is equivalent to finding a dotted arrow such that the diagram

is $2$ -commutative. It is possible to do this for all $n \geq N$ because by hypothesis the map $\eta $ is formally versal at $\mathscr {W}_0 = \mathscr {Z}_0$ (see Definition 2.2). The resulting sequence of maps $\psi _n\colon \mathscr {W}_n \to \mathscr {Z}_n$ and the induced map $\widehat {\psi }\colon \widehat {\mathscr {W}} \to \mathscr {Z}$ are isomorphisms by Proposition 2.9 and part (3) of Proposition 2.12. If we define $\varphi $ to be the inverse of $\psi $ followed by the canonical map $\widehat {\mathscr {W}} \to \mathscr {W}$ , then by construction we have a compatible sequence of $2$ -isomorphisms $\xi \circ \varphi |_{\mathscr {Z}_{n}} \cong \eta |_{\mathscr {Z}_{n}}$ for all $n\geq 1$ .

If $\mathscr {X}$ is an algebraic stack with quasi-separated diagonal, then the stack $I := \operatorname {\mathrm {Isom}}_{\mathscr {Z}} (\xi \circ \varphi , \eta )$ is a quasi-separated algebraic space, locally of finite type over $\mathscr {Z}$ . The $2$ -isomorphisms $\xi \circ \varphi |_{\mathscr {Z}_n} \cong \eta |_{\mathscr {Z}_n}$ give a compatible sequence of sections $\sigma _n$ of $I \to \mathscr {Z}$ over $\mathscr {Z}_n$ for all $n \geq 1$ . The image of all of the $\sigma _n$ lie in some quasi-compact open substack $I' \subset I$ , so we may replace I with $I'$ . Then Tannaka duality implies that there is a unique section $\sigma \colon \mathscr {Z} \to I' \subset I$ of $I \to \mathscr {Z}$ , which corresponds to a $2$ -isomorphism $\xi \circ \varphi \simeq \eta $ satisfying the conditions of the theorem.

3. Affine étale neighborhoods

In this section we prove the existence of affine étale neighborhoods (Theorem 1.2).

Proof of Theorem 1.2

Step 1: Reduction to $\mathscr {X}$ of finite presentation over $\mathbb {Z}$ . We may replace $\mathscr {X}$ with an open quasi-compact neighborhood of the image of $W_0$ . Then $\mathscr {X}$ is quasi-compact and quasi-separated and hence of approximation type [Reference RydhRyd23]Footnote 1 .

We can thus write $\mathscr {X}_0$ as the intersection of finitely presented closed immersions $\mathscr {X}_\lambda \hookrightarrow \mathscr {X}$ [Reference RydhRyd15, Thm. D]. Using standard limit methods, we can thus, for sufficiently large $\lambda $ , find an étale (resp. smooth) morphism $f_\lambda \colon W_\lambda \to \mathscr {X}_\lambda $ that restricts to $f_0 \colon W_0 \to \mathscr {X}_0$ [Reference RydhRyd15, App. B]. After replacing $f_0$ with $f_\lambda $ we can thus assume that $\mathscr {X}_0\hookrightarrow \mathscr {X}$ is of finite presentation.

Using [Reference RydhRyd15, Thm. D] we can now write $\mathscr {X}$ as an inverse limit of stacks of finite presentation over $\operatorname {\mathrm {Spec}} \mathbb {Z}$ . Using standard limit methods, we can thus arrange so that the étale (resp. smooth) map $f_0\colon W_0\to \mathscr {X}_0$ and the closed immersion $\mathscr {X}_0\hookrightarrow \mathscr {X}$ arise as the pull-backs from stacks of finite presentation over $\operatorname {\mathrm {Spec}} \mathbb {Z}$ [Reference RydhRyd15, App. B].

In the two reduction steps above, we can also arrange so that $W_0$ remains affine by [Reference RydhRyd15, Thm. C]. We can thus assume that $\mathscr {X}$ is of finite presentation over $\operatorname {\mathrm {Spec}} \mathbb {Z}$ .

Step 2: Existence of affine formal neighborhoods. Let $\mathscr {X}_n$ denote the nth infinitesimal neighborhood of $\mathscr {X}_0$ in $\mathscr {X}$ . We claim that $f_0 \colon W_0 \to \mathscr {X}_0$ lifts to a compatible sequence of Cartesian squares

such that each $f_n$ is étale (resp. smooth). Indeed, by [Reference OlssonOls06, Thm. 1.4], the obstruction to lifting $f_{n-1}$ to $f_n$ belongs to the group

$$\begin{align*}\operatorname{\mathrm{Ext}}^2_{\mathcal{O}_{W_{0}}}\bigl(\mathbb{L}_{W_0/\mathscr{X}_0},f_0^*(\mathcal{I}^n/\mathcal{I}^{n+1})\bigr), \end{align*}$$

where $\mathcal {I}$ is the coherent ideal sheaf defining $\mathscr {X}_0 \hookrightarrow \mathscr {X}$ . This group is zero since $\mathbb {L}_{W_0/\mathscr {X}_0} = \Omega _{W_0/\mathscr {X}_0}[0]$ is a vector bundle and $W_0$ is affine.

Since $W_0$ is affine, each $W_n$ is also affine [Reference KnutsonKnu71, Cor. 3.6], [Reference RydhRyd15, Cor. 8.2]. It follows from [Reference GrothendieckEGAI, Cor. 0.7.2.8] that $Z:= \operatorname {\mathrm {Spec}} \big ( \varprojlim _n \Gamma (W_n,\mathcal {O}_{W_n}) \big )$ is a Noetherian affine scheme complete along $W_0$ such that $W_i$ is the ith infinitesimal neighborhood of $W_0$ in Z. By Tannaka duality [Reference Hall and RydhHR19], there is an induced morphism $\eta \colon Z\to \mathscr {X}$ which is formally versal at $W_0$ (Lemma 2.10). Note that Tannaka duality applies because we assume that $\mathscr {X}$ has affine stabilizers.

Step 3: Existence of étale neighborhoods. Applying Artin algebraization for pairs (Theorem 1.1) yields an affine scheme W of finite type over $\operatorname {\mathrm {Spec}} \mathbb {Z}$ , a closed immersion $W_0 \hookrightarrow W$ , an isomorphism $\widehat {W} \to Z$ and a morphism $f \colon W \to \mathscr {X}$ extending $\eta |_{W_n}$ for all n; in particular, $f \colon W \to \mathscr {X}$ is étale (resp. smooth) along $W_0$ . The preimage $f^{-1}(\mathscr {X}_0)$ is a closed subscheme of W which agrees with $W_0$ after restricting to the Zariski-localization of W along $W_0$ . Therefore, there is an affine open subscheme $W' \subset W$ containing $W_0$ such that $f|_{W'}$ extends $f_0$ . This finishes the proof of Theorem 1.2.

The following example shows that Theorem 1.2 does not hold if the stabilizers of $\mathscr {X}$ are (1) infinite discrete, or (2) abelian varieties, or (3) $\mathscr {X}$ is a $2$ -stack with affine double diagonal. This was communicated to us by K. Česnavičius.

Example 3.1. Let $S_0\hookrightarrow \mathbb {A}^2_{\mathbb {C}}$ be the affine nodal cubic, and let S be the completion of $\mathbb {A}^2_{\mathbb {C}}$ along $S_0$ . There exists a nontrivial connected $\mathbb {Z}$ -torsor $E_0\to S_0$ : an infinite chain of $\mathbb {A}^1_{\mathbb {C}}$ ’s [SGA3II, Exp. X, 1.6]. Let $\mathscr {X}=S \times B\mathbb {Z}$ , $\mathscr {X}_0=S_0 \times B\mathbb {Z}$ , and let $f_0\colon W_0=S_0 \to \mathscr {X}_0$ correspond to the torsor $E_0\to S_0$ . If $f_0$ extends to a map $f\colon W\to \mathscr {X}$ as in Theorem 1.2, then $W\to S$ has a section. This section gives a $\mathbb {Z}$ -torsor $E\to S$ extending $E_0 \to S_0$ . But S is normal so $E \to S$ must be the trivial $\mathbb {Z}$ -torsor, which is a contradiction.

Similarly, if A is an abelian variety over $\mathbb {C}$ and $P\in A(\mathbb {C})$ is a nontorsion point, then inducing the $\mathbb {Z}$ -torsor $E_0 \to S_0$ along the homomorphism $p\colon \mathbb {Z}\to A \colon n\mapsto nP$ produces an A-torsor $F_0\to S_0$ of infinite order which cannot extend to an A-torsor $F\to S$ . Indeed, every A-torsor over the regular scheme S has finite order, cf. [Reference BhattBha16, Ex. 4.12]. This gives a counterexample with $\mathscr {X}=S\times BA$ .

Similarly, for a suitable nonnormal affine irreducible surface $S_0\hookrightarrow \mathbb {A}_{\mathbb {C}}^n$ , there is a nontorsion element $H^2(S_0,\mathbb {G}_m)$ which does not lift to $H^2(S,\mathbb {G}_m)$ [Reference BhattBha16, Ex. 4.13]. This shows that Theorem 1.2 does not hold for the $2$ -stack $\mathscr {X}=S\times B^2\mathbb {G}_m$ .

4. Existence of geometric pushouts

In this section, we prove Theorem 1.8, on the existence of pushouts of algebraic stacks. The exposition will follow [Reference HallHal17, App. A] closely, where a useful special case of this result was established. We begin with a definition.

Definition 4.1. Fix a $2$ -commutative square of algebraic stacks

where ${i}$ and ${i}'$ are closed immersions and f and $f'$ are affine. If the induced map

$$\begin{align*}\mathcal{O}_{\mathscr{X}_3} \to {i}^{\prime}_*\mathcal{O}_{\mathscr{X}_2} \times_{({i}'f)_*\mathcal{O}_{\mathscr{X}_0}} f^{\prime}_*\mathcal{O}_{\mathscr{X}_1} \end{align*}$$

is an isomorphism of sheaves, then we say that the square is a geometric pushout, and that $\mathscr {X}_3$ is a geometric pushout of the diagram $[\mathscr {X}_2 \xleftarrow {f} \mathscr {X}_0 \xrightarrow {{i}} \mathscr {X}_1]$ .

The main result of this section is the following refinement of Theorem 1.8. It also generalizes [Reference HallHal17, Prop. A.2] from the case of a locally nilpotent closed immersion to a general closed immersion.

Theorem 4.2. Any diagram of algebraic stacks $[\mathscr {X}_2 \xleftarrow {f} \mathscr {X}_0 \xrightarrow {i} \mathscr {X}_1]$ , where i is a closed immersion, f is affine, and $\mathscr {X}_1$ is quasi-separated, admits a geometric pushout $\mathscr {X}_3$ . The resulting geometric pushout square is $2$ -Cartesian and $2$ -co-Cartesian in the $2$ -category of algebraic stacks with quasi-separated diagonals. If $\mathscr {X}_1$ and $\mathscr {X}_2$ are quasi-compact (resp. quasi-separated, resp. Deligne–Mumford, resp. algebraic spaces, resp. affine schemes), then so is $\mathscr {X}_3$ .

We will need the following two lemmas—the first is precisely [Reference HallHal17, Lem. A.3] and the second is a mild extension of [Reference HallHal17, Lem. A.4].

Lemma 4.3. Fix a $2$ -commutative square of algebraic stacks

  1. (1) If the square is a geometric pushout, then it is $2$ -Cartesian.

  2. (2) If the square is a geometric pushout, then it remains so after flat base change on $\mathscr {X}_3$ .

  3. (3) If after faithfully flat and locally finitely presented base change on $\mathscr {X}_3$ the square is a geometric pushout, then it was a geometric pushout prior to base change.

Proof. The claim (1) is local on $\mathscr {X}_3$ for the smooth topology, thus we may assume that everything in sight is affine—whence the result follows from [Reference FerrandFer03, Thm. 2.2]. Claims (2) and (3) are trivial applications of flat descent.

Lemma 4.4. Consider a $2$ -commutative diagram of algebraic stacks

where the back and left faces of the cube are $2$ -Cartesian and the top and bottom faces are geometric pushout squares. Then all faces of the cube are $2$ -Cartesian. Moreover, if the morphisms $\mathscr {U}_1 \to \mathscr {X}_1$ and $\mathscr {U}_2 \to \mathscr {X}_2$ have one of the following properties:

  1. (1) flat;

  2. (2) surjective;

  3. (3) locally of finite type;

  4. (4) flat and locally of finite presentation; or

  5. (5) smooth;

then the morphism $\mathscr {U}_3 \to \mathscr {X}_3$ has the same property.

Proof. By Lemma 4.3 (2), this is all smooth local on $\mathscr {X}_3$ and $\mathscr {U}_3$ ; thus, we immediately reduce to the case where everything in sight is affine. Fix a diagram of rings $[A_2 \rightarrow A_0 \xleftarrow {p} A_1]$ , where $p \colon A_1\to A_0$ is surjective. For $j=0$ , $1$ , $2$ fix $A_j$ -algebras $B_j$ and $A_0$ -isomorphisms $B_2\otimes _{A_2} A_0 \cong B_0$ and $B_1\otimes _{A_1} A_0 \cong B_0$ . Set $A_3 = A_2\times _{A_0} A_1$ and $B_3 = B_2\times _{B_0} B_1$ , then we first have to prove that the natural maps $B_3\otimes _{A_3} A_j \to B_j$ are isomorphisms and that these isomorphisms are compatible with the given isomorphisms. This is an immediate consequence of [Reference FerrandFer03, Thm. 2.2(i)] since these are just questions about modules.

Case (1) similarly follows from [Reference FerrandFer03, Thm. 2.2(iv)]. Case (2) follows from the observation that $|\mathscr {X}_1| \amalg |\mathscr {X}_2| \to |\mathscr {X}_3|$ and $|\mathscr {U}_1| \amalg |\mathscr {U}_2| \to |\mathscr {U}_3|$ are surjective [Reference FerrandFer03, Sch. 4.3 & Thm. 5.1]. Case (5) follows from (4), the surjectivity of $|\mathscr {X}_1| \amalg |\mathscr {X}_2| \to |\mathscr {X}_3|$ already remarked, and the observation that smoothness is a fibral criterion for morphisms that are flat and locally of finite presentation.

For (3), we argue as follows: By [Reference FerrandFer03, Thm. 2.2(ii)], an $A_3$ -module $W_3$ is zero if and only if the modules $W_3\otimes _{A_3} A_1$ and $W_3\otimes _{A_3} A_2$ are zero. Now, write $B_3$ as the union of its finite type $A_3$ -subalgebras $B_{3,\lambda }$ . As filtered direct limits commute with tensor products, it follows that for sufficiently large $\lambda $ , the homomorphisms $B_{3,\lambda }\otimes _{A_3} A_1 \to B_1$ and $B_{3,\lambda }\otimes _{A_3} A_2 \to B_2$ are surjective. Looking at the cokernel, it follows that $B_{3,\lambda } \to B_3$ is surjective.

For (4): If $B_j$ is a flat $A_j$ -algebra of finite presentation for $j=1$ , $2$ , then we know by (3) that $B_3$ is of finite type. Hence, we can choose a surjection $P_3=A_3[x_1,\ldots ,x_n] \twoheadrightarrow B_3$ . Let $J_3$ be the kernel. Since $B_3$ is $A_3$ -flat, the sequence

$$\begin{align*}0 \to J_3\to P_3\to B_3 \to 0 \end{align*}$$

remains exact after tensoring by any $A_3$ -algebra. In particular, $J_j = J_3 \otimes _{A_3} A_j$ is a $P_j = P_3 \otimes _{A_3} A_j$ -module of finite type for $j=1$ , $2$ . It now follows from Ferrand’s case of finite type modules (over the co-Cartesian square defined by the $P_j$ ) that $J_3$ is a $P_3$ -module of finite type; hence, $B_3$ is an $A_3$ -algebra of finite presentation.

We now come to an important lemma, where we make use of Theorem 1.2 in a critical way. Note that the proof is almost identical to [Reference HallHal17, Lem. A.8].

Lemma 4.5. Fix a $2$ -commutative square of algebraic stacks

If the square is a geometric pushout, then the square is $2$ -Cartesian and $2$ -co-Cartesian in the $2$ -category of algebraic stacks with quasi-separated diagonals.

Proof. That the square is $2$ -Cartesian is Lemma 4.3 (1). It remains to show that we can uniquely complete all $2$ -commutative diagrams of algebraic stacks

with a map $\mathscr {X}_3\to \mathscr {W}$ and compatible $2$ -isomorphisms. By smooth descent, this is smooth-local on $\mathscr {X}_3$ , so we may reduce to the situation where the $\mathscr {X}_j=\operatorname {\mathrm {Spec}} A_j$ are all affine schemes. Since $\mathscr {X}_3$ is a geometric pushout of the diagram $[\mathscr {X}_2\xleftarrow {f} \mathscr {X}_0 \xrightarrow {i} \mathscr {X}_1]$ , it follows that $A_3\cong A_2\times _{A_0} A_1$ .

Let $q \colon \operatorname {\mathrm {Spec}} B \to \mathscr {W}$ be a smooth morphism such that the pullback $v_j \colon U_j \to \mathscr {X}_j$ of q along $\psi _j$ is surjective for $j\in \{0,1,2\}$ , which exists because the $\mathscr {X}_j$ are all quasi-compact. There are compatibly induced morphisms of quasi-separated algebraic spaces $\psi _{j,B} \colon U_j \to \operatorname {\mathrm {Spec}} B$ for $j=1$ and $2$ and $f_B \colon U_0 \to U_2$ and $i_B \colon U_0 \hookrightarrow U_1$ .

Let $c_2 \colon \operatorname {\mathrm {Spec}} C_2 \to U_2$ be an étale morphism such that $v_2\circ c_2$ is smooth and surjective. The morphism $c_2$ pulls back along $f_B$ to give an étale morphism $c_0\colon \operatorname {\mathrm {Spec}} C_0 \to U_0$ such that $v_0\circ c_0$ is smooth and surjective. Let $\tilde {f} \colon \operatorname {\mathrm {Spec}} C_0 \to \operatorname {\mathrm {Spec}} C_2$ and $\tilde {\psi }_2 \colon \operatorname {\mathrm {Spec}} C_2 \to \operatorname {\mathrm {Spec}} B$ be the resulting morphisms.

Since $c_0$ is étale and $i_B$ is a closed immersion, it follows that there is an étale morphism $c_1\colon \operatorname {\mathrm {Spec}} C_1 \to U_1$ whose pullback along $i_B$ is isomorphic to $c_0$ (Theorem 1.2). It can easily be arranged that $v_1 \circ c_1$ is smooth and surjective. Let $C_3 = C_2\times _{C_0} C_1$ . Then there is a uniquely induced ring homomorphism $A_3 \to C_3$ . By Lemma 4.4, the morphism $c_3\colon \operatorname {\mathrm {Spec}} C_3 \to \operatorname {\mathrm {Spec}} A_3$ is smooth and surjective. Hence, we may replace $\operatorname {\mathrm {Spec}} A_j$ by $\operatorname {\mathrm {Spec}} C_j$ and further assume that the $\psi _j$ for $j=0$ , $1$ , and $2$ factor through some smooth morphism $q\colon \operatorname {\mathrm {Spec}} B \to \mathscr {W}$ . In particular, there is an induced morphism $\psi _3\colon \operatorname {\mathrm {Spec}} A_3 \to \operatorname {\mathrm {Spec}} B \to \mathscr {W}$ .

It remains to prove that the morphism $\psi _3$ is unique up to a unique choice of $2$ -morphism. Let $\psi _3$ and $\psi _3'\colon \operatorname {\mathrm {Spec}} A_3 \to \mathscr {W}$ be two compatible morphisms. That these morphisms are isomorphic can be checked smooth-locally on $\operatorname {\mathrm {Spec}} A_3$ . But smooth-locally, the morphisms $\psi _3$ and $\psi ^{\prime }_3$ both factor through some $\operatorname {\mathrm {Spec}} B \to \mathscr {W}$ and the morphisms $\operatorname {\mathrm {Spec}} A_j \to \operatorname {\mathrm {Spec}} A_3 \to \operatorname {\mathrm {Spec}} B$ coincide for $j=0$ , $1$ and $2$ , thus $\psi _3$ and $\psi ^{\prime }_3$ are isomorphic. To show that the isomorphism between $\psi _3$ and $\psi ^{\prime }_3$ is unique, we just repeat the argument, and the result follows.

We finally come to the proof of Theorem 4.2.

Proof of Theorem 4.2

By Lemma 4.5, it suffices to prove the existence of geometric pushouts. Let $\mathscr {C}_0$ denote the category of affine schemes. For ${d}=1$ , $2$ , $3$ , let $\mathscr {C}_{d}$ denote the full $2$ -subcategory of the $2$ -category of algebraic stacks with affine dth diagonal. Note that $\mathscr {C}_3$ is the full $2$ -category of algebraic stacks. We will prove by induction on $d\geq 0$ that if $[\mathscr {X}_2 \xleftarrow {f} \mathscr {X}_0 \xrightarrow {i} \mathscr {X}_1]$ belongs to $\mathscr {C}_d$ and $\mathscr {X}_1$ is quasi-separated, then it admits a geometric pushout. For the base case, where $d=0$ and $\mathscr {X}_j = \operatorname {\mathrm {Spec}} A_j$ is affine, take $\mathscr {X}_3 = \operatorname {\mathrm {Spec}} ( A_2\times _{A_0} A_1 )$ and the result is clear.

Now, let $d>0$ and assume that $[\mathscr {X}_2 \xleftarrow {f} \mathscr {X}_0 \xrightarrow {i} \mathscr {X}_1]$ belongs to $\mathscr {C}_d$ . Fix a smooth surjection $\amalg _{l\in \Lambda } X_2^l \to \mathscr {X}_2$ , where $X_2^l$ is an affine scheme $\forall l\in \Lambda $ . Set $X_0^l = X_2^l \times _{\mathscr {X}_2} \mathscr {X}_0$ . As f is affine, the scheme $X_0^l$ is also affine. By Theorem 1.2, the resulting smooth surjection $X_0^l \to \mathscr {X}_0$ lifts to a smooth surjection $X^l_1 \to \mathscr {X}_1$ , with $X^l_1$ affine, and $X_0^l\cong X^l_1\times _{\mathscr {X}_1} \mathscr {X}_0$ . For $j = 0$ , $1$ and $2$ and u, v, $w \in \Lambda $ set $X_j^{uv}=X_j^u\times _{\mathscr {X}_j} X_j^v$ and $X_j^{uvw} = X_j^u \times _{\mathscr {X}_j} X_j^v \times _{\mathscr {X}_j} X_j^w$ . Note that for $j=0$ , $1$ and $2$ and all u, v, $w\in \Lambda $ we have $X_j^{uv}$ , $X_j^{uvw} \in \mathscr {C}_{d-1}$ . By the inductive hypothesis, for $I=u$ , $uv$ or $uvw$ , a geometric pushout $X_3^I$ of the diagram $[X_2^I \leftarrow X_0^I \rightarrow X_1^I]$ exists. By Lemma 4.5, there are uniquely induced morphisms $X^{uv}_j \to X^{u}_j$ . For $j\neq 3$ , these morphisms are clearly smooth, and by Lemma 4.4 the morphisms $X^{uv}_3 \to X^u_3$ are smooth. It easily verified that the universal properties give rise to a smooth groupoid $[\amalg _{u,v\in \Lambda } X^{uv}_3 \rightrightarrows \amalg _{w\in \Lambda } X_3^w]$ . The quotient $\mathscr {X}_3$ of this groupoid in the category of stacks is algebraic. By Lemma 4.3 (3) it is also a geometric pushout of the diagram $[\mathscr {X}_2 \leftarrow \mathscr {X}_0 \rightarrow \mathscr {X}_1]$ and the result follows.

That the pushout inherits the properties ‘quasi-compact’ and ‘quasi-separated’ follows from $\mathscr {X}_1\amalg \mathscr {X}_2\to \mathscr {X}_3$ being affine and surjective. The properties ‘Deligne–Mumford’ and ‘algebraic space’, are inherited since $(\mathscr {X}_1\smallsetminus \mathscr {X}_0) \amalg \mathscr {X}_2\to \mathscr {X}_3$ is a surjective monomorphism. For ‘affine’, this was the base case of the induction.

5. Local structure of algebraic stacks

In this section, we prove the main local structure results for stacks (Theorems 1.3 and 1.4) as well as non-Noetherian generalizations (Theorems 5.1 and 5.8).

5.1. Proof of Theorem 1.3

When $f_0 \colon \mathscr {W}_0 \to \mathscr {X}_0$ is smooth or étale, the theorem can be established along similar lines to [Reference Alper, Hall and RydhAHR19, Proof of Thm. 5.3].

Proof of Theorem 1.3(1)—smooth/étale case

Step 1: An effective formally versal solution. Since $\mathscr {W}_0$ is quasi-compact, we may assume that $\mathscr {X}$ is quasi-compact after replacing $\mathscr {X}$ with a quasi-compact open substack containing the image of $\mathscr {W}_0$ . Since $\mathscr {W}_0$ is linearly fundamental, we can apply [Reference Alper, Hall and RydhAHR19, Thm. 1.11] to obtain a Cartesian square

where $\widehat {f} \colon \widehat {\mathscr {W}} \to \mathscr {X}$ is a flat morphism and $\widehat {\mathscr {W}}$ is a linearly fundamental stack coherently complete along $\mathscr {W}_0$ . Since $\mathscr {W}_n\to \mathscr {X}_n$ is smooth, $\widehat {f} \colon \widehat {\mathscr {W}}\to \mathscr {X}$ is formally versal at $\mathscr {W}_0$ (Lemma 2.10).

Step 2: Algebraization. We now apply algebraization for linearly fundamental pairs (Theorem 2.3) to the pair $(\widehat {\mathscr {W}}, \mathscr {W}_0)$ and morphism $\widehat {f} \colon \widehat {\mathscr {W}}\to \mathscr {X}$ to obtain a fundamental pair $(\mathscr {W}, \mathscr {W}_0)$ with $\mathscr {W}$ of finite type over S and a morphism $f \colon \mathscr {W} \to \mathscr {X}$ smooth (resp. étale) along $\mathscr {W}_0$ such that $\widehat {\mathscr {W}}$ is isomorphic over $\mathscr {X}$ to the coherent completion of $\mathscr {W}$ along $\mathscr {W}_0$ . After replacing $\mathscr {W}$ with an open neighborhood, we may arrange that f is smooth (resp. étale) and $\mathscr {W}$ is fundamental. Indeed, if $\mathscr {U} \subset \mathscr {W}$ is an open neighborhood of $\mathscr {W}_0$ such that $f|_{\mathscr {U}}$ is smooth (resp. étale) and if $\pi \colon \mathscr {W}\to W$ denotes the adequate moduli space, then we replace $\mathscr {W}$ with the inverse image of any affine open subscheme of $W\smallsetminus \pi (\mathscr {W}\smallsetminus \mathscr {U}))$ containing $\pi (\mathscr {W}_0)$ .

The case when $f_0 \colon \mathscr {W}_0 \to \mathscr {X}_0$ is syntomic is handled by reducing to the smooth case.

Proof of Theorem 1.3(2)—syntomic case

Step 1: We may assume that $f_0 \colon \mathscr {W}_0 \to \mathscr {X}_0$ is affine. We may assume that $\mathscr {X}$ is quasi-compact. Since $\mathscr {W}_0$ is fundamental, there is an affine morphism $\mathscr {W}_0 \to B \mathrm {GL}_n$ for some n. Since $\mathscr {X}_0$ has affine diagonal (as it has the resolution property), the induced morphism $\mathscr {W}_0 \to \mathscr {X}_0 \times B \mathrm {GL}_n$ is affine. Since $B \mathrm {GL}_n$ is smooth with smooth diagonal, we may replace $(\mathscr {X}, \mathscr {X}_0)$ with $(\mathscr {X} \times B \mathrm {GL}_n, \mathscr {X}_0 \times B \mathrm {GL}_n)$ .

Step 2: There is a factorization $f_0 \colon \mathscr {W}_0 \hookrightarrow \mathscr {Y}_0 \to \mathscr {X}_0$ , where $\mathscr {W}_0 \hookrightarrow \mathscr {Y}_0$ is a regular closed immersion, $\mathscr {Y}_0 \to \mathscr {X}_0$ is smooth and affine, and $\mathscr {Y}_0$ is linearly fundamental. Since $\mathscr {X}_0$ has the resolution property and $(f_0)_* \mathcal {O}_{\mathscr {W}_0}$ is a finite type $\mathcal {O}_{\mathscr {X}_0}$ -algebra, there exist a vector bundle $\mathcal {E}_0$ on $\mathscr {X}_0$ and a surjection $\operatorname {\mathrm {Sym}}(\mathcal {E}_0)\twoheadrightarrow (f_0)_*\mathcal {O}_{\mathscr {W}_0}$ . Setting $\mathscr {Y}_0 = \mathbb {V}(\mathcal {E}_0)=\operatorname {\mathrm {Spec}}(\operatorname {\mathrm {Sym}}\mathcal {E}_0)$ yields a factorization such that $\mathscr {W}_0 \hookrightarrow \mathscr {Y}_0$ is a regular closed immersion and $\mathscr {Y}_0 \to \mathscr {X}_0$ is smooth and affine. To arrange that $\mathscr {Y}_0$ is linearly fundamental, we apply the étale case of the local structure theorem (Theorem 1.3 (1)) to the closed immersion $\mathscr {W}_0\hookrightarrow \mathscr {Y}_0$ to extend the isomorphism $\mathscr {W}_0 \stackrel {\sim }{\to } \mathscr {W}_0$ to an étale morphism $\mathscr {Y}^{\prime }_0 \to \mathscr {Y}_0$ with $\mathscr {Y}^{\prime }_0$ fundamental. Since $\mathscr {W}_0$ satisfies (PC) or (N), or $\mathscr {Y}_0$ satisfies (FC), there is an open neighborhood of $\mathscr {W}_0\hookrightarrow \mathscr {Y}^{\prime }_0$ that is linearly fundamental [Reference Alper, Hall and RydhAHR19, Prop. 7.20].

Step 3: Apply the smooth version of the local structure theorem. Since $\mathscr {Y}_0$ is linearly fundamental, we may apply the smooth case of the local structure theorem (Theorem 1.3 (1)) to the closed immersion $\mathscr {X}_0 \hookrightarrow \mathscr {X}$ and smooth morphism $\mathscr {Y}_0 \to \mathscr {X}_0$ to obtain a commutative diagram

with a Cartesian square such that $\mathscr {Y} \to \mathscr {X}$ is smooth and $\mathscr {Y}$ is fundamental.

Step 4: Lift the closed substack $\mathscr {W}_0 \hookrightarrow \mathscr {Y}_0$ to a closed substack $\mathscr {W} \hookrightarrow \mathscr {Y}$ syntomic over $\mathscr {X}$ . Let $\mathcal {I}_0$ be the ideal sheaf defining $\mathscr {W}_0 \hookrightarrow \mathscr {Y}_0$ , and consider the conormal bundle $\mathcal {N}_0:=\mathcal {I}_0/\mathcal {I}_0^2$ . After replacing $\mathscr {Y}$ with an étale fundamental neighborhood of $\mathscr {W}_0\hookrightarrow \mathscr {Y}$ , we may extend the conormal bundle $\mathcal {N}_0$ to a vector bundle $\mathcal {N}$ on $\mathscr {Y}$ ; this follows from applying [Reference Alper, Hall and RydhAHR19, Prop. 7.18(4)] to the fundamental pair $(\mathscr {Y}, \mathscr {W}_0)$ .

We claim that after replacing $\mathscr {Y}$ with a fundamental étale neighborhood of $\mathscr {W}_0$ the canonical homomorphism $\mathcal {N}\twoheadrightarrow \mathcal {N}_0 \hookrightarrow \mathcal {O}_{\mathscr {Y}_0}/\mathcal {I}_0^2$ extends to a diagram

If $\mathscr {Y}$ is linearly fundamental, this is immediate as the functor $\operatorname {\mathrm {Hom}}_{\mathcal {O}_{\mathscr {Y}}}(\mathcal {N},-) = \Gamma (\mathscr {Y}, \mathcal {N}^{\vee } \otimes -)$ is exact. In general, let $\mathscr {W}_1 \hookrightarrow \mathscr {Y}_0$ be the closed substack defined by $\mathcal {I}_0^2$ . Then we have a morphism $\mathscr {W}_1\to \mathbb {V}(\mathcal {N})$ over $\mathscr {Y}$ which by [Reference Alper, Hall and RydhAHR19, Prop. 7.18(1)] extends to a section $\mathscr {Y}\to \mathbb {V}(\mathcal {N})$ after replacing $\mathscr {Y}$ with a fundamental étale neighborhood of $\mathscr {W}_0$ . This gives the requested map $\mathcal {N}\to \mathcal {O}_{\mathscr {Y}}$ .

Let $\mathscr {W}$ be the closed substack defined by the image of $\mathcal {N}\to \mathcal {O}_{\mathscr {Y}}$ . By construction, $\mathscr {W}$ contains the closed substack $\mathscr {W}_0$ . We claim that $\mathscr {W}_0\hookrightarrow \mathscr {W}\times _{\mathscr {X}} \mathscr {X}_0$ is an isomorphism and $\mathscr {W} \to \mathscr {X}$ is syntomic in an open neighborhood of $\mathscr {W}_0$ . This establishes the theorem as we may shrink further to arrange that $\mathscr {W} \to \mathscr {X}$ is syntomic in a fundamental open neighborhood of $\mathscr {W}_0$ . These claims can be verified smooth-locally on $\mathscr {X}$ and $\mathscr {Y}$ , so we may assume that $\mathscr {X}$ and $\mathscr {Y}$ are affine schemes and $\mathcal {N}$ is a trivial vector bundle. By construction, $\mathcal {N}\mathcal {O}_{\mathscr {Y}_0}+\mathcal {I}_0^2=\mathcal {I}_0$ , so it follows that $\mathscr {W}_0\hookrightarrow \mathscr {W}\times _{\mathscr {Y}} \mathscr {Y}_0$ is an isomorphism in an open neighborhood of $\mathscr {W}_0$ by Nakayama’s lemma.

Let $f_1,\dots ,f_n\in \mathcal {O}_{\mathscr {Y}}$ be the image of a basis of $\mathcal {N}$ . We claim that $f_1,\dots ,f_n$ is a regular sequence in a neighborhood of $\mathscr {W}_0$ and that $\mathscr {W}\to \mathscr {X}$ is flat in a neighborhood of $\mathscr {W}_0$ . By [Reference GrothendieckEGAIV, Thm. 11.3.8 (c) $\Rightarrow$ (b’)], it is enough to prove that the images of $f_1,\dots ,f_n$ in $\mathcal {O}_{\mathscr {Y}_x,w}$ is a regular sequence for every $w\in |\mathscr {W}_0|$ with image $x\in |\mathscr {X}_0|$ , which follows by construction.

5.2. Non-Noetherian local structure theorem

The following provides a non-Noetherian generalization of Theorem 1.3, which we establish by reducing to the Noetherian case.

Theorem 5.1 (Local structure of stacks)

Let $\mathscr {X}$ be a quasi-separated algebraic stack with affine stabilizers, $\mathscr {X}_0 \hookrightarrow \mathscr {X}$ be a closed substack and $f_0\colon \mathscr {W}_0\to \mathscr {X}_0$ be a morphism with $\mathscr {W}_0$ linearly fundamental. Assume one of the following conditions:

  1. (1) $\mathscr {X}$ is locally of finite type over an excellent algebraic space or

  2. (2) $\mathscr {W}_0$ satisfies (PC) or (N), or

  3. (3) $\mathscr {X}_0$ satisfies (FC).

Then

  1. (a) If $f_0$ is smooth (resp. étale), then there exists a smooth (resp. étale) morphism $f\colon \mathscr {W}\to \mathscr {X}$ such that $\mathscr {W}$ is fundamental and $f|_{\mathscr {X}_0}\simeq f_0$ .

  2. (b) Assume that $\mathscr {W}_0$ satisfies (PC) or (N) or $\mathscr {X}_0$ satisfies (FC). If $f_0$ is syntomic and $\mathscr {X}_0$ has the resolution property, then there exists a syntomic morphism $f\colon \mathscr {W}\to \mathscr {X}$ such that $\mathscr {W}$ is fundamental and $f|_{\mathscr {X}_0}\cong f_0$ .

Proof. Case (1) is precisely Theorem 1.3. For cases (2)–(3), after replacing $\mathscr {X}$ with a quasi-compact open substack we can assume that $\mathscr {X}$ is quasi-compact. If $\mathscr {X}_0$ satisfies (FC), we can assume that $\mathscr {X}$ is also (FC). Indeed, let S be the spectrum of $\mathbb {Z}$ localized in the characteristics of $\mathscr {X}_0$ , and replace $\mathscr {X}$ , $\mathscr {X}_0$ and $\mathscr {W}_0$ with their base changes along $S\to \operatorname {\mathrm {Spec}} \mathbb {Z}$ . Once the theorem is established in this case, we can use standard limit methods to replace S with an open subscheme of $\operatorname {\mathrm {Spec}} \mathbb {Z}$ . If instead $\mathscr {X}_0$ satisfies (PC) or (N), we let $S=\operatorname {\mathrm {Spec}} \mathbb {Z}$ .

By [Reference RydhRyd23], we can write $\mathscr {X}_0\hookrightarrow \mathscr {X}$ as a limit of finitely presented closed immersions $\mathscr {X}_{0,\lambda }\hookrightarrow \mathscr {X}$ with transition maps that are closed immersions. For sufficiently large $\lambda $ , we can extend $f_0\colon \mathscr {W}_0\to \mathscr {X}_0$ to a map $f_{0,\lambda }\colon \mathscr {W}_{0,\lambda }\to \mathscr {X}_{0,\lambda }$ of finite presentation. For sufficiently large $\lambda $ , we have that $f_{0,\lambda }$ is smooth/étale/syntomic. If $\mathscr {X}_0$ has the resolution property, then so does $\mathscr {X}_{0,\lambda }$ for sufficiently large $\lambda $ . This follows from the Totaro–Gross characterization of the resolution property as having a quasi-affine morphism to $B\mathrm {GL}_N$ for some N [Reference TotaroTot04, Reference GrossGro17] and [Reference RydhRyd15, Thm. C]. For sufficiently large $\lambda $ , we also have that $\mathscr {W}_{0,\lambda }$ is linearly fundamental [Reference Alper, Hall and RydhAHR19, Thm. 7.3] using that either $\mathscr {W}_0$ is (PC) or (N), or $\mathscr {X}$ is (FC). After replacing $\mathscr {W}_0$ and $\mathscr {X}_0$ with $\mathscr {W}_{0,\lambda }$ and $\mathscr {X}_{0,\lambda }$ we may thus assume that $\mathscr {X}_0\hookrightarrow \mathscr {X}$ is of finite presentation.

Using [Reference RydhRyd23], we may further write $\mathscr {X}\to S$ as a limit of algebraic stacks $\mathscr {X}_{\lambda }\to S$ of finite presentation. For sufficiently large $\lambda $ , we can descend the finitely presented maps $f_0\colon \mathscr {W}_0\to \mathscr {X}_0$ and $i\colon \mathscr {X}_0 \hookrightarrow \mathscr {X}$ to finitely presented maps $f_{0,\lambda }\colon \mathscr {W}_{0,\lambda }\to \mathscr {X}_{0,\lambda }$ and $i_\lambda \colon \mathscr {X}_{0,\lambda }\hookrightarrow \mathscr {X}_{\lambda }$ . For sufficiently large $\lambda $ , we have that $\mathscr {X}_\lambda $ has affine stabilizers [Reference Hall and RydhHR15, Thm. 2.8] and, as before, that $f_{0,\lambda }$ is smooth/étale/syntomic, that $i_\lambda $ is a closed immersion, that $\mathscr {W}_{0,\lambda }$ is linearly fundamental and that $\mathscr {X}_{0,\lambda }$ has the resolution property. We are now in the situation of Theorem 1.3.

5.3. Compact generation

We can now prove Theorem 1.12 on the compact generation of algebraic stacks in positive characteristic.

Proof of Theorem 1.12

The implications (1) $\implies $ (2) $\implies $ (3) and (4) $\implies $ (5) are trivial. The implication (3) $\implies $ (5) is [Reference Hall, Neeman and RydhHNR19, Thm. 1.1] since every closed point has positive characteristic. It remains to prove that (5) implies (1) and (4). To this end, let x be a closed point of $\mathscr {X}$ , which we view as morphism $x\colon \operatorname {\mathrm {Spec}} l \to \mathscr {X}$ , where l is an algebraically closed field. Let $i_x \colon \mathcal {G}_x \hookrightarrow \mathscr {X}$ be the closed immersion of the residual gerbe of x. Then there is a field $\kappa (x)$ such that $\mathcal {G}_x \to \operatorname {\mathrm {Spec}} \kappa (x)$ is a coarse moduli space. Certainly, $\kappa (x) \subseteq l$ . After taking a finite extension $\kappa (x) \subseteq k \subseteq l$ , $(\mathcal {G}_x)_k \simeq BH$ , for some group scheme H over k. After passing to an additional finite extension of k, there is a subgroup scheme $H' \hookrightarrow H$ such that $H^{\prime }_l \simeq G^0_{\mathrm {red}}$ . By assumption, $G^0_{\mathrm {red}}$ is a torus, so $H'$ is of multiplicative type. Set $\mathscr {W}_0^x = BH'$ , $\mathscr {X}_0^x = \mathcal {G}_x$ and let $f_0^x \colon \mathscr {W}_0^x \to \mathscr {X}_0^x$ be the induced morphism. We claim that $f_0^x$ is syntomic. Indeed, $f_0^x$ is the composition $BH' \to BH \to \mathcal {G}_x$ . Now $BH \to \mathcal {G}_x$ is the base change of $\operatorname {\mathrm {Spec}} k \to \operatorname {\mathrm {Spec}} \kappa (x)$ , which is syntomic. Also, $BH' \to BH$ is fppf-locally the morphism $H/H' \to \operatorname {\mathrm {Spec}} k$ . Since $H \to \operatorname {\mathrm {Spec}} k$ is syntomic (Lemma 5.2) and $H \to H/H'$ is fppf, $H/H' \to \operatorname {\mathrm {Spec}} k$ is syntomic. By descent, $BH' \to BH$ is syntomic and so $f_0^x$ is too.

We now apply Theorem 5.1 (2) (b) to $f_0^x$ : This results in a syntomic morphism $f^x\colon \mathscr {W}^x \to \mathscr {X}$ such that $\mathscr {W}^x$ is fundamental and $f^x|_{\mathscr {X}_0^x} \simeq f_0^x$ . Since $\mathscr {W}^x$ is fundamental and $f_0^x$ is finite, we may shrink $\mathscr {W}^x$ so that $f^x$ is quasi-finite [Reference Alper, Hall and RydhAHR20, Lem. 3.1]. Additionally, since $\mathscr {X}$ has affine diagonal, we may further shrink $\mathscr {W}^x$ so that $f^x$ is affine [Reference Alper, Hall and RydhAHR19, Prop. 5.7]. By [Reference Alper, Hall and RydhAHR19, Prop. 6.7], after passing to a strictly étale neighborhood of $\mathscr {W}_0^x$ , we may further shrink $\mathscr {W}^x$ so that it is nicely fundamental.

Since $\mathscr {X}$ is quasi-compact and the $f^x$ are all open morphisms, there is a finite set of closed points $x_1$ , $\dots $ , $x_m$ of $\mathscr {X}$ such that the induced morphism $f\colon \mathscr {W} = \amalg _{i=1}^m \mathscr {W}^{x_i} \xrightarrow {\amalg f^{x_i}} \mathscr {X}$ is affine, quasi-finite, syntomic and faithfully flat. But $\mathscr {W}$ is nicely fundamental, so it is $\aleph _0$ -crisp [Reference Hall and RydhHR17, Ex. 8.6]. By [Reference Hall and RydhHR17, Thm. C], $\mathscr {X}$ is $\aleph _0$ -crisp. This proves (5) $\implies $ (1). Since $\mathscr {W}\to \mathscr {X}$ is quasi-finite and surjective and the reduced identity components of the stabilizers of $\mathscr {W}$ are tori, so are those of $\mathscr {X}$ . This proves (5) $\implies $ (4).

We include the following standard result (also see [Reference Cotner and ZavyalovCZ22, Lem. A.2] for a different argument).

Lemma 5.2. Let S be an algebraic space. If $G \to S$ is a group algebraic space that is flat and locally of finite presentation, then it is syntomic.

Proof. Since $G \to S$ is flat and locally of finite presentation, we reduce immediately to the situation where S is the spectrum of an algebraically closed field k [SP, Tags 01UF & 069N] and we must show that $G \to \operatorname {\mathrm {Spec}} k$ is a local complete intersection morphism. Let $G^0 \subseteq G$ be the connected component of the identity, which is a normal, irreducible and quasi-compact flat closed subgroup scheme of G [SP, Tag 0B7R]. Since G is locally of finite type, $G^0 \subseteq G$ is even open and closed. Hence, the quotient $G/G^0$ is étale. Thus, we may replace G with $G^0$ and assume that G is connected and of finite type. If the characteristic of k is $0$ , then $G \to S$ is smooth and we are done (Cartier’s theorem [SP, Tag 047N]). In general, there is an extension of groups $1 \to G_{\mathrm {ant}} \to G \to G_{\mathrm {aff}} \to 1$ , where $G_{\mathrm {ant}}$ is anti-affine (i.e., $\Gamma (G_{\mathrm {ant}},\mathcal {O}_{G_{\mathrm {ant}}}) \simeq k$ ) and $G_{\mathrm {aff}}$ is affine [Reference BrionBri09, (0.2)]. Then $G_{\mathrm {ant}}$ is smooth, so it suffices to prove the claim when G is affine. In this case, $G \hookrightarrow \mathrm {GL}_n$ for some $n>0$ . The cover $\mathrm {GL}_n \to \mathrm {GL}_n/G$ is faithfully flat and of finite presentation. Since $\mathrm {GL}_n$ is smooth over $\operatorname {\mathrm {Spec}} k$ , $\mathrm {GL}_n/G$ is also smooth over $\operatorname {\mathrm {Spec}} k$ —this follows immediately from the descent of regularity under faithfully flat extensions of local rings [Reference GrothendieckEGAIV, 0 ${}_{\mathrm{IV}}$ .17.3.3]. Hence, $\mathrm {GL}_n \to \mathrm {GL}_n/G$ is syntomic [SP, Tags 069M & 069K]. The fiber of the syntomic morphism $\mathrm {GL}_n \to \mathrm {GL}_n/G$ over a k-point is $G \to \operatorname {\mathrm {Spec}} k$ , which is consequently a local complete intersection morphism.

5.4. Local structure of stacks at pro-affine-immersions

We recall [Reference Temkin and TyomkinTT17, §3]: A morphism of algebraic stacks $j \colon \mathscr {U} \to \mathscr {X}$ is a pro-open immersion if every morphism $\mathscr {Y} \to \mathscr {X}$ with set-theoretic image contained in $|j(\mathscr {U})|$ factors uniquely through j. It is established in [Reference Temkin and TyomkinTT17, Prop. 3.1.4] that j is necessarily a flat monomorphism and $|j(\mathscr {U})| = \cap _{\mathscr {V} \supseteq |j(\mathscr {U})|} \mathscr {V}$ , where the intersection ranges over all open stacks $\mathscr {V} \subseteq \mathscr {X}$ containing $j(\mathscr {U})$ . If j is quasi-compact, then it is a pro-open immersion if and only if it is a flat monomorphism [Reference Temkin and TyomkinTT17, Thm. 3.2.5] and then j is quasi-affine [Reference RaynaudRay68, Prop. 1.5 (ii)]. If j is quasi-compact, then it is also a topological embedding [Reference RaynaudRay68, Prop. 1.2] and if in addition $\mathscr {X}$ is quasi-compact, then $|j(\mathscr {U})| = \cap _{\mathscr {V} \supseteq |j(\mathscr {U})|} \mathscr {V}$ , where the intersection ranges over the quasi-compact opens of $\mathscr {X}$ containing $j(\mathscr {U})$ .

Remark 5.3. Let $j\colon \mathscr {U} \to \mathscr {X}$ be a quasi-compact pro-open immersion of algebraic stacks. There is a factorization of j as $\mathscr {U} \xrightarrow {j'} \mathscr {X}' \xrightarrow {g} \mathscr {X}$ , where $j'$ is an affine pro-open immersion and g is a quasi-compact open immersion [Reference RaynaudRay68, Prop. 1.5 (i)].

We introduce the following variant: a morphism of algebraic stacks $j \colon \mathscr {U} \to \mathscr {X}$ is a pro-affine(-open) immersion if $\mathscr {U}$ represents a cofiltered intersection $\cap _{\alpha } \mathscr {V}_\alpha $ , where the $\mathscr {V}_\alpha \subseteq \mathscr {X}$ are (open) immersions and the transition maps $\mathscr {V}_\alpha \to \mathscr {V}_\beta $ , which are automatically (open) immersions, are eventually affine.

Example 5.4. An immersion of algebraic stacks is a pro-affine-immersion.

Example 5.5. If $x \in |\mathscr {X}|$ is a point of a quasi-separated algebraic stack, then the inclusion $\mathscr {G}_x \to \mathscr {X}$ of the residual gerbe is a pro-affine-immersion [Reference Hall and RydhHR18, Lem. 2.1].

Remark 5.6. A pro-affine-open immersion of algebraic stacks is pro-étale.

Remark 5.7. If $\mathscr {X}$ is a normal and $\mathbb {Q}$ -factorial Noetherian stack, then any quasi-compact pro-open immersion $j \colon \mathscr {U} \to \mathscr {X}$ is pro-affine-open. This follows from the result [Reference RaynaudRay68, Cor. 2.7]: After restricting to an open substack, the complement of $\mathscr {U}$ is a, possibly infinite, union of Cartier divisors and the complements of finite unions of these divisors are affine open immersions.

The following theorem simultaneously generalizes Theorem 1.4 and Theorem 5.1. Note that in Theorem 1.4 no extra conditions are needed as (FC) always holds for the residual gerbe as it is a one-point space.

Theorem 5.8 (Local structure of stacks at pro-affine-immersions)

Assumptions and conclusions as in Theorem 5.1 (2) or (3) except that $\mathscr {X}_0\hookrightarrow \mathscr {X}$ is a pro-affine-immersion.

Proof. As a first preliminary step, we can as before assume that $\mathscr {X}$ is quasi-compact and, if $\mathscr {X}_0$ satisfies (FC), that $\mathscr {X}$ satisfies (FC) by base changing along $S \to \operatorname {\mathrm {Spec}} \mathbb {Z}$ where S is the spectrum of $\mathbb {Z}$ localized in the characteristics of $\mathscr {X}_0$ .

By assumption, $\mathscr {X}_0 = \cap _\lambda \mathscr {X}_\lambda $ is an intersection of a cofiltered system of immersions $\mathscr {X}_\lambda \hookrightarrow \mathscr {X}$ with eventually affine inclusions $\mathscr {X}_\mu \hookrightarrow \mathscr {X}_{\lambda }$ . Pick $\alpha $ sufficiently large such that $\mathscr {X}_\lambda \hookrightarrow \mathscr {X}_{\alpha }$ is affine for all $\lambda \geq \alpha $ and pick a quasi-compact open neighborhood $\mathscr {U}$ of $\mathscr {X}_0$ in $\mathscr {X}_\alpha $ . Then $\mathscr {X}_0 = \cap _{\lambda \geq \alpha } (\mathscr {X}_\lambda \cap \mathscr {U})$ , so we may assume that all the $\mathscr {X}_\lambda $ are quasi-compact and that all the $\mathscr {X}_\mu \hookrightarrow \mathscr {X}_\lambda $ are affine.

By standard limit methods, the morphism $f_0 \colon \mathscr {W}_0 \to \mathscr {X}_0$ descends to a morphism $f_\alpha \colon \mathscr {W}_\alpha \to \mathscr {X}_\alpha $ , which is étale, smooth or syntomic if $f_0$ is so. If $\lambda \geq \alpha $ , set $\mathscr {W}_{\lambda } = \mathscr {W}_\alpha \times _{\mathscr {X}_\alpha } \mathscr {X}_{\lambda }$ . Then $\mathscr {W}_0 = \cap _{\lambda \geq \alpha } \mathscr {W}_\lambda $ . Now, either $\mathscr {X}$ satisfies (FC) (by the initial reduction) or $\mathscr {W}_0$ satisfies (PC) or (N). Hence, $\mathscr {W}_\beta $ is linearly fundamental for some $\beta \gg \alpha $ [Reference Alper, Hall and RydhAHR19, Thm. 7.3]. After replacing $\mathscr {X}$ with an open neighborhood of $\mathscr {X}_\beta $ , we may assume that $\mathscr {X}_\beta \hookrightarrow \mathscr {X}$ is a closed immersion. We may now apply Theorem 5.1 (2) or (3) to $f_\beta $ and the result follows.

We now prove the refinements.

Proof of Theorem 1.5

Arguing as in the proof of Theorem 5.8, we may assume that $\mathscr {W}_0$ satisfies (PC) or (N) or $\mathscr {W}$ satisfies (FC). We may further assume that there is a factorization of $\mathscr {W}_0 \hookrightarrow \mathscr {W} \to \mathscr {X}$ through an immersion $\mathscr {W}_\beta \hookrightarrow \mathscr {W}$ such that $\mathscr {W}_{\beta }$ is fundamental and $\mathscr {W}_\beta \hookrightarrow \mathscr {W} \to \mathscr {X}$ is representable [Reference RydhRyd15, Thm. C]. We now factor $\mathscr {W}_\beta \hookrightarrow \mathscr {W}$ as $\mathscr {W}_\beta \hookrightarrow \mathscr {Z} \subseteq \mathscr {W}$ , where $\mathscr {W}_\beta \hookrightarrow \mathscr {Z}$ is a closed immersion and $\mathscr {Z} \subseteq \mathscr {W}$ is an open immersion. In this generality, however, $\mathscr {Z}$ is not necessarily fundamental (it can be arranged to be if $\mathscr {W}_0 \hookrightarrow \mathscr {W}$ is a closed immersion, however). But we can now apply Theorem 5.1 to the closed immersion $\mathscr {W}_\beta \hookrightarrow \mathscr {Z}$ . We thus obtain an étale neighborhood $p \colon \mathscr {W}' \to \mathscr {Z}$ of $\mathscr {W}_\beta $ such that $\mathscr {W}'$ is fundamental and the induced morphism $\mathscr {W}_\beta ' = p^{-1}(\mathscr {W}_\beta ) \simeq \mathscr {W}_\beta \to \mathscr {Z} \subseteq \mathscr {W} \to \mathscr {X}$ is representable. The result now follows from [Reference Alper, Hall and RydhAHR19, Prop. 5.7] applied to the pair $(\mathscr {W}',\mathscr {W}_\beta ')$ and the morphism $\mathscr {W}' \to \mathscr {X}$ .

Proof of Theorem 1.6

As in the proof of Theorem 1.5, we may assume that there is a factorization of $\mathscr {W}_0 \hookrightarrow \mathscr {W}$ through an immersion $\mathscr {W}_\beta \hookrightarrow \mathscr {W}$ such that $\mathscr {W}_{\beta }$ is linearly fundamental [Reference Alper, Hall and RydhAHR19, Thm. 7.3]. Likewise, if $\mathscr {W}_0=[\operatorname {\mathrm {Spec}} A_0/G_0]$ as in (1), then we can arrange so that $\mathscr {W}_\beta =[\operatorname {\mathrm {Spec}} A_\beta /G_\beta ]$ with $G_\beta $ embeddable and linearly reductive or nice [Reference Alper, Hall and RydhAHR19, Lem. 2.12 and Thm. 7.3]. Finally, if $\mathscr {W}_0=[\operatorname {\mathrm {Spec}} A_0/G]$ as in (2), then $\mathscr {W}_\beta =[\operatorname {\mathrm {Spec}} A_\beta /G]$ by [Reference RydhRyd15, Thm. C].

We have a closed then open factorization $\mathscr {W}_\beta \hookrightarrow \mathscr {Z} \subseteq \mathscr {W}$ . Apply Theorem 5.1 to $\mathscr {W}_\beta \hookrightarrow \mathscr {Z}$ to replace $\mathscr {W}$ with an étale neighborhood of $\mathscr {W}_\beta $ that is fundamental. We can now apply [Reference Alper, Hall and RydhAHR19, Props. 7.16, 7.18(3) and 7.20] and the result follows.

5.5. Nisnevich neighborhoods

Proof of Theorem 1.9

We apply Theorem 1.4 to every point of $|\mathscr {X}|$ : For each $x\in |\mathscr {X}|$ we obtain an étale morphism $f_x \colon \mathscr {W}_x \to \mathscr {X}$ such that $f_x|_{\mathscr {G}_x}$ is an isomorphism and $\mathscr {W}_x$ is fundamental. If $\mathscr {X}$ has affine (resp. separated) diagonal, then Theorem 1.5 says that we can arrange that $f_x$ is affine (resp. representable). By Theorem 1.6, we may further assume that $\mathscr {W}_x$ is nicely fundamental. Set $\mathscr {W} = \amalg _{x\in |\mathscr {X}|} \mathscr {W}_x$ , and take $f=\amalg _{x} f_x \colon \mathscr {W} \to \mathscr {X}$ , then f is a quasi-separated Nisnevich covering. By [Reference Hall and RydhHR18, Prop. 3.3], we may shrink $\mathscr {W}$ so that it is quasi-compact (a monomorphic splitting sequence must factor through finitely many of the $\mathscr {W}_x$ ), remains nicely fundamental and f is a Nisnevich covering.

Proof of Theorem 1.11

We apply Theorem 5.1 to every closed point of $|\mathscr {X}|$ : For each closed point x of $\mathscr {X}$ we obtain an étale morphism $g \colon \mathscr {W} \to \mathscr {X}$ such that $\mathscr {W}=[U/\mathrm {GL}_n]$ is fundamental and $g|_{\mathscr {G}_x}$ is an isomorphism. If $\mathscr {X}$ has affine (resp. separated diagonal), then Theorem 1.5 says that we can arrange that g is affine (resp. representable).

For an integer $d\geq 1$ , let $\mathscr {W}^d$ be the dth fiber product of g; then the symmetric group $S_d$ acts on $\mathscr {W}^d$ by permuting the factors. Let e be the maximum rank of a fiber of g. Then there is an induced Nisnevich covering $f \colon \coprod _{1 \leq d \leq e} [\mathscr {W}^d/S_d] \to \mathscr {X}$ since g is representable.

Let $V^d$ be the dth fiber product of $U\to \mathscr {W}\to \mathscr {X}$ . Then $\mathscr {W}^d=[V^d/(\mathrm {GL}_n)^d]$ . Let P be one of the properties: separated, quasi-affine, affine. If the diagonal of $\mathscr {X}$ has property P, then the algebraic space $V^d$ has property P. Since the Stiefel manifold $\mathrm {GL}_{dn}/(\mathrm {GL}_n)^d$ is affine, it follows that $\mathscr {W}^d=[V'/\mathrm {GL}_{nd}]$ for an algebraic space $V'$ with property P.

Let $p\colon \mathscr {W}^d\to [\mathscr {W}^d/S_d]$ . Let $\mathcal {E}$ be the vector bundle on $\mathscr {W}^d$ with frame bundle $V'$ . Then we claim that the frame bundle V of $p_*\mathcal {E}$ is an algebraic space with property P. Indeed, V is an algebraic space since the stabilizers of $[\mathscr {W}^d/S_d]$ act faithfully on $p_*\mathcal {E}$ , cf. [Reference Edidin, Hassett, Kresch and VistoliEHKV01, Lem. 2.13]. Since $p^*V\to V$ is finite, étale and surjective, it is enough to prove that $p^*V$ has property P. But since p is finite étale, we have that $p^*p_*\mathcal {E}\to \mathcal {E}$ is split surjective and it follows that $p^*V$ has property P by considering Stiefel manifolds again. We have thus shown that $[\mathscr {W}^d/S_d]=[V/\mathrm {GL}_N]$ for an algebraic space V with property P.

When $\mathscr {X}$ has affine diagonal, then $\mathscr {W}^d\to \mathscr {X}$ is affine but $[\mathscr {W}^d/S_d]\to \mathscr {X}$ is merely separated. Let $\mathrm {SEC}^d(\mathscr {W}/\mathscr {X})\subseteq \mathscr {W}^d$ be the open and closed substack that is the complement of all diagonals. Then $S_d$ acts freely on $\mathrm {SEC}^d(\mathscr {W}/\mathscr {X})$ relative to $\mathscr {X}$ and $\mathrm {\acute {E}T}^d(\mathscr {W}/\mathscr {X}):=[\mathrm {SEC}^d(\mathscr {W}/\mathscr {X})/S_d]\to \mathscr {X}$ is affine and an étale neighborhood of any point of $\mathscr {X}$ at which g has rank d. Thus, $f\colon \coprod _{1 \leq d \leq e} \mathrm {\acute {E}T}^d(\mathscr {W}/\mathscr {X}) \to \mathscr {X}$ is a fundamental Nisnevich covering with f affine.

5.6. Existence of henselizations

Proof of Theorem 1.7

By Theorem 5.8, there exists an étale neighborhood $\mathscr {W} \to \mathscr {X}$ of $\mathscr {W}_0:=\mathscr {X}_0$ such that $\mathscr {W}$ is fundamental. Let $\mathscr {W}_0 \to W_0$ and $\mathscr {W} \to W$ be the good and adequate moduli spaces. We claim that the henselization $W^h$ of W along $W_0$ exists and is affine. If $\mathscr {W}_0$ is a closed substack, then this follows from [Reference RaynaudRay70, Ch. XI, Thm. 2] as W is affine. If $\mathscr {W}_0 = \mathscr {G}_x$ is the residual gerbe of a point $x \in |\mathscr {X}|$ , then $W_0 = \operatorname {\mathrm {Spec}} \kappa (x) \hookrightarrow W$ is the inclusion of a point w and $W^h = \operatorname {\mathrm {Spec}} \mathcal {O}_{W,w}^h$ . In this case, we also note that $\mathscr {W}_0$ satisfies (FC). Let $\mathscr {W}^h = \mathscr {W} \times _W W^h$ . Since $W^h \to W$ is flat, $\mathscr {W}^h \to W^h$ is an adequate moduli space. By [Reference Alper, Hall and RydhAHR19, Thm. 3.6], $(\mathscr {W}^h, \mathscr {W}_0)$ is a henselian pair and by [Reference Alper, Hall and RydhAHR19, Cor. 6.10], $\mathscr {W}^h$ is linearly fundamental since the closed points of $\mathscr {W}^h$ have linearly reductive stabilizer. To show that $\mathscr {W}^h \to \mathscr {X}$ is the henselization of $\mathscr {X}$ along $\nu \colon \mathscr {X}_0 \hookrightarrow \mathscr {X}$ , it is enough to prove that any quasi-separated étale neighborhood $g \colon \mathscr {W}'\to \mathscr {W}^h$ of $\mathscr {W}_0$ has a section. This is precisely the conclusion of [Reference Alper, Hall and RydhAHR19, Prop. 7.9].

6. Local structure of derived algebraic stacks

In this section, we give a derived version of the local structure theorem.

An algebraic derived $1$ -stack is the derived analogue of an algebraic stack: It is a sheaf of $\infty $ -groupoids on the opposite of the $\infty $ -category of simplicial commutative rings (with its étale topology) that admits a surjective morphism, represented by smooth derived algebraic spaces, from a disjoint union of derived affine schemes.

Let $\mathscr {X}$ be an algebraic derived $1$ -stack. We say that $\mathscr {X}$ is fundamental if there exists an affine morphism $\mathscr {X}\to B\mathrm {GL}_n$ ; that is, if $\mathscr {X}=[\operatorname {\mathrm {Spec}} A/\mathrm {GL}_n]$ for some derived affine scheme A. We say that $\mathscr {X}$ is linearly fundamental if it is fundamental and cohomologically affine, that is, $R\Gamma (\mathscr {X},-)$ is t-exact.

Proposition 6.1 (Derived effectivity theorem)

Let $\mathscr {X}_0\hookrightarrow \mathscr {X}_1\hookrightarrow \mathscr {X}_2\hookrightarrow \dots $ be a sequence of derived thickenings, that is, $\mathscr {X}_m \cong \tau _{\leq m} \mathscr {X}_n$ for every $m\leq n$ . If $\mathscr {X}_0$ is linearly fundamental, then there is a linearly fundamental algebraic derived $1$ -stack $\mathscr {X}$ and a compatible sequence of equivalences $\tau _{\leq n} \mathscr {X} \cong \mathscr {X}_n$ .

Proof. The existence and uniqueness of an algebraic $1$ -stack $\mathscr {X}$ with compatible isomorphisms $\tau _{\leq n} \mathscr {X} \cong \mathscr {X}_n$ is given by [Reference LurieLur04, Prop. 5.4.6]: $\mathscr {X}$ is determined by the equivalence $\mathscr {X}(A) \cong \mathscr {X}_n(A)$ for n-truncated simplicial commutative rings and $\mathscr {X}(A) \cong \varprojlim _n \mathscr {X}(\tau _{\leq n} A)$ in general.

Let $f_0\colon \mathscr {X}_0\to B\mathrm {GL}_r$ be an affine morphism. The obstruction to lifting a morphism $f_n\colon \mathscr {X}_n\to B\mathrm {GL}_r$ to $f_{n+1}\colon \mathscr {X}_{n+1}\to B\mathrm {GL}_r$ lies in

$$\begin{align*}\operatorname{\mathrm{Ext}}^1_{\mathscr{X}_0}\bigl(f_0^*\mathbb{L}_{B\mathrm{GL}_r},\pi_{n+1}(\mathcal{O}_{\mathscr{X}_{n+1}})[n+1]\bigr). \end{align*}$$

This obstruction group vanishes since $\mathscr {X}_0$ is linearly fundamental. We can thus find a compatible sequence of morphisms $f_n\colon \mathscr {X}_n\to B\mathrm {GL}_r$ . Since $f_0$ is affine, so is $f_n$ for every n. The compatible family of morphisms $f_n : \mathscr {X}_n \to B\mathrm {GL}_r$ defines a morphism $f : \mathscr {X} \to B\mathrm {GL}_r$ , and the resulting morphism is affine because it is affine on every truncation.

Finally, because pushforward along the inclusion $\mathscr {X}_0 \hookrightarrow \mathscr {X}$ is t-exact and identifies $\mathsf {QCoh}(\mathscr {X})^\heartsuit \cong \mathsf {QCoh}(\mathscr {X}_0)^\heartsuit $ , $\mathscr {X}$ is cohomologically affine if and only if $R\Gamma (\mathscr {X}_0,-)$ has cohomological dimension $0$ on $\mathsf {QCoh}(\mathscr {X}_0)^\heartsuit $ . Since $\mathscr {X}_0$ has affine diagonal, this is the same as being cohomologically affine.

Proof of Theorem 1.13

If $\mathscr {X}_0$ satisfies (FC), then let S be the spectrum of $\mathbb {Z}$ localized in the characteristics of $\mathscr {X}_0$ and base change everything along $S\to \operatorname {\mathrm {Spec}} \mathbb {Z}$ . At the very end, we can then replace S by an open quasi-compact subscheme of $\mathbb {Z}$ .

First, assume that $f_0$ is smooth. Then $\mathscr {W}_0\times _{\mathscr {X}_0} (\mathscr {X}_0)_{\mathrm {cl}}$ is classical and we may apply the classical version of the local structure theorem (Theorem 5.1). This gives us a fundamental classical stack $\mathscr {W}_{\mathrm {cl}}$ and a smooth morphism $f_{\mathrm {cl}} \colon \mathscr {W}_{\mathrm {cl}}\to \mathscr {X}_{\mathrm {cl}}$ . Since either (PC)/(N) holds for $\mathscr {W}_0$ or (FC) for $\mathscr {W}_{\mathrm {cl}}$ , we may assume that $\mathscr {W}_{\mathrm {cl}}$ is linearly fundamental (Theorem 1.6). We may now deform $f_{\leq 0}:=f_{\mathrm {cl}}$ to smooth maps $f_{\leq n} \colon \mathscr {W}_{\leq n}\to \tau _{\leq n}\mathscr {X}$ for every n. Indeed, the obstruction lies in

$$\begin{align*}\operatorname{\mathrm{Ext}}^2_{\mathscr{W}_{\mathrm{cl}}}(\mathbb{L}_{f_{\mathrm{cl}}},f_{\mathrm{cl}}^*\pi_n(\mathcal{O}_{\mathscr{X}})[n]),\end{align*}$$

which vanishes as $\mathscr {W}_{\mathrm {cl}}$ is cohomologically affine and $f_{\mathrm {cl}}$ is smooth. By Proposition 6.1, there is a linearly fundamental derived $1$ -stack $\mathscr {W}$ with compatible isomorphisms $\mathscr {W}_{\leq n} \cong \tau _{\leq n}\mathscr {W}$ . Because both $\mathscr {W}$ and $\mathscr {X}$ are nilcomplete [Reference LurieLur04, Prop. 5.3.7], the smooth morphisms $\mathscr {W}_{\leq n} \to \tau _{\leq n} \mathscr {X}$ extend uniquely to a smooth morphism $f\colon \mathscr {W}\to \mathscr {X}$ . Since

$$\begin{align*}\operatorname{\mathrm{Ext}}^1_{(\mathscr{W}_0)_{\mathrm{cl}}}(\mathbb{L}_{(f_0)_{\mathrm{cl}}},(f_0)_{\mathrm{cl}}^*\pi_n(\mathcal{O}_{\mathscr{X}_0})[n])=0,\end{align*}$$

the isomorphism $\mathscr {W}_0\times _{\mathscr {X}_0} (\mathscr {X}_0)_{\mathrm {cl}}\to \mathscr {W}\times _{\mathscr {X}} (\mathscr {X}_0)_{\mathrm {cl}}$ extends to an isomorphism $\mathscr {W}_0\to \mathscr {W}\times _{\mathscr {X}} \mathscr {X}_0$ over $\mathscr {X}_0$ .

When instead $f_0$ is quasi-smooth, we proceed as in the syntomic case of the classical version of the local structure theorem; see the proof of Theorem 1.3 (2).

Step 1: First, replace $\mathscr {X}$ with $\mathscr {X}\times B\mathrm {GL}_n$ so that $\mathscr {W}_0\to \mathscr {X}_0$ becomes affine.

Step 2: Consider the morphism of classical stacks $(\mathscr {W}_0)_{\mathrm {cl}}\to (\mathscr {X}_0)_{\mathrm {cl}}$ , and pick a factorization $(\mathscr {W}_0)_{\mathrm {cl}}\to \mathscr {Y}_0\to (\mathscr {X}_0)_{\mathrm {cl}}$ where the first map is a closed immersion and the second map is affine and smooth. Here, we use that $(\mathscr {X}_0)_{\mathrm {cl}}$ has the resolution property. Then apply the classical étale version of the structure theorem to $(\mathscr {W}_0)_{\mathrm {cl}}=(\mathscr {W}_0)_{\mathrm {cl}}\hookrightarrow \mathscr {Y}_0$ . We can thus replace $\mathscr {Y}_0$ with an étale neighborhood of $(\mathscr {W}_0)_{\mathrm {cl}}$ and assume that $\mathscr {Y}_0$ is linearly fundamental.

Step 3: Apply the smooth case of the derived local structure theorem to $\mathscr {Y}_0\to (\mathscr {X}_0)_{\mathrm {cl}}\hookrightarrow \mathscr {X}$ , and we obtain a smooth map $\mathscr {Y}\to \mathscr {X}$ . Since $\mathscr {Y}\to \mathscr {X}$ is smooth and $\mathscr {W}_0$ is linearly fundamental, the obstructions to lifting the closed immersion $(\mathscr {W}_0)_{\mathrm {cl}}\hookrightarrow \mathscr {Y}$ to closed immersions $\tau _{\leq n}(\mathscr {W}_0)\hookrightarrow \mathscr {Y}$ over $\mathscr {X}$ for every n vanish. We obtain a closed immersion $\mathscr {W}_0\hookrightarrow \mathscr {Y}$ because both $\mathscr {W}_0$ and $\mathscr {Y}$ are nilcomplete [Reference LurieLur04, Prop. 5.3.7]. Since either (PC)/(N) holds for $\mathscr {W}_0$ or (FC) for $\mathscr {Y}$ , we may assume that $\mathscr {Y}$ is linearly fundamental (Theorem 1.6).

Step 4: Now, let $\mathscr {Y}_0=\mathscr {Y}\times _{\mathscr {X}} \mathscr {X}_0$ (previously it denoted its classical truncation). The morphism $\mathscr {W}_0\to \mathscr {Y}_0$ is a quasi-smooth closed immersion. Let $\mathcal {N}=\pi _1(\mathbb {L}_{\mathscr {W}_0/\mathscr {Y}_0})$ denote the corresponding conormal bundle on $(\mathscr {W}_0)_{\mathrm {cl}}$ . After replacing $\mathscr {Y}$ with an étale neighborhood of $\mathscr {W}_0$ [Reference Alper, Hall and RydhAHR19, Prop. 7.18(4)], we may assume that $\mathcal {N}$ extends to a vector bundle $\mathcal {E}$ on $\mathscr {Y}$ .

Let F denote the homotopy fiber of $\mathcal {O}_{\mathscr {Y}_0}\to \mathcal {O}_{\mathscr {W}_0}$ . Since the Hurewicz map $F\otimes _{\mathcal {O}_{\mathscr {Y}_0}} \mathcal {O}_{\mathscr {W}_0}\to \mathbb {L}_{\mathscr {W}_0/\mathscr {Y}_0}[-1]$ is an isomorphism on $\pi _0$ , we have an induced isomorphism $\mathcal {E}|_{(\mathscr {W}_0)_{\mathrm {cl}}}\simeq \mathcal {N}\simeq F|_{(\mathscr {W}_0)_{\mathrm {cl}}}$ . Since $\mathscr {Y}_0$ is cohomologically affine, this lifts to a map $\mathcal {E}|_{\mathscr {Y}_0}\to F$ . The composition $s_0\colon \mathcal {E}|_{\mathscr {Y}_0}\to F\to \mathcal {O}_{\mathscr {Y}_0}$ corresponds to a section $s_0^\vee $ of $\mathcal {E}^\vee |_{\mathscr {Y}_0}$ and the derived zero-locus of this section $\mathscr {Z}_0:=\{s_0^\vee =0\}\hookrightarrow \mathscr {Y}_0$ defines a quasi-smooth closed immersion. Here, the derived zero-locus is the pullback fitting in the Cartesian square

The map $s_0\colon \mathcal {E}|_{\mathscr {Y}_0}\to F$ corresponds to a $2$ -commutative diagram

and hence to a map $\mathscr {W}_0\to \mathscr {Z}_0$ . By construction, we have that $\mathbb {L}_{\mathscr {W}_0/\mathscr {Z}_0}=0$ so the closed immersion $\mathscr {W}_0\to \mathscr {Z}_0$ is also an open immersion. After replacing $\mathscr {Y}$ with an open neighborhood of $\mathscr {W}_0$ , we can thus assume that $\mathscr {W}_0=\mathscr {Z}_0$ .

Finally, we may lift the section $s_0^\vee $ of $\mathcal {E}^\vee |_{\mathscr {Y}_0}$ to a section $s^\vee $ of $\mathcal {E}^\vee $ since $\mathscr {Y}$ is cohomologically affine. The derived zero-locus $\mathscr {W}:=\{s^\vee =0\}\hookrightarrow \mathscr {Y}$ is a quasi-smooth closed immersion restricting to $\mathscr {W}_0\hookrightarrow \mathscr {Y}_0$ and the composition $f\colon \mathscr {W}\hookrightarrow \mathscr {Y}\to \mathscr {X}$ is a quasi-smooth morphism such that $f|_{\mathscr {X}_0} \simeq f_0$ .

A Nonexistence of Zariskification

In this section, we show that the Zariskification, in contrast to the henselization, does not exist in general. This counterexample was mentioned in [Reference Temkin and TyomkinTT17, 3.1.2].

Let X be a scheme and $Z\hookrightarrow X$ be a closed subscheme. The generization of Z is the subset of X consisting of all points $x\in |X|$ such that $\overline {\{x\}}\cap Z\neq \emptyset $ . A Zariskification of X along Z is a flat quasi-compact monomorphism $W\to X$ such that the image is the generization of Z. The Zariskification is unique up to isomorphism since if W and $W'$ are two monomorphisms as above, then $W\times _X W'\to W$ and $W\times _X W'\to W'$ are faithfully flat quasi-compact monomorphisms, hence isomorphisms.

If $X=\operatorname {\mathrm {Spec}} A$ is an affine scheme and $Z=\operatorname {\mathrm {Spec}}(A/I)$ is a closed subscheme, then the Zariskification exists and equals $W=\operatorname {\mathrm {Spec}}\bigl ( (1+I)^{-1}A\bigr )$ [Reference RaynaudRay70, §2]. If $Z=\{x_1,x_2,\dots ,x_n\}$ is a finite set of points, then the Zariskification is the semi-localization at Z.

In the following example, we show that the Zariskification at two points of Hironaka’s nonprojective proper smooth threefold does not exist.

Example A.1 (Nonexistence of Zariskification)

Let X be a projective threefold and $c,d$ curves as in [Reference HartshorneHar77, p. 443]. Let $X'$ be the nonprojective proper threefold given by gluing the different blow-ups and let $l_0$ , $m_0$ , $l^{\prime }_0$ and $m^{\prime }_0$ be curves on $X'$ as in loc. cit. and let $P'=l_0 \cap m_0$ and $Q'=l^{\prime }_0\cap m^{\prime }_0$ .

There is no affine neighborhood containing both $P'$ and $Q'$ . We claim that the generization E of $P'$ and $Q'$ is not pro-open (i.e., not represented by a flat quasi-compact monomorphism). For this, we can use Raynaud’s criterion for locally factorial schemes [Reference RaynaudRay68, Cor. 2.7]. Hence, it is enough to show that there is a point $x'$ not in E such that every divisor containing $x'$ intersects E (i.e., intersects $P'$ or $Q'$ ). But since $l_0+m^{\prime }_0$ is numerically trivial, every divisor that intersects $l_0$ properly contains $m^{\prime }_0$ . In particular, every divisor intersecting $l_0$ contains either $P'$ or $Q'$ . Raynaud’s criterion is thus not satisfied for a point $x'$ on $l_0$ (not equal to $P'$ ).

Example A.2 (Algebraic space without Zariski-localization at a point)

For a suitable choice of X and curves $c,d$ , one can endow Hironaka’s proper threefold $X'$ with a free action of $G=\mathbb {Z}/2\mathbb {Z}$ that interchanges $P'$ and $Q'$ . The quotient $X'/G$ is then not a scheme since the image of $\{P',Q'\}$ is a point z that does not admit an affine neighborhood. Moreover, the Zariskification at z does not exist. Indeed, if there is a flat monomorphism $W\to X'/G$ of algebraic spaces with image the generization of z, then it pulls back to a flat monomorphism $W'\to X'$ with image the generization of $P'$ and $Q'$ . Since $W'$ is a scheme (see [SP, 0B8A] or [Reference Temkin and TyomkinTT17, Thm. 3.1.5]), this contradicts Example A.1.

Acknowledgements

The first author was partially supported by NSF grant DMS-1801976 and DMS-2100088. The second author was partially supported by the Australian Research Council DP210103397 and FT210100405. The third author was partially supported by NSF grants DMS-1945478 (CAREER), DMS-1601967, a Simons Collaboration Grant and the Alfred P. Sloan Foundation. The fourth author was supported by the Swedish Research Council 2015-05554 and the Göran Gustafsson Foundation for Research in Natural Sciences and Medicine.

Competing interest

The authors have no conflict interest to declare.

Footnotes

1 When $f_0$ is étale, we do not need [Reference RydhRyd23]. Indeed, then $\mathscr {X}_0$ is Deligne–Mumford so after replacing $\mathscr {X}$ with an open neighborhood of $\mathscr {X}_0$ , we may assume that $\mathscr {X}$ is Deligne–Mumford, hence of global type and approximation type [Reference RydhRyd15, Def. 2.1, Prop. 2.10].

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