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On the properness of the moduli space of stable surfaces over $\mathbb{Z}$[1/30]

Published online by Cambridge University Press:  29 November 2024

Emelie Arvidsson
Affiliation:
Mathematics Department, University of Utah, Salt Lake City, UT, USA. arvidsson@math.utah.edu
Fabio Bernasconi
Affiliation:
Mathematik und Informatik, Universität Basel, 4051 Basel, Switzerland. Dipartimento di Matematica “Guido Castelnuovo”, SAPIENZA Università di Roma, Roma, Italy. fabio.bernasconi@unibas.ch
Zsolt Patakfalvi
Affiliation:
EPFL SB MATH CAG, MA C3 615 (Bâtiment MA), Lausanne, Switzerland. zsolt.patakfalvi@epfl.ch
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Abstract

We show the properness of the moduli stack of stable surfaces over $\mathbb{Z}\left[ {1/30} \right]$, assuming the locally-stable reduction conjecture for stable surfaces. This relies on a local Kawamata–Viehweg vanishing theorem for 3-dimensional log canonical singularities at closed point of characteristic $p \ne 2,3$ and $5$, which are not log canonical centres.

Type
Research Article
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, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of the Foundation Composition Mathematica, in partnership with the London Mathematical Society

1. Introduction

In [Reference Deligne and MumfordDM69, Theorem 5.2], Deligne and Mumford proved that the moduli stack of stable curves $\overline{\mathcal{M}}_g$ of given genus $g \geq 2$ is a proper Deligne-Mumford (DM) stack over $\mathbb{Z}$ . By introducing stable curves (i.e. curves with at worst nodal singularities and ample canonical class) into the moduli problem, they were able to construct a natural compactification of the moduli of smooth curves of genus $g$ , which led to interesting applications, such as the proof of irreducibility of $\mathcal{M}_g$ [Reference Deligne and MumfordDM69], and the proof of general semi-stable reduction for curves in [Reference de JongdJ97].

The natural higher-dimensional generalisation of smooth curves of genus at least 2 are smooth canonically polarised varieties. Hence, it is natural to look for a compactification of the moduli space of these. A possible approach has been proposed by Kollár and Shepherd-Barron in [Reference Kollár and Shepherd-BarronKSB88] using the Minimal Model Program (MMP for short). According to Kollár and Shepherd-Barron, the correct generalisation of stable curves to arbitrary dimensions are stable varieties, projective varieties with semi-log canonical singularities and ample canonical class. We refer to the book [Reference KollárKol23b] for a comprehensive treatment of the construction of the moduli space of stable varieties in characteristic 0.

The case of positive and mixed characteristic presents further difficulties. To mention a few: the MMP is still largely conjectural in dimension $\gt 3$ , the invariance of plurigenera (even asymptotic) is known to fail [Reference BrivioBri23, Reference KollárKol23a], the singularities of the MMP are cohomologically more complicated [Reference Cascini and TanakaCT19, Reference BernasconiBer19] and other problems arise due to presence of inseparable morphisms [Reference KollárKol23b, Section 8.8]. However the MMP for 3-folds in positive characteristic $p \geq 5$ and mixed characteristic $(0, p\gt 5)$ has now been established [Reference Hacon and XuHX15, Reference Cascini, Tanaka and XuCTX15, Reference BirkarBir16, Reference Birkar and WaldronBW17, Reference Das and WaldronDW22, Reference Hacon and WitaszekHW22, Reference Takamatsu and YoshikawaTY23, Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23] and, following the strategy in characteristic 0, many of the steps needed for the construction of the moduli space $\overline{\mathcal{M}}_{2,v}$ of stable surfaces have been proven in [Reference Hacon and KovácsHK19, Reference PatakfalviPat17, Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Reference PosvaPos21a, Reference PosvaPos21b]. Nowadays, we know that $\overline{\mathcal{M}}_{2,v}$ exists as a separated Artin stack with finite diagonal over $\mathbb{Z}[1/30]$ by [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Corollary 10.2], but whether it is proper remains still an open question. Our main result is the following, where locally-stable reduction means a weakening of semi-stable reduction; see Definition 4.11 for the precise definition.

Theorem 1.1. Assume the existence of locally-stable reduction for surfaces. Then the moduli stack $\overline{\mathcal{M}}_{2,v}$ of stable surfaces of volume $v$ is proper over $\mathbb{Z}[1/30]$ .

The main technical result needed to prove Theorem 1.1 concerns the depth of 3-dimensional log canonical singularities, which we briefly explain. In [Reference PosvaPos21b, Theorem 6.0.5], Posva reduced the valutative criterion of properness for the stack $\overline{\mathcal{M}}_{2,v}$ to two conjectures on families of stable surfaces over a DVR: roughly speaking, the existence of semi-stable reduction and the $(S_2)$ -condition of the central fibre of a locally stable family of surfaces. To prove the $(S_2)$ -condition of the central fibre, it is thus natural to study the $(S_3)$ -condition at a closed point $x$ of a log canonical 3-fold singularity.

Let us first explain what the tools used to prove the $(S_2)$ -condition in characteristic 0 are, as we will mimic this approach. In [Reference KollárKol13, Theorem 7.20], a local version of the Kawamata–Viehweg vanishing theorem concerning the depth of divisorial sheaves on divisorially log terminal (dlt) and log canonical pairs in characteristic 0 is presented (similar results were obtained previously by Alexeev and Hacon [Reference AlexeevAle08, Reference Alexeev and HaconAH12]).

Theorem 1.2 (Local Kawamata–Viehweg vanishing for log canonical pairs). Let $(X,\Delta )$ be a log canonical pair over a field of characteristic 0. Let $D$ be a $\mathbb{Z}$ -divisor such that $D \sim _{\mathbb{Q}} \Delta ^{\prime}$ where $0 \leq \Delta ^{\prime} \leq \Delta$ . If $x$ is a point that is not the generic point of an lc centre, then

\begin{equation*}{\mathrm {depth}}_{x} \mathcal {O}_X(-D) \geq \min \left \{3, {\mathrm {codim}}_X x \right \}.\end{equation*}

This local vanishing is one of the crucial ingredients for the properness of the moduli functor as shown in [Reference KollárKol23b, Definition-Theorem 2.3], where 1.2 is used to prove the $(S_2)$ -condition on the central fibre of a locally stable family. For this reason it is natural to consider whether Theorem 1.2 remains true in positive and in mixed characteristics. The examples of klt not CM 3-fold singularities (see [Reference Cascini and TanakaCT19, Reference BernasconiBer21, Reference Arvidsson, Bernasconi and LaciniABL22]) show that Theorem 1.2 is false in equicharacteristic $p \leq 5$ . On the contrary, in [Reference Arvidsson, Bernasconi and LaciniABL22] the first two authors showed together with Lacini that 3-fold klt singularities are Cohen–Macaulay in characteristic $p\gt 5$ , and this was later extended by the second author and Kollár in [Reference Bernasconi and KollárBK23, Theorem 17] to a local Kawamata–Viehweg vanishing on 3-dimensional excellent dlt singularities whose residue field is perfect of characteristic $p\gt 5$ (analogue to [Reference KollárKol13, Theorem 7.31]). Moreover, in [Reference Patakfalvi and SchwedePS14, Theorem 3.8], the third author and Schwede prove a local Kawamata–Viehweg vanishing for sharply $F$ -pure singularities. From all these results, it would be natural to expect an analogue of Theorem 1.2 for 3-dimensional log canonical singularities to hold, at least in large characteristics. Unfortunately, we show that this is not the case.

Theorem 1.3 (See Section 5). For every prime $p\gt 0$ , there exist a 3-dimensional log canonical singularity $x \in X$ such that

  1. (i) the residue field of the closed point $x$ is perfect of characteristic $p$ ;

  2. (ii) $x$ is not a minimal log canonical centre;

  3. (iii) ${\mathrm{depth}} (\mathcal{O}_{X,x})=2$ .

Nevertheless, we are able to obtain a weaker local Kawamata–Viehweg vanishing statement, which is sufficient to deduce the properness of the moduli space $\overline{\mathcal{M}}_{2,v}$ . See Section 2.1 for the notion of pair used in the article.

Theorem 1.4. Let $C \subset (X,\Delta )$ be a 1-dimensional minimal log canonical centre of a 3-dimensional log canonical pair $(X,X_0+\Delta ),$ and let $x \in C$ be a closed point with perfect residue field of characteristic $p \neq 2, 3$ and $5$ . If $X_0$ is Cartier and $x \in X_0$ , then $\mathcal{O}_{X,x}$ is $(S_3)$ and $X_0$ is $(S_2)$ at $x$ .

To prove Theorem 1.4, we find a clear geometric reason for the failure of the $(S_3)$ -condition at a closed point $x$ of a log canonical 3-dimensional singularity $X$ , which is not a log canonical centre.

Theorem 1.5. Let $(X,\Delta )$ be a 3-dimensional log canonical pair on the spectrum of a local ring, such that the residue field of the closed point $x$ is perfect of characteristic $p \neq 2,3, 5$ . Let $C \subset X$ be a 1-dimensional minimal log canonical centre for $(X,\Delta )$ . Then there exists a proper birational modification $f \colon Z \to X$ such that

  1. (i) $Z$ is Cohen–Macaulay,

  2. (ii) the exceptional divisor $E$ is $(S_2)$ , and for each point $c \in C$ , $E$ is normal at the generic points of the fibre $E_c$ ;

  3. (iii) $H^2_x(X, \mathcal{O}_X) \simeq H^0_x(C, R^1f_*\mathcal{O}_E)$ .

In particular, if $\mathcal{O}_{X,x}$ is not $(S_3)$ , then $E \to C$ has a wild fibre over $x$ .

We now give an overview of the article. In Section 2, we collect the various technical results on surfaces and 3-folds that we need for our proofs. In Section 3, using the MMP for 3-folds and the Kawamata–Viehweg vanishing for log canonical surfaces admitting a morphism to a curve, we show Theorem 1.5. In Section 4, we review the theory of wild fibers of a fibred surface $f\colon E\to C$ , developed by Raynaud in [Reference RaynaudRay70], which we apply in combination with Theorem 1.5 to conclude 1.4 in 4.2. In Subsection 4.3, we combine the previous results to show Theorem 1.1 and we also present an application to the asymptotic invariance of plurigenera for minimal models of log canonical surfaces of log general type. In Section 5, we show the counterexample 1.3 by applying a relative cone construction to an elliptic surface fibration with a wild fibre.

Remark 1.6. While completing this work, the first author has found an alternative construction [Reference ArvidssonArv23, Theorem 2] that can replace the role played by Theorem 1.5 in this work. This construction simplifies some of the technical arguments in this article. Indeed, the main technical difficulty in the present approach is that in Theorem 1.5, the modification $Z$ together with the crepant bounday is not, in general, dlt, but only étale dlt. In [Reference ArvidssonArv23, Theorem 2] the first author proves an analogous statement using a possibly non- $\mathbb{Q}$ -factorial dlt modification. We believe that the various vanishing statements discussed here may be of independent interest.

2. Preliminaries

2.1 Basic notation

Notation 2.1. Throughout this article we work over a fixed base ring $R$ , and $X$ , $Y$ and $Z$ always denote quasi-projective schemes of pure dimension $n$ over $R$ , unless otherwise stated.

The base ring $R$ is always be assumed to be Noetherian, excellent, of finite Krull dimension, and admitting a dualising complex $\omega _{R}^{\bullet }$ . Furthermore, $R$ will always be assumed to be of pure dimension $d$ . Here, and in general in the present article, dimension means the absolute dimension, not the relative dimension over $R$ .

We normalise $\omega _{R}^{\bullet }$ as in [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Section 2.1]: $H^{-i}(\omega _R^{\bullet }) =0$ if $i\gt d$ and with $H^{-d}(\omega _R^{\bullet }) \neq 0$ . The first non-zero cohomology sheaf $\omega _R := H^{-d}(\omega _R^{\bullet })$ is the dualising sheaf of $R$ . For the upper-shriek functor, we follow the convention of [Sta, Tag 0A9Y]. By [Sta, Tag 0AA3], the complex $\omega _X^{\bullet } := \pi ^{!} \omega _R^{\bullet }$ is a dualising complex for $X$ , where $\pi \colon X \to{\mathrm{Spec}}(R)$ is the structure morphism. We then define the dualising sheaf $\omega _X$ of $X$ to be the first non-zero cohomology sheaf of the complex $\omega _X^\bullet$ .

We say that $X$ is a curve (resp. a surface, a 3-fold) if it is a connected reduced scheme of dimension 1 (resp. 2, 3). We say a proper morphism $f \colon X \to Y$ is a contraction if $f_*\mathcal{O}_X=\mathcal{O}_Y$ .

Given a closed subscheme $Z$ of $X$ , we denote by $\Gamma _{Z,X}$ the functor of global sections with support on $Z$ . The induced right-derived functor is denoted by $R\Gamma _{Z,X}$ and its $i$ -th cohomology by $R^i \Gamma _{Z,X}$ (or $H^i_Z(X, -)$ ). These groups are called the $i$ -th local cohomology groups with support on $Z$ .

A Weil $\mathbb{Q}$ -divisor $D$ on a connected reduced scheme $X$ is a formal sum of codimension $1$ integral subschemes with rational coefficients. As we will work with non-normal schemes, we recall the definition of the more restrictive class of Mumford divisors following [Reference KollárKol23b].

Definition 2.2. A Weil $\mathbb{Q}$ -divisor $B$ on $X$ is called a Mumford $\mathbb{Q}$ -divisor if $X$ is regular at all generic points of ${\mathrm{Supp}} B$ .

Equivalently, $B$ is Mumford if ${\mathrm{Supp}} B$ does not contain any irreducible component of codimension 1 of the divisorial part of the conductor $D \subset X$ . We say a Mumford $\mathbb{Q}$ -divisor $D$ is $\mathbb{Q}$ -Cartier if there exists $n\gt 0$ such that $nD$ is a Cartier divisor. We refer to [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Section 2.5] for the various notions of positivity (as ample, nef, big) for $\mathbb{Q}$ -Cartier $\mathbb{Q}$ -divisors. When $R=k$ is a field and $X$ is integral, then for a nef $\mathbb{Q}$ -Cartier $\mathbb{Q}$ -divisor $L$ , the numerical dimension of $L$ is $\nu (L):=\text{max} \left \{n \geq 0 \mid L^{n} \neq 0 \right \}$ .

Definition 2.3. We say $(X, \Delta )$ is a couple if

  1. (i) $X$ is a reduced, pure-dimensional, $(S_2)$ and $(G_1)$ (where the latter means that $\omega _X$ is locally free at codimension 1 points of $X$ ) scheme,

  2. (ii) $\Delta$ is an effective Mumford $\mathbb{Q}$ -divisor.

An open set $U \subset X$ is big if ${\mathrm{codim}}_{X}(X \setminus U) \geq 2$ . If $X$ is $(S_2)$ and $(G_1)$ , then any reflexive sheaf is determined on big open sets, and a Mumford divisor $D$ defines a reflexive sheaf $\mathcal{O}_X(D)$ [Reference HartshorneHar94]. By [Reference KollárKol13, Paragraph 5.6], in this case the Mumford class group coincides with the group of isomorphism classes of reflexive sheaves of rank 1 that are locally free in codimension $1$ . As a consequence, if $X$ is pure-dimensional, $(S_2)$ and $(G_1)$ , then there exists a Mumford divisor $K_X$ such that $\mathcal{O}_X(K_X) \simeq \omega _X$ (note that $\omega _X$ is reflexive by [Sta, Tag 0AWN]).

Definition 2.4. We say a couple $(X, \Delta )$ is a pair if $K_X+\Delta$ is a Mumford $\mathbb{Q}$ -Cartier divisor.

If $(X, \Delta )$ is a pair and $X$ is normal, for every proper birational morphism of normal schemes $\pi \colon Y \to X$ , we can write

\begin{equation*}K_Y+\pi _*^{-1}\Delta =\pi ^{*}(K_X+\Delta )+\sum _i a(E_i, X, \Delta ) E_i,\end{equation*}

where $E_i$ run through the $\pi$ -exceptional divisors and $a(E_i, X, \Delta ) \in \mathbb{Q}$ are called the discrepancies of $E_i$ with respect to $(X,\Delta )$ . We define $\Delta _Y:=\pi _*^{-1}\Delta -\sum _i a(E_i, X, \Delta ) E_i$ as the crepant pull-back of $\Delta$ on $Y$ . We say that $(X, \Delta )$ is a klt (resp. log canonical or lc) pair if $X$ is normal and if for every proper birational maps of normal schemes $\pi \colon Y \to X$ , $\lfloor{\Delta _Y \rfloor } \leq 0$ (resp. the coefficients of $\lfloor{\Delta _Y \rfloor }$ are $\leq 1$ ).

We say that a pair $(X,D)$ of pure dimension $n$ is snc (=simple normal crossings) if for every closed point $x \in X$ , $X$ is regular at $x$ and if there exists local coordinates $t_1, \dots, t_n$ such that ${\mathrm{Supp}}(D) \subset (t_1 \cdots t_n=0)$ . Note that being snc is a local property in the Zariski topology (but not in the étale topology). We denote by ${\mathrm{nsnc}}(X, \Delta )$ the non-snc locus of $(X, \Delta )$ . We say that $(X, \Delta )$ is dlt if it is log canonical, and for every exceptional divisor $E$ such that ${\mathrm{cent}}_X(E) \subset{\mathrm{nsnc}}(X, \Delta )$ , we have $a(E_i, X, \Delta )\gt -1.$

Definition 2.5. Let $(X, \Delta )$ be a pair. The étale-snc locus ${\mathrm{etsnc}}(X, \Delta )$ is the locus where $(X, \Delta )$ is snc in the étale topology. This is a Zariski open set of $X$ .

We say that a pair $(X,\Delta )$ is étale-dlt if for every exceptional divisor $E$ over $X$ such that ${\mathrm{cent}}_X E \subseteq X \setminus{\mathrm{etsnc}}(X, \Delta )$ we have $a(E; X, \Delta ) \gt -1$ .

2.2 Semi-log canonical singularities

If $X$ is reduced, then we can consider its normalisation morphism $\pi \colon \overline{X} \to X$ (see [Sta, Tag 035N]). The conductor ideal of $\pi$ is the largest ideal $\mathcal{I}$ of $\mathcal{O}_X$ , which is also an ideal of $\mathcal{O}_{{\overline{X}}}$ . It can be also defined explicitly in multiple ways:

\begin{align*} & \mathcal{I}= \left \{ s \in \mathcal{O}_X \mid s \cdot \pi _* \mathcal{O}_{\overline{X}} \subseteq \mathcal{O}_X \textrm{ as subsheaves of the field of total fractions} \right \}=\\& {\mathrm{im}} \Big ( \left \{\phi \in{\mathrm{Hom}}_{\pi _* \mathcal{O}_{{\overline{X}}}}(\pi _* \mathcal{O}_{{\overline{X}}}, \pi _* \mathcal{O}_{{\overline{X}}}) \mid{{\mathrm{im}} \phi \subseteq \mathcal{O}_X} \right \} \to \mathcal{O}_X \Big ) ={\mathrm{im}} \big ( \mathcal{H}\text{om}_{\mathcal{O}_X}(\pi _{*}\mathcal{O}_{\overline{X}},\mathcal{O}_X) \to \mathcal{O}_X \big ). \end{align*}

The conductor subscheme $D$ of $X$ (resp. $\overline{D}$ of $\overline{X}$ ) is the subscheme defined by $\mathcal{I}$ in $X$ (resp. in $\overline{X}$ ).

We recall the definition of the singularities of the MMP for non-normal varieties, following [Reference KollárKol13]. We start by explaining what a node is.

Definition 2.6 [Reference KollárKol13, 1.41]. We say that a scheme $S$ has a node at a codimension 1 point $s \in S$ if $\mathcal{O}_{S,s} \simeq A/(f)$ , where $(A, \mathfrak{m})$ is a regular local ring of dimension 2, $f \in \mathfrak{m}^2$ and $f$ is not a square in $\mathfrak{m}^2\setminus \mathfrak{m}^3$ . Sometimes we equivalently say that $S$ is nodal at $s \in S$ .

Remark 2.7. Let $(A, \mathfrak{m})$ be a regular local ring of dimension 2, and let $f \in \mathfrak{m}^2$ such that ${\mathrm{Spec}}(A/(f))$ is a node. It is easy to see that the effective divisor given by $(f=0)$ has multiplicity 2 at the closed point of ${\mathrm{Spec}}(A)$ and that $f$ is not irreducible if and only if the pair $(W, D):=({\mathrm{Spec}}(A), (f=0))$ is snc. Examples where the pair is not snc are given in [Reference KollárKol13, Examples, page 1]. If $\text{char}(k(s)) \neq 2$ , then it is clear that there exists an étale neighborhood $V$ of $W$ for which $(V,D_V)$ is snc.

Definition 2.8. The scheme $X$ (quasi-projective over $R$ as assumed in Notation 2.1) is said to be demi-normal if it is pure-dimensional, it satisfies Serre’s condition $(S_2)$ and its codimension 1 points are either regular or nodal.

If $X$ is demi-normal, then $D$ and $\overline{D}$ are reduced closed subschemes of pure codimension $1$ (see [Reference KollárKol13, Line 14 of page 189]. We use the following definition of semi-log canonical pairs in the present article:

Definition 2.9. We say that $(X, \Delta )$ is a semi-log canonical pair (or slc) if

  1. (i) $X$ is demi-normal and $(X, \Delta )$ is a pair;

  2. (ii) the normalised pair $\big (\overline{X}, \overline{D}+\overline{\Delta }\big )$ is log canonical, where $\overline{D}$ is the conductor subscheme.

Note that in Definition 2.9, $\big (\overline{X}, \overline{D}+\overline{\Delta }\big )$ is automatically a pair, as it is crepant to $(X, \Delta )$ . As in this article we are interested in understanding the locus of strictly log canonical singularities, we recall the terminology on log canonical places and centres.

Definition 2.10. Let $(X,\Delta )$ be a pair. We denote by ${\mathrm{nklt}}(X,\Delta )$ the non-klt locus of $(X,\Delta )$ , which is the closed subset of $X$ consisting of points $x$ of $X$ for which $(X,\Delta )$ is not klt near $x$ .

Let $(X,\Delta )$ be a log canonical pair. We say that an irreducible exceptional divisor $E$ for proper birational modification $f \colon Y\to X$ is a log canonical place if $a(E,X,\Delta )=-1$ . A closed subset $Z \subset X$ is a log canonical centre if there exists a log canonical place $E$ such that ${\mathrm{cent}}_X(E)=Z$ .

We recall the construction of double covers of demi-normal varieties explained in [Reference KollárKol13, 5.23]. This allows to reduce many questions to slc pairs whose irreducible components are regular in codimension 1.

Proposition 2.11 [Reference KollárKol13, 5.23]. Let $(X, \Delta )$ be an slc pair such that $\frac{1}{2} \in \mathcal{O}_X$ . Then there exists a finite morphism $\pi \colon \widetilde{X} \to X$ of degree 2 such that

  1. (i) $\widetilde{X}$ is $(S_2)$ ;

  2. (ii) $\pi$ is étale in codimension 1;

  3. (iii) the irreducible components of $\widetilde{X}$ are $(R_1)$ (i.e. regular in codimension 1);

  4. (iv) the normalisation of $\widetilde{X}$ is a disjoint union of two copies of the normalisation of $X$ ;

  5. (v) if $K_{\widetilde{X}} + \Delta _{\widetilde{X}} = \pi ^{\ast }(K_X+\Delta )$ , the pair $(\widetilde{X}, \Delta _{\widetilde{X}})$ is slc.

We need also a non-normal version of dlt-ness. We refer to [Reference KollárKol13, Definition 1.10] for the definition of semi-snc pair.

Definition 2.12. An slc pair $(X,\Delta )$ is semi-dlt if $a(E,X,\Delta )\gt -1$ for every exceptional divisor $E$ such that the generic point of ${\mathrm{cent}}_X E$ is contained in the locus where $(X,\Delta )$ is not semi-snc, where “semi-snc” is defined in [Reference KollárKol13, Def 1.10].

As for dlt, the notion of semi-dlt is not local in the étale topology.

2.3 Log canonical surface singularities

In this section we collect some results on 2-dimensional excellent surface singularities, relying on the classification scheme of [Reference KollárKol13, Section 3.3].

Notation 2.13. Besides the assumptions on our base ring $R$ stated in Notation 2.1, in the present section we suppose that $R$ is integrally closed, local and of dimension 2 with maximal ideal $\mathfrak{m}$ and residue field $k:=R/\mathfrak{m}$ . Additionally, we set $X={\mathrm{Spec}} R$ , and we set $\Delta$ to be a $\mathbb{Q}$ -divisor on $X$ for which $(X, \Delta )=({\mathrm{Spec}}(R), \Delta )$ is a pair. We denote by $x \in X$ the closed point of $X$ .

Definition 2.14. Let $\pi \colon Y \to X$ be a projective birational morphism of normal surfaces. We say that $\pi$ is a log minimal resolution of $(X, \Delta )$ if

  1. (i) $Y$ is regular and $\pi _*^{-1} \lfloor{ \Delta \rfloor }$ is regular (as a closed subscheme);

  2. (ii) $K_Y+\pi _*^{-1} \Delta$ is $\pi$ -nef;

  3. (iii) ${\mathrm{mult}}_y \pi _*^{-1} \Delta \leq 1$ for every $y \in Y$ ;

  4. (iv) the support of ${\mathrm{Ex}}(\pi ) + \pi _*^{-1}\Delta$ has a node at every intersection point of ${\mathrm{Ex}}(\pi )$ and $ \pi _*^{-1} \lfloor \Delta \rfloor$ .

Remark 2.15. The existence of a log minimal resolution for surfaces is proven in [Reference KollárKol13, Theorem 2.25.a]. The construction goes as follows: if $f \colon W \to X$ is a projective log resolution of $(X, \Delta )$ such that $f_*^{-1}\Delta$ is regular, then $Y$ is obtained as the output of a $(K_W+f_*^{-1}\Delta )$ -MMP over $X$ .

We need a slightly modified version of the above in the case of dlt surfaces.

Lemma 2.16. Assume that $(X, \Delta )$ is a dlt surface pair. Then there exists a projective birational morphism $\pi \colon Y \to X$ such that

  1. (i) $Y$ is regular and $K_Y+\pi _*^{-1} \Delta$ is $\pi$ -nef;

  2. (ii) if $K_Y+\Gamma \sim _{\mathbb{Q}} \pi ^*(K_X+\Delta )$ , then $\lfloor \Gamma \rfloor = \pi _*^{-1} \lfloor \Delta \rfloor$ ;

  3. (iii) the support of ${\mathrm{Ex}}(\pi ) + \pi _*^{-1}\Delta$ has a node at every intersection point of ${\mathrm{Ex}}(\pi )$ and $ \pi _*^{-1} \lfloor \Delta \rfloor$ .

Proof. Let $f \colon W \to X$ be a thrifty log resolution of $(X,\Delta )$ [Reference KollárKol13, Lemma 2.79]. As $X$ is a surface, $f$ being thrifty means that it is an isomorphism at the nodes of $\lfloor \Delta \rfloor$ . This we can achieve by running our resolution algorithm by excluding the nodes of $\lfloor \Delta \rfloor$ .

Then run a $(K_W + f_*^{-1}\Delta )$ -MMP over $X$ ending with $\pi \colon Y \to X$ such that $K_Y+\pi _*^{-1}\Delta$ is $\pi$ -nef. As this is also a $K_W$ -MMP, we deduce that $Y$ is regular by [Reference KollárKol13, Theorem 2.29]. As $f$ does not extract log canonical places, (ii) is immediate. To finally verify (iii), we argue as in the proof of [Reference KollárKol13, Theorem 2.25.a].

Our next goal is a precise understanding of the exceptional divisor of a log minimal resolution of a log canonical singularity. We start by recalling [Reference KollárKol13, Theorem 2.31] on the reduced boundary of 2-dimensional log canonical singularities.

Theorem 2.17. Assume that $(X,\Delta = E + D)$ is log canonical, where $E=\sum _i E_i$ has only coefficients 1. Then either:

  1. (i) $E$ is regular at $x$ , or

  2. (ii) $E$ has a node at $x$ , no components of the support of $D$ contain $x$ and every exceptional divisor of a minimal log resolution has discrepancy $-1$ .

We will need the following observation on conics.

Lemma 2.18. Let $k$ be a separably closed field, and let $C$ be a $k$ -projective integral Gorenstein curve. Suppose that $C$ is singular and ${\mathrm{char}} k \neq 2$ . Then $\deg _k \omega _{C/k} \geq 0$ .

Proof. Without loss of generality we can suppose $k=H^0(C, \mathcal{O}_C)$ . Suppose by contradiction that $\deg _k \omega _{C/k} \lt 0$ . By [Reference KollárKol13, Lemma 10.6], $C$ embeds as a conic in $\mathbb{P}^2_k$ . Taking the base change to $\overline{k}$ , we still get an embedding $C_{\overline{k}} \rightarrow \mathbb{P}^2_{\overline{k}}$ . As $k$ is separably closed, $C_{\overline{k}}$ is still an irreducible conic, and by the classification of conics over an algebraically closed field, either $C_{\overline{k}}$ is regular or it is a double line. Note that the case of a double line cannot appear as ${\mathrm{char}}(k) \neq 2$ by [Reference Bernasconi and TanakaBT22, Lemma 2.17]. Finally, if $C_{\overline{k}}$ is regular, we deduce $C$ is regular by descent for faithfully flat morphisms [Sta, Tag 033E], getting a contradiction.

Example 2.19. The following examples show that the assumptions in Lemma 2.18 are sharp. Let $k$ be a field, and consider the conic

\begin{equation*}C:= \left \{ x^2-uy^2=0 \right \} \subset \mathbb {P}^2_{k}={\mathrm {Proj}} k[x,y,z],\end{equation*}

where $u \in k$ . By the Jacobian criterion [Sta, Tag 07PF], it is easy to see that the only non-regular point of $C$ is $p=[0:0:1]$ . Note that $\deg _k \omega _{C/k} =-2$ . This example shows that the assumptions of Lemma 2.17 are indeed necessary:

  • If ${\mathrm{char}} k \neq 2$ and $u \not \in k^2$ , then $C$ is integral, singular and with $\deg _k \omega _{C/k} \lt 0$ , but $k$ is not separably closed.

  • If ${\mathrm{char}} k \neq 2$ and $k$ is separably closed, then $C$ is singular and with $\deg _k \omega _{C/k} \lt 0$ , but $C$ is not integral.

  • If ${\mathrm{char}} k = 2$ , $k$ is separably closed and $u \not \in k^2$ , then $C$ is integral, singular and with $\deg _k \omega _{C/k} \lt 0$ . Geometrically, $C_{\overline{k}}$ is a double line.

Proposition 2.20. Assume that $(R,m)$ is strictly Henselian with ${\mathrm{char}} k=p \neq 2$ , and that $(X, \Delta )$ is log canonical such that $\Delta$ is a $\mathbb{Q}$ -divisor. Let $\pi \colon Y \to (X, \Delta )$ be a log minimal resolution as in Definition 2.14 . Then one of the following holds:

  1. (i) $\Delta =0$ and there exists an irreducible nodal curve $E \subset{\mathrm{Ex}}(\pi )$ . Then ${\mathrm{Ex}}(\pi )=E$ , $K_Y + E \equiv _X 0$ and $(Y,E)$ is étale-snc;

  2. (ii) $(Y,\pi _*^{-1} \lfloor{\Delta \rfloor }+{\mathrm{Ex}}(\pi ))$ is snc.

Proof. The proof is case by case.

$\fbox{$There\ exists\ a\ singular\ exceptional\ curve\ E \subset{\mathrm{Ex}}(\pi )\textit{:}$}$ By Lemma 2.18, $\deg _k \omega _{C/k} \geq 0$ in this case. By [Reference KollárKol13, 3.30.1], then $\Delta =0$ , and $E$ is the unique exceptional divisor. Let $-1 \leq a \in{\mathbb{Q}}$ be the discrepancy of $E$ . By adjunction we have

(1) \begin{equation} 0 \leq \deg K_E \leq (K_X +E) \cdot E = (K_X - aE) \cdot E + (1+a) E^2 = (1+ a ) E^2 \leq 0. \end{equation}

In particular, we have equality everywhere. Taking into account that $E^2\lt 0$ , this means that $a=-1$ . We obtain that $(Y,E)$ is log canonical. Taking into account that $Y$ is regular, we deduce that $(Y,E)$ is étale-snc. To see $K_Y + E \equiv _X 0$ , we simply note that $(K_Y +E ) \cdot E =0$ by Equation (1).

$\fbox{$All\ irreducible\ component\ E_{i}\ of\ {\mathrm{Ex}}(\pi )\ are\ regular\textit{:}$}$ Note that $\pi _*^{-1} \lfloor{\Delta \rfloor }$ is regular and that ${\mathrm{Ex}}(\pi ) + \pi _*^{-1} \lfloor{\Delta \rfloor }$ is snc at intersection points by construction of the minimal resolution, in this case. We are left to prove that ${\mathrm{Ex}}(\pi )$ is snc. We can suppose that all irreducible components are conics by [Reference KollárKol13, 3.30.2], and we fix $r_i:=\dim _k H^0(E_i, \mathcal{O}_{E_i})$ .

$\fbox{$All\ the\ E_{i}\ are\ regular,\ and\ (E_i \cdot E_j) \gt \max \left \{r_i, r_j\right \}\ for\ some\ i \neq j\textit{:}$}$ In this case $\Delta =0$ and there are two exceptional curves $E_1$ and $E_2$ , by [Reference KollárKol13, 3.30.3]. Consider the following computation:

\begin{align*} &0 \leq E_1 \cdot E_2 + \deg K_{E_1} \leq (K_X +E_1 + E_2) \cdot E_1\\ &= (K_X - a_1E_1 - a_2E_1) \cdot E_1 + (1+a_1) E_1^2 + (1+a_2) E_1 \cdot E_2 = (1+a_1) E_1^2 + (1+a_2) E_1 \cdot E_2 \end{align*}

This implies that

(2) \begin{equation} -(1+a_1) E_1^2 \leq (1+ a_2) E_1 \cdot E_2. \end{equation}

By applying the same argument to $E_2$ instead of to $E_1$ , we obtain

(3) \begin{equation} -(1+a_2) E_2^2 \leq (1+ a_1) E_1 \cdot E_2. \end{equation}

Multiplying (2) and (3) together, we obtain the following, where we are also using that both sides of the two inequalities are non-negative:

(4) \begin{equation} (1+a_2) (1+a_1) (E_1^2)( E_2^2) \leq (1+ a_1) (1+a_2) (E_1 \cdot E_2)^2. \end{equation}

In other words, either one of the $a_i$ is equal to $-1$ , or the determinant of the intersection matrix is non-positive. The latter contradicts the negative definiteness of the intersection matrix; hence, we obtain that one of the $a_i$ is $-1$ . By symmetry we can assume that $a_1=-1$ . However, then (3) says that $(1+a_2) E_2^2 \geq 0$ . As $E_2^2\lt 0$ , this implies also that $a_2=-1$ .

In particular, $(Y, E_1 + E_2)$ are log canonical, and hence, by adjunction, so are $(E_1, E_1 \cap E_2)$ and $(E_2, E_1 \cap E_2)$ . This means that the coefficients of $E_1 \cap E_2$ are $1$ on both $E_1$ and $E_2$ . As $k$ is separably closed, all finite non-trivial extensions of $k$ have degree divisible by $p$ . As $E_1 \cdot E_2 =2$ and $p \neq 2$ , in fact $E_1 \cap E_2$ contains only points with residue field equal to $k$ . As above we have seen that the coefficients of these points cannot be more than $1$ , so we obtain that $E_1 \cap E_2$ has two distinct points with coefficient $1$ and, hence, that the intersection of $E_1$ and $E_2$ is transversal. In particular, $(Y, E_1 + E_2)$ is snc (and the singularity is a cusp with the exceptional divisor of the minimal resolution being a cycle of two conics).

$\fbox{$All\ the\ E_{i}\ are\ regular,\ and\ (E_i \cdot E_j) =\max \left \{r_i, r_j\right \}\ for\ all\ i\ and\ j\textit{:}$}$ fix two components $E_i$ and $E_j$ . We may assume by symmetry that $r_i \geq r_j$ . In particular, the intersection scheme $E_i \cap E_j$ is a length one Artinian scheme over $H^0(E_i, \mathcal{O}_{E_i})$ . This implies that $E_i \cap E_j$ is reduced. Hence, the intersection of $E_i$ and $E_j$ is transversal, which concludes our proof.

The following is well-known:

Lemma 2.21. Let $f \colon Y \to Z$ be a projective birational morphism of normal surfaces over $R$ , and let $D$ be a nef $\mathbb{Q}$ -Cartier divisor on $Y$ . If $f_*D$ is $\mathbb{Q}$ -Cartier, then it is nef.

Proof. Let $C$ be a curve on $Z$ , mapping to a closed point of ${\mathrm{Spec}}(R)$ . By projection formula for the Mumford pull-back, we conclude that $f_*D \cdot C =D \cdot f^*C \geq 0$ .

Corollary 2.22. Assume that the characteristic of $k$ is $p \neq 2$ and that $(X={\mathrm{Spec}}(R), \Delta )$ is log canonical. Then there exists a projective birational morphism $f \colon Z \to X$ such that

  1. (i) $\big (Z,f_*^{-1}\lfloor \Delta \rfloor +{\mathrm{Ex}}(f)\big )$ is étale-dlt,

  2. (ii) $K_Z+f_*^{-1}\Delta +{\mathrm{Ex}}(f)=f^*(K_X+\Delta )$ , and

  3. (iii) $-{\mathrm{Ex}}(f)$ is nef over $X$ .

Proof. First, we may assume that $R$ is strictly Henselian. Second, let $\pi \colon Y \to X$ be as in Definition 2.14. By Proposition 2.20, there are two cases. In case i, $\Delta =0$ $\big (Y,{\mathrm{Ex}}(\pi )\big )$ is étale-snc and ${\mathrm{Ex}}(\pi )$ is a single exceptional divisor; necessarily, then, anti- $f$ -nef. In this case, $f:=\pi$ satisfies the assertion of the theorem.

In case ii, the pair $\big (Y, \pi _*^{-1}\lfloor \Delta \rfloor +{\mathrm{Ex}}(\pi )\big )$ is snc. By [Reference TanakaTan18, Theorem 1.1.(QF)], we can run a $\big (K_Y+\pi _*^{-1}\Delta +{\mathrm{Ex}}(\pi ) \big ) \equiv _X \big (\sum _i (1+a(E_i, X, \Delta ) E_i\big )$ -MMP over $X$ , denoted by $\rho \colon Y \to Z$ , ending with a minimal model $f \colon Z \to X$ . By a standard application of the negativity lemma [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23]*Lemma 2.16, the birational contraction $\rho$ contracts exactly the $\pi$ -exceptional divisors with discrepancy $a(E,X, \Delta )\gt -1$ , and thus $Z$ is a $\mathbb{Q}$ -factorial surface with $(K_Z + f_*^{-1}\Delta +{\mathrm{Ex}}(f)) = f^*(K_X+\Delta )$ . As a $\big (K_Y+\pi _*^{-1}\Delta +{\mathrm{Ex}}(\pi )\big )$ -MMP over $X$ is a $\big (K_Y+\pi _*^{-1}\lfloor \Delta \rfloor +{\mathrm{Ex}}(\pi )\big )$ -MMP,Footnote 1 the pair $\big (Z, f_*^{-1}\lfloor \Delta \rfloor +{\mathrm{Ex}}(f)\big )$ remains dlt. By the definition of the log minimal resolution, $-\sum _i a(E_i, X, \Delta ) E_i$ is nef over $X$ , and therefore, so is $-{\mathrm{Ex}}(f)=\rho _*(-\sum _i (1+a(E_i, X, \Delta )) E_i)$ by Lemma 2.21.

2.4 Dlt modifications and log canonical centers

In this section, we recall dlt modifications and apply their existence to the study of log canonical centres of log canonical 3-folds. Since we will need the MMP developed in [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23], we suppose the following:

Notation 2.23. Besides the assumptions on our base ring $R$ stated in Notation 2.1, we suppose that the characteristic of the residue fields of $R$ are different from $2, 3$ and $5$ .

Definition 2.24. Let $(X,\Delta )$ be a log canonical pair. A proper birational morphism $\pi \colon (Y,\Delta _Y) \to (X, \Delta )$ is a dlt modification (or a dlt blow-up) if $(Y, \Delta _Y)$ is dlt, where $K_Y+\Delta _Y \sim _{\mathbb{Q}} \pi ^*(K_X+\Delta )$ and $\Delta _Y=f_*^{-1}\Delta +E$ , where $E$ denotes the divisorial part of the exceptional locus of $\pi$ .

The existence of a dlt modification for $(X,\Delta )$ , extracting only divisors of discrepancies $-1$ , is a standard consequence of the MMP (see [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Corollary 9.21]).

Proposition 2.25. Let $(X, \Delta )$ be a log canonical 3-fold pair. Then there exists a dlt modification $Y \to (X, \Delta )$ .

We recall some properties of log canonical centres on log canonical excellent 3-fold pairs.

Proposition 2.26. Any intersection of log canonical centres of a 3-dimensional log canonical pair $(X,\Delta )$ is a union of log canonical centres.

Proof. This is [Reference Filipazzi and WaldronFW20, Corollary 1.7] (see also [Reference PosvaPos21b, Corollary 5.2.16] for a proof in the case $X$ is defined over $\mathbb{F}_p$ ).

We will need the following characterisation of plt pairs.

Corollary 2.27. Let $(X, \Delta =D+B)$ be a 3-dimensional log canonical pair, where $D$ is a prime divisor. If $D$ is a minimal log canonical centre, then $(X, \Delta )$ is plt in a neighbourhood of $D$ .

Proof. Suppose by contradiction that $(X,\Delta )$ is not plt around $D$ . By definition, there exists a log canonical centre $S$ such that $Z:=S \cap D$ is not-empty and that ${\mathrm{codim}}_X Z \geq{\mathrm{codim}}_X S \gt 1$ . As $Z$ is a union of log canonical centres by Proposition 2.26, this contradicts the minimality of $D$ .

We will need the following technical result on dlt singularities:

Lemma 2.28. Let $\pi \colon (Y, \Delta _Y) \to (X, \Delta )$ be a proper crepant birational contraction of $\mathbb{Q}$ -factorial pairs. If $(Y, \Delta _Y)$ is dlt and if $a(E, X, \Delta )\gt -1$ for every $\pi$ -exceptional divisor $E$ , then $(X,\Delta )$ is dlt as well.

Proof. Let $E$ be a log canonical place over $(X, \Delta )$ . As $(Y,\Delta _Y)$ is dlt, the generic point of $Z={\mathrm{cent}}_Y(E)$ is a stratum of $(Y, \Delta _Y^{=1})$ , and $E$ is already a log canonical place of $(Y, \Delta _Y^{=1})$ . This in particular implies that $Z \not \subseteq{\mathrm{Supp}} \Delta _Y^{\lt 1}$ . However, as both $X$ and $Y$ are $\mathbb{Q}$ -factorial, the exceptional locus of $\pi$ is purely divisorial. So, putting the last two sentences and the assumption on the discrepancies of the $\pi$ -exceptional divisors together, we obtain that $Z \not \subseteq{\mathrm{Ex}}(\pi )$ . However, that means that $\pi$ is an isomorphism around the generic point of $ \pi (Z)$ , and therefore $\pi (Z)$ is also a stratum of $(X, \Delta ^{=1})$ .

Note that the $\mathbb{Q}$ -factoriality hypothesis in Lemma 2.27 is needed as shown in [Reference FujinoFuj07, Example 3.8.4].

2.5 A restriction sequence for pairs

In this section, we refine the short exact sequences used in [Reference Hacon and WitaszekHW19, Reference Bernasconi and KollárBK23]. We start by recalling some general properties of codimension 1 strata of dlt pairs.

Lemma 2.29. Let $\big (X,\sum _{i\in I} E_i+\Delta \big )$ be a dlt pair, where $E_i$ are prime divisors and $\lfloor \Delta \rfloor =0$ . Then

  1. (i) $E_i$ is $(R_1)$ (i.e. $E_i$ is regular in codimension 1) for every $i \in I$ ;

  2. (ii) the normalisation $n \colon \bigcup E^{n}_i \rightarrow \bigcup E_i$ is the disjoint union of the $(S_2)$ -ifications of the $E_i$ ’s, and it factorises through the $(S_2)$ -ification $\nu \colon E^{\nu } \rightarrow \bigcup E_i$ ;

  3. (iii) if $X$ is $\mathbb{Q}$ -factorial, then $E^{\nu }_{i} \to E_i$ is a universal homeomorphism for every $i \in I$ .

Proof. For i, it is sufficient to localise at codimension 1 points of $E_i$ and apply [Reference KollárKol13, Theorem 2.31]. Then ii follows immediately from i and iii is proven in [Reference Hacon and WitaszekHW23, Lemma 2.1].

We begin by studying the singularities of the étale-dlt surfaces.

Lemma 2.30. Assume that $R$ is local with closed point $x \in X={\mathrm{Spec}} R$ and that $(X, \Delta = E+D)$ is an étale-dlt surface pair such that $\lfloor \Delta \rfloor =E$ . Then either

  1. (i) $(X,E+D)$ is dlt at $x$ ; or

  2. (ii) $X$ is regular, $E$ is irreducible with a node at $x$ and $\Delta =0$ .

In particular, $X$ is $\mathbb{Q}$ -factorial.

Proof. If $E=0$ , then $\lfloor \Delta \rfloor =0$ , and hence $(X, \Delta )$ is klt. This is covered by point 1. Hence, we may assume that $E \neq 0$ . As we work in the local case, this means that $x \in{\mathrm{Supp}} E$ . By [Reference KollárKol13, Proposition 2.15] $(X,\Delta )$ has log canonical singularities. If there is an irreducible component of $E$ that is singular, then $E$ is an irreducible nodal curve and $\Delta =0$ by Theorem 2.16. As $(X, \Delta )$ is étale-dlt, in this case $X$ is regular, so we are in case ii. Thus we may also assume that every irreducible component of $E$ is regular. We may also assume that $x \not \in{\mathrm{etsnc}}(X, \Delta )$ . Note that ${\mathrm{Spec}} R \setminus \{x \} \subseteq{\mathrm{snc}}(X, \Delta )$ , and that all discrepancies over the point $x$ are greater than $-1$ by the étale snc assumption. Hence, $(X, \Delta )$ is actually dlt at $x$ .

For the assertion about $\mathbb{Q}$ -factoriality, we conclude in case i by combining [Reference KollárKol13, Proposition 2.28] and [Reference KollárKol13, Proposition 10.9]; case ii is then immediate.

For étale-dlt surface pairs we need the following statement on the existence of a special resolution not extracting log canonical places.

Lemma 2.31. Let $(X, \Delta =E+\Gamma )$ be an étale-dlt surface pair such that $\lfloor \Delta \rfloor =E$ . Then there exists a projective birational morphism $\pi \colon Y \to X$ such that

  1. (i) $Y$ is a regular surface, and

  2. (ii) by setting $K_Y+\Delta _Y = \pi ^* (K_X+\Delta )$ , we have $\Delta _Y \geq 0$ and $\lfloor{ \Delta _Y \rfloor }=\pi _*^{-1}(E)$ .

Proof. Let $x \in (X, \Delta )$ be a closed point. We divide the proof into two cases. If $(X,\Delta )$ is dlt near $x$ , we take the resolution of singularities at $x$ constructed in Lemma 2.16. If $(X,\Delta )$ is not dlt near $x$ , we do not perform any blow-up as $X$ is already regular around $x$ by Lemma 2.30.

We need the following generalisation of the short exact sequence of [Reference Hacon and WitaszekHW19, Section 3] to étale-dlt surface pairs.

Lemma 2.32. Let $(X, \Delta )$ be a log canonical surface pair. Suppose $\Delta = E +\Delta ^{\prime}$ , where $E$ is a $\mathbb{Z}$ -divisor and $(X,E)$ is étale-dlt. Let $D$ be a $\mathbb{Z}$ -divisor on $X$ such that ${\mathrm{Supp}} D$ does not contain any irreducible component of $E$ or any point of ${\mathrm{Sing}} E$ . Then there exists a canonically defined Mumford $\mathbb{Z}$ -divisor $D_E$ on $E$ such that

  1. (i) $D_E \sim _{\mathbb{Q}} D|_E + \Gamma _E$ for some Mumford $\mathbb{Q}$ -divisor $0\leq \Gamma _E \leq{\mathrm{Diff}}_E(0)\leq{\mathrm{Diff}}_E(\Delta ^{\prime})$ ;

  2. (ii) there exists a short exact sequence of $\mathcal{O}_X$ -modules

    \begin{equation*}0 \to \omega _X(D) \to \omega _X(E+D) \to \omega _E(D_E) \to 0.\end{equation*}

Proof. Recall that $X$ is $\mathbb{Q}$ -factorial by Lemma 2.30. By the assumption that no irreducible component of $ E$ and no point of the singular locus of $E$ is contained in the support of $D$ , the divisor $D|_E$ is a well-defined Mumford $\mathbb{Q}$ -divisor on $E$ .

Let $\pi \colon Y \to X$ be the resolution of the pair $ (X, E)$ given by Lemma 2.31, and write $K_Y+E_Y+\Gamma _Y=\pi ^{*}(K_X+E)$ , where $\lfloor E_Y + \Gamma _Y \rfloor = E_Y=\pi _*^{-1}(E)$ . As $\pi$ extracts no divisor of discrepancy $-1$ , $\pi$ is an isomorphism around the singular points of $E$ . Hence, $ \pi |_{E_Y} : E_Y \to E$ is an isomorphism. For similar reasons, $\lceil \pi ^* D\rceil |_{E_Y}$ does make sense, i.e. the support of $\lceil \pi ^* D\rceil$ intersects $E_Y$ only along its regular locus. Let $D_E$ be the divisor on $E$ corresponding to the divisor $\lceil \pi ^* D\rceil |_{E_Y}$ on $E_Y$ via the isomorphism $\pi |_{E_Y}$ .

As $Y$ is regular, we have the following exact sequence on $Y$ :

(5) \begin{equation} 0 \to \omega _Y(\lceil \pi ^*D \rceil ) \to \omega _Y(E_Y+ \lceil \pi ^{*}D \rceil ) \to \omega _{E_Y}\left (\lceil \pi ^{*}D \rceil |_{E_Y}\right ) \to 0. \end{equation}

Note the following properties:

  1. (i) since $\pi$ does not extract any divisor of discrepancy $-1$ , we have $K_Y+\lceil \pi ^{*}D \rceil \geq \lfloor K_Y+\Gamma _Y+\pi ^*D\rfloor \geq \lfloor \pi ^{*}(K_X+D)\rfloor,$ so $\pi _*(\omega _Y(\lceil \pi ^*D \rceil ))= \omega _{X}(D)$ . Similarly, $\pi _*(\omega _Y(E_Y+ \lceil \pi ^{*}D \rceil ))=\omega _X(E+D)$ ;

  2. (ii) By the above choice of $D_E$ , we have $\pi _* \omega _{E_Y}\left (\lceil \pi ^{*}D \rceil |_{E_Y}\right ) \cong \left ( \pi |_{E_Y} \right )_* \omega _{E_Y}\left (\lceil \pi ^{*}D \rceil |_{E_Y}\right ) \cong \omega _E (D_E)$ .

  3. (iii) by GR vanishing for surfaces [Reference KollárKol13, Theorem 10.4], $R^1\pi _*\omega _Y(\lceil \pi ^*D \rceil )=0$ .

Thus, pushing forward 5 via $\pi$ , we obtain the short exact sequence

\begin{equation*}0 \to \omega _X(D) \to \omega _X(E+D) \to \omega _E(D_E) \to 0.\end{equation*}

We are left to check only that $D_E \sim _{{\mathbb{Q}}} D|_E+\Gamma _E$ for some $0 \leq \Gamma _E \leq{\mathrm{Diff}}_E(0)$ . Note that via the isomorphism $\pi |_{E_Y}$ , $\Gamma _E$ identifies with $(\lceil \pi ^{*}D \rceil -\pi ^*D)|_{E_Y} \geq 0$ . Let $x$ be a point of $X$ , and let $i_x$ be the determinant of the dual graph of the minimal resolution of $X$ at $x$ . By possibly restricting to a neighbourhood of $x$ , we have that $i_x D$ is Cartier by [Reference KollárKol13, Prop 10.9.(3)]. Additionally, by [Reference KollárKol13, Corollary 3.45], the following equality holds:

\begin{equation*} {\mathrm {Diff}}_E(0) =\begin {cases} \left (1-\frac {1}{i_x}\right )x, & \mbox {if } (X,E) \mbox { is plt near } x \\ x, & \mbox {if } (X,E) \mbox { is not plt near } x, \end {cases}\end{equation*}

Since $\lfloor \Gamma _E \rfloor =0$ and $i_x \Gamma _E$ is integral, we finally conclude that $\Gamma _E \leq{\mathrm{Diff}}_E(0) \leq{\mathrm{Diff}}_E(\Delta ^{\prime}).$

In higher dimension we deduce the following generalisation of [Reference Bernasconi and KollárBK23, Lemma 5]:

Proposition 2.33. Let $(X, \Delta )$ be a log canonical pair. Suppose $\Delta =E+\Delta ^{\prime}$ , where $E$ is a $\mathbb{Z}$ -divisor and $(X,E)$ is an étale-dlt pair. Let $\nu \colon E^{\nu } \to E$ be the $(S_2)$ -ification of $E$ . If $D$ is a $\mathbb{Z}$ -divisor on $X$ , then there is a short exact sequence of $\mathcal{O}_X$ -modules:

\begin{equation*}0 \to \omega _X(D) \to \omega _X(E+D) \to ^{r} \nu _*\left (\omega _{E^{\nu }}(D_{E^{\nu }}) \right ), \end{equation*}

where $D_{E^{\nu }} \sim _{\mathbb{Q}} D|_{E^{\nu }}+\Gamma _E$ is a Mumford divisor on $E^{\nu }$ for some $\mathbb{Q}$ -divisor $0\leq \Gamma _{E^{\nu }} \leq{\mathrm{Diff}}_{E^{\nu }}(\Delta ^{\prime})$ . Moreover, $r$ is a surjection at all codimension 1 points in $E$ , and, if $\omega _X(D)$ is $S_3$ , then $r$ is surjective.

Proof. By Lemma 2.30, at the codimension $2$ singular points of $E$ , the $ \mathbb{Z}$ -divisor $D$ is Cartier. Hence, up to replacing $D$ by another divisor in its linear equivalence class, we may assume that $D$ does not contain any component of $E$ and that it also does not contain any singular point of $E$ that has codimension $2$ in $X$ . By localising at codimension 2 points of $X$ and applying Lemma 2.32, there exists a canonically defined Mumford $\mathbb{Z}$ -divisor $D_E$ on $E$ . As the irreducible components of $E$ are $(R_1)$ , by taking the preimage of $D$ in $E^{\nu }$ we obtain a globally defined Mumford $\mathbb{Z}$ -divisor $D_{E^\nu }$ on the $(S_2)$ surface $E^\nu$ .

Consider the natural exact sequence

\begin{equation*}0 \to \omega _X(D) \to \omega _X(E+D) \to \mathcal {Q} \to 0,\end{equation*}

where $\mathcal{Q}$ is a sheaf supported on $E$ . Note that $\mathcal{Q}$ is a torsion-free $\mathcal{O}_E$ -module of rank 1 by [Reference KollárKol13, Corollary 2.61], and therefore, the $(S_2)$ -hull $\mathcal{Q} \to \mathcal{Q}^{(**)}$ is an injection. So we obtain the exact sequence

\begin{equation*}0 \to \omega _X(D) \to \omega _X(E+D) \to \mathcal {Q}^{**}.\end{equation*}

We now claim that $\mathcal{Q}^{(**)}$ is isomorphic to $\nu _*(\omega _{E^{\nu }}(D_{E^{\nu }}))$ . By construction of the residue map, there is a natural homomorphism $\psi \colon \mathcal{Q} \to \nu _*(\omega _{E^{\nu }}(D_{E^{\nu }}))$ . As $\nu _*(\omega _{E^{\nu }}(D_{E^{\nu }}))$ is $S_2$ , then there is a natural map $\mathcal{Q}^{(**)} \to \nu _*(\omega _{E^{\nu }}(D_{E^{\nu }}))$ . As both $\mathcal{O}_X$ -modules are $(S_2)$ , it is sufficient to show equality at codimension 1 points of $E$ , which has been proved in Lemma 2.32. The linear equivalence $D_{E^{\nu }} \sim _{{\mathbb{Q}}} D|_{E^{\nu }} + \Gamma _E$ and $0 \leq \Gamma _{E^{\nu }} \leq{\mathrm{Diff}}_{E^{\nu }}(\Delta ^{\prime})$ is a codimension 2 statement and it is a consequence of Lemma 2.32.

For the last claim, if $\omega _X(D)$ is $(S_3)$ , then $\mathcal{Q}$ is $(S_2)$ by [Reference KollárKol13, Lemma 2.60], thus concluding that $r$ is surjective.

2.6 Partial resolutions of demi-normal excellent surfaces

In this subsection, we fix an excellent base ring $T$ such that $\frac{1}{2} \in \mathcal{O}_T.$ We start by defining the notion of a pinch point for excellent local rings.

Definition 2.34. Let $(R, \mathfrak{m})$ be a 2-dimensional excellent local ring. We say it is a pinch point if there exists a finite étale morphism $R \to S$ such that $S \simeq R^{\prime}/(x^2-zy^2)$ , where $R^{\prime}$ is a 3-dimensional regular local ring and $(x,y,z)$ is a regular system of parameters for $R^{\prime}$ .

We recall the definition of semi-regular surfaces.

Definition 2.35 (cf. [Reference Kollár and Shepherd-BarronKSB88], Definition 4.2). A surface $S$ is called semi-regular if for every closed point $s \in S$ , the local ring $\mathcal{O}_{S,s}$ is regular, a node (cf. Definition 2.6) or a pinch point.

Motivated by [Reference KollárKol13, Theorem 10.56], we introduce the notion of semi-regularity for surface pairs.

Definition 2.36. Let $(S, H)$ be a pair, where $S={\mathrm{Spec}}(R)$ and where $R$ is an excellent local ring of dimension 2 and $H$ is a Weil $\mathbb{Z}$ -divisor. We say that $(S,H)$ is a semi-regular pair if $S$ is semi-regular and if one of the following holds:

  1. (i) the pair $(S, H)$ is snc;

  2. (ii) $S$ is nodal, and there exists an étale morphism ${\mathrm{Spec}} R/(x^2-uy^2) \to S$ , where $R$ is 3-dimensional regular ring with $u \in R^*$ , local parameters $x,y,z$ and $H=(z=0)$ ;

  3. (iii) $S$ is a pinch point, and there exists an étale morphism ${\mathrm{Spec}} R/(x^2-zy^2) \to S$ , where $R$ is a 3-dimensional regular ring with local parameters $x,y,z$ and $H=(x=z=0)$ .

Remark 2.37. As in the characteristic 0 case, the conductor $D \subset S$ of a semi-regular surface is a regular curve. In case iii, if $f \colon T \to S$ is the blow-up of $S$ along $D$ , then the local computations in [Reference KollárKol13, Definition 1.43] show that the pair $(T, D_T + f^*H)$ is snc.

Definition 2.38 (cf. [Reference Kollár and Shepherd-BarronKSB88], Definitions 4.3, 4.4). Let $(S, H)$ be a demi-normal surface pair. We say that $\pi \colon T \to (S,H)$ is a semi-regular resolution if

  1. (i) $\pi$ is a proper morphism;

  2. (ii) $\pi$ is an isomorphism over the nc locus of $(S,H)$ ;

  3. (iii) $(T,\pi ^*H)$ is a semi-regular pair;

  4. (iv) no component of the non-normal locus $D_T$ of $T$ is $\pi$ -exceptional.

We say $\pi$ is good if additionally

  1. (e) ${\mathrm{Ex}}(\pi ) \cup \pi ^*H \cup D_T$ has regular components and transverse intersections.

If $(S,H)$ is a pair, we say that a semi-regular resolution $\pi$ is thrifty if $a(E, S, F)\gt -1$ for all $\pi$ -exceptional divisors $E$ .

Note that the assumption $(S,H)$ is demi-normal implies that $\pi$ is an isomorphism over a big open set of $S$ .

To show the existence of semi-regular resolutions of excellent surfaces, we follow the strategy of [Reference PosvaPos21a, Section 3.6]. We start with a description of involutions for complete DVR in characteristic $\neq 2$ .

Lemma 2.39. Let $(R, \mathfrak{m})$ be a complete DVR with residue field $k:=R/\mathfrak{m}$ of characteristic $p \neq 2$ . Let $\tau$ be a non-trivial involution of $R$ such that $\tau (\mathfrak{m})=\mathfrak{m}$ . Then there exists a uniformizer $\pi \in \mathfrak{m} \setminus \mathfrak{m}^2$ such that $\tau (\pi )=-\pi$ .

Proof. The proof is similar to [Reference PosvaPos21a, Lemma 3.6.5]. We fix $t \in \mathfrak{m}$ to be a uniformiser.

$\fbox{$Suppose\ t -\tau (t) \notin \mathfrak{m}^2.$}$ In this case, we set $\pi :=t - \tau (t)$ . Note that $\tau (\pi )=\tau (t)-\tau ^2(t)=i$ $\tau (t)-t=-\pi$ , and we conclude.

$\fbox{$Suppose\ t -\tau (t) \in \mathfrak{m}^2.$}$ Then there exists $f \in \mathfrak{m}$ such that $\tau (t)=(1+f)t$ . Moreover, it is easy to see that $\tau (t^k)-t^k \in \mathfrak{m}^{k+1}$ . We distinguish two cases.

$\fbox{$1.\ \tau\ acts\ non-trivially\ on\ k.$}$ Let $\alpha \in k \setminus k^{\tau }$ . Let $\widetilde{\alpha }$ be a lifting of $\alpha$ to $R$ . Note that $\widetilde{\alpha }-\tau (\widetilde{\alpha })(1+f)$ is invertible. Indeed, as $R$ is local, it is sufficient to note that $\widetilde{\alpha }-\tau (\widetilde{\alpha })(1+f) \equiv \alpha -\tau (\alpha ) \neq 0 \mod \mathfrak{m}$ by choice of $\alpha$ . Consider $s:= \widetilde{\alpha } t$ . Note that

\begin{equation*}s-\tau (s) \equiv \big (\widetilde {\alpha } - \tau (\widetilde {\alpha })\big ) t \neq 0 \mod \mathfrak {m}^2, \end{equation*}

as $\alpha -\tau (\alpha ) \neq 0$ . Thus $s-\tau (s) \notin \mathfrak{m}^2$ , and thus, we can conclude by the previous step.

$\fbox{$2.\ \tau\ acts\ trivially\ on\ k.$}$ We verify this contradicts the non-triviality of $\tau$ . We construct a recursive sequence $t_k$ such that $t_k -\tau (t_k) \in \mathfrak{m}^{k+1}$ . Fix $t_0=0$ and $t_1:=t$ . Suppose $t_k$ is defined. We have $t_k -\tau (t_k)= a t^{k+1} \mod \mathfrak{m}^{k+2}$ for some $a \in R$ . As $2$ is invertible in $R$ , we can define

\begin{equation*}t_{k+1}:=t_k - \frac {a}{2} t^{k+1}.\end{equation*}

Note that $\tau (\frac{a}{2}) \cong \frac{a}{2} \mod \mathfrak{m}$ by hypothesis. Therefore,

\begin{equation*} \tau (t_{k+1})-t_{k+1} \equiv -a t^{k+1}+\frac {a}{2} t^{k+1} - \tau \left (\frac {a}{2} \right ) t^{k+1} \mod \mathfrak {m}^{k+2} \equiv 0, \end{equation*}

as $\tau (a/2) \equiv a/2 \mod \mathfrak{m}$ . Now the sequence $(t_k)$ is a Cauchy sequence and thus converges to $s \in \mathfrak{m}$ . Note that by construction, $\tau (s)=s$ , reaching a contradiction (as $\tau$ is non-trivial).

Lemma 2.40. Let $(S, H)$ be a quasi-projective snc surface pair over $T$ , and let $D$ be a regular divisor intersecting transversally $H$ . Let $\tau \colon D \rightarrow D$ be a non-trivial involution. Then $(S/R(\tau ), H/R(\tau ))$ is a semi-regular pair.

Proof. The relation $R(\tau )$ is finite; thus the quotient $p \colon S \to U:=S/R(\tau )$ exists, and it is demi-normal by [Reference PosvaPos21a, Lemma 2.3.13]. Moreover, by [Reference KollárKol13, 9.13], the diagram

is a push-out square. We may assume that $U={\mathrm{Spec}}(R)$ is the spectrum of a local ring with maximal ideal $\mathfrak{m}_R$ . Therefore, $S$ is an affine regular scheme ${\mathrm{Spec}}(A)$ , and there exists a Cartier divisor $f \in A$ (resp. $h \in A$ ) such that $D=(f=0)$ (resp. $H=(h=0)$ ).

If $D \to D/R(\tau )$ is a $(\mathbb{Z}/2\mathbb{Z})$ -quotient we have two cases:

  1. (i) $A$ has exactly two maximal ideals. In this case, up to an étale base change, we may assume $A=A_1 \oplus A_2$ , where $A_1$ and $A_2$ are local rings. Let $f_i \in A_i$ (resp. $h_i \in A_i$ ) be the local equations of $D|_{{\mathrm{Spec}}(A_i)}$ (resp. $H|_{{\mathrm{Spec}}(A_i)}$ ) for $i=1,2$ . Note that the transversality hypothesis on $H$ and $D$ implies that $(f_i, h_i)= \mathfrak{m}_{A_i}$ . Then the push-out property implies that $\mathfrak{m}_U=R \cap (\mathfrak{m}_{A_1} \oplus \mathfrak{m}_{A_2})$ . Let $\tau \colon A_1/f_1 \to A_2/f_2$ be the involution; therefore, $x:=(f_1,0), y=(0,f_2)$ and $z:=(h_1,h_2)$ generate $\mathfrak{m}_U$ . If $\tau$ is trivial, then we have the relations $x=y$ and $H/R(\tau )=(z=0)$ , and we are in case i of Definition 2.38. If $\tau$ is not-trivial, then we have the relation $xy=0$ , and therefore, ${\mathrm{Spec}}(R)$ is nodal and $H/R(\tau )=(z=0)$ , thus ending in case ii of Definition 2.38.

  2. (ii) $A$ is a local ring such that $\tau (\mathfrak{m}_A)=\mathfrak{m}_A$ , and let $\tau \colon A/(f) \to A/(f)$ be an involution. The involution $\tau$ extends to the completion of $A$ and the completion of $R$ is the preimage of the $\tau$ -invariant elements of $A/(f)$ . As $\tau$ fixes $\mathfrak{m}_A$ , the residue field of $R$ is isomorphic to $k^{\tau }$ . The completion $\hat{A}/(f)$ is a complete DVR, and thus there exists a uniformiser $\pi \in \hat{A}/(f)$ such that $\tau (\pi )=-\pi$ by Lemma 2.39. Let $\widetilde{\pi }$ be a lifting of $\pi$ to $\hat{A}$ such that $H=(\widetilde{\pi }=0)$ (note that $h/\widetilde{\pi }$ is invertible). We distinguish two cases:

    1. (a) Suppose $k=k^{\tau }$ . Then $R \subset A$ is the subalgebra generated by $f, \widetilde{\pi }$ and $\widetilde{\pi }f$ . Moreover, $H/R(\tau )$ is given by the equations $ (\widetilde{\pi }=\widetilde{\pi }f=0),$ and thus we are in case iii of Definition 2.38.

    2. (b) Suppose $k^{\tau } \subsetneq k$ . Then there exists $\alpha \in k$ such that $k=k^{\tau }(\alpha )$ and $\tau (\alpha )=-\alpha .$ Let $A^{\prime}$ to be the preimage of $k^{\tau }$ under the projection $A \to k$ . In this case, consider the subalgebra of $A^{\prime}$ generated by $x:=\alpha \widetilde{\pi }, y:=f, z:= \alpha f$ . Therefore, we have the relation $ \alpha ^2y^2=z^2$ , showing that $R$ is a nodal singularities and that $H/R(\tau )$ is described by $(x=0)$ , showing we end up in case ii of Definition 2.38.

We now show the existence of semi-resolution (in characteristic 0, this is [Reference KollárKol13, Theorem 10.54]).

Corollary 2.41. Let $(S, H)$ be a quasi-projective demi-normal surface pair over $T$ . Then there exists a good semi-regular resolution $\pi \colon V \to (S,H)$ . If, moreover, $(S, H)$ is semi-dlt, then we can choose $\pi$ to be thrifty.

Proof. Let $\nu \colon (S^\nu, D_{S^\nu }) \to S$ be the normalisation morphism where $D_{S^\nu }$ is the conductor subscheme of $S^\nu$ . Let $f\colon X \to (S^\nu, D_{S^\nu }+\nu ^*H)$ be a log resolution of $(S^\nu, D_{S^\nu }+\nu ^*H)$ and let $D_X:=f_*^{-1}D_{S^\nu }$ . The involution $\tau$ lifts to an involution of $D_X$ , and we can apply Lemma 2.40 to construct a projective birational contraction $q \colon Y \to S$ fitting in the commutative diagram

such that $q \colon Y \to (S,H)$ is a semi-regular resolution of $(S,H)$ .

If $(S,H)$ is semi-dlt, then $(S^\nu, D_{S^n}+\nu ^*H)$ is a dlt pair. In this case, we can take $f \colon X \to (S^\nu, D_{S^n}+\nu ^*H)$ to be a thrifty log resolution of $(S^n, D_{S^n})$ , and end-product $T \to (S,H)$ is clearly a thrifty semi-regular resolution.

We show how we can slightly improve the resolution algorithm (see [Reference KollárKol13, Corollary 10.55] for an analogue in characteristic 0).

Definition 2.42. Let $(S, H)$ be a demi-normal surface pair, and let $S^0 \subset S$ be the largest open set such that $(S^0, H|_{S^0})$ is semi-snc. We say that $\pi \colon T \to (S,F)$ is a semi-log resolution if

  1. (i) $\pi$ is projective and birational;

  2. (ii) $(T, D_T:=\pi _*^{-1}{\mathrm{Supp}}(F)+{\mathrm{Ex}}(\pi ))$ is a semi-snc pair;

  3. (iii) $\pi$ is an isomorphism over the generic point of every lc centre of $(S,H)$ ;

  4. (iv) $\pi$ is an isomorphism at the generic point of every lc centre of $(T, D_T)$ .

Theorem 2.43. Let $(S, H)$ be a quasi-projective demi-normal surface pair over $T$ . Then there exists a semi-log resolution $\pi \colon V \to (S,H)$ . If $(S, H)$ is semi-dlt, we can choose $\pi$ to be thrifty.

Proof. Consider $q \colon Y \to (S,H)$ be the semi-regular resolution constructed in Proposition 2.41. The only problem is around the pinch points of $Y$ , which are isolated by dimension reasons. Therefore, we can localise to a neighbourhood of $y \in Y$ , where $y$ is a pinch point, and we let $D_y$ be the local component of the non-normal locus $D_T$ . By blowing-up $D_y$ we obtain our desired semi-log resolution as explained in Remark 2.37.

2.7 Vanishing theorems for slc surfaces

In this section we generalise the vanishing theorems of Kawamata–Viehweg type for klt surfaces due to Tanaka [Reference TanakaTan18, Theorem 3.3] to the slc case using the method developed by Kollár in [Reference KollárKol13, Section 10.3]. For an overview on vanishing theorems for slc pairs in characteristic 0, we refer to [Reference FujinoFuj15]. The most general result we prove is Theorem 2.51, which is the fundamental vanishing theorem we will use in Section 3. We start with the case of semi-snc surface pairs.

Proposition 2.43. Let $(S, \Delta )$ be a semi-snc surface pair with $\Delta$ a reduced $\mathbb{Z}$ -divisor, and let $f \colon S \to T$ be a surjective projective morphism onto a normal scheme of dimension $\dim (T) \geq 1$ . Let $M$ be a Cartier divisor on $S$ . Suppose that

  1. (i) $M \sim _{{\mathbb{Q}}, f} K_S+\Delta ^{\prime} + L$ , where

    1. (a) $L$ is a $f$ -nef $\mathbb{Q}$ -divisor, and

    2. (b) $0 \leq \Delta ^{\prime} \leq \Delta$ is a $\mathbb{Q}$ -divisor.

  2. (ii) if $Z$ is a log canonical centre of $\left (S, \Delta \right )$ , including the irreducible components of $Z$ as well, then

    1. (a) $\dim \big ( f(Z) \big ) \geq 1$ ;

    2. (b) if $F_Z$ is the generic fibre of $Z \to f(Z)$ , then $\dim F_Z =\nu (L|_{F_Z})$ .

Then $R^1f_*{\mathcal{O}}_S(M)=0$ .

Proof. Using the relative Kawamata–Viehweg vanishing theorem for surfaces [Reference TanakaTan18, Theorem 3.3], we can repeat the same steps of the proof of [Reference KollárKol13, Corollary 10.34].

The following result is useful to reduce various statements to the case of semi-snc pairs.

Lemma 2.45. Let $(S, \Delta )$ be a semi-dlt surface pair such that $\frac{1}{2} \in \mathcal{O}_S$ . Let $D$ be a $\mathbb{Q}$ -Cartier $\mathbb{Z}$ -divisor such that $D \sim _{{\mathbb{Q}}} K_S+\Delta +M$ for some $\mathbb{Q}$ -Cartier divisor $M$ . Then there is a proper birational morphism $g \colon Y \to S$ , a Cartier divisor $D_Y$ and a $\mathbb{Q}$ -divisor $\Delta _{D, Y}$ such that

  1. (i) $(Y, \Delta _{D, Y})$ is semi-snc;

  2. (ii) $D_Y \sim _{\mathbb{Q}} K_Y+\Delta _{D,Y}+g^*M$ ;

  3. (iii) if $Z$ is a log canonical centre of $(Y, \Delta _{D, Y})$ , then the restriction $g|_Z$ is birational;

  4. (iv) $g_*{\mathcal{O}}_Y(D_Y)={\mathcal{O}}_S(D)$ ;

  5. (v) $R^ig_*{\mathcal{O}}_Y(D_Y)=0$ for $i\gt 0$ .

Proof. The same proof of [Reference KollárKol13, Proposition 10.36] applies as thrifty semi-log resolutions by Theorem 2.43 exist for excellent surfaces and the necessary vanishing theorems hold by Proposition 2.44.

We generalise Proposition 2.44 to the case of semi-dlt surface pairs.

Proposition 2.46. Let $(S, \Delta )$ be a semi-dlt surface pair such that $\frac{1}{2} \in \mathcal{O}_S$ , and let $f \colon S \to T$ be a projective morphism onto a normal scheme of $\dim (T) \geq 1$ . Let $D$ be a $\mathbb{Q}$ -Cartier $\mathbb{Z}$ -divisor on $S$ . Suppose that

  1. (i) $D \sim _{{\mathbb{Q}}, f} K_S+\Delta + L$ , where $L$ is a $f$ -nef $\mathbb{Q}$ -divisor;

  2. (ii) if $Z$ is a log canonical centre of $(S, \Delta )$ , including the irreducible components of $Z$ as well, then

    1. (a) $\dim (f(Z)) \geq 1$ ;

    2. (b) if $F_Z$ is the generic fibre of $Z \to f(Z)$ , then $\dim F_Z =\nu (L|_{F_Z})$ .

Then $R^1f_*{\mathcal{O}}_S(D)=0$ .

Proof. Let $g \colon Y \to S$ be a proper birational morphism such that the pair $(Y, \Delta _{D,Y})$ and the Cartier divisor $D_Y$ on $Y$ satisfy the conditions of Lemma 2.45, and denote by $h \colon Y \to T$ the natural composition. By Proposition 2.44, we conclude that $R^1h_*\mathcal{O}_Y(D_Y)=0$ . As $g_*{\mathcal{O}}_Y(D_Y)={\mathcal{O}}_S(D)$ and $R^ig_*{\mathcal{O}}_Y(D_Y)=0$ for $i\gt 0$ by Proposition 2.44 we deduce $R^1f_*{\mathcal{O}}_S(D)=0$ by the Leray spectral sequence.

In order to generalise to the slc case, the following is a useful observation:

Lemma 2.47. Let $(S, \Delta )$ be an slc surface pair such that $\frac{1}{2} \in \mathcal{O}_S$ , and let $f \colon S \to T$ be a projective morphism onto a normal scheme of $\dim (T) \geq 1$ . Suppose that

  1. (i) every irreducible component of $S$ is $(R_1)$ ;

  2. (ii) if $Z$ is a log canonical centre of $(S, \Delta )$ , then $\dim (f(Z)) \geq 1$ .

Then $(S, \Delta )$ is semi-dlt.

Proof. We argue by contradiction. Let $E$ be an exceptional divisor such that $a(E, S, \Delta )=-1$ and ${\mathrm{cent}}_S(E) \subset{\mathrm{nsnc}}(S, \Delta )$ . The hypothesis (a) guarantees that $(S,\Delta )$ is snc at codimension 1 points. Therefore ${\mathrm{cent}}_S(E)$ is a closed point, contradicting (b).

Corollary 2.48. Let $(S, \Delta )$ be an slc surface pair such that $\frac{1}{2} \in \mathcal{O}_S$ , and let $f \colon S \to T$ be a projective morphism onto a normal scheme of $\dim (T) \geq 1$ . Let $D$ be a $\mathbb{Q}$ -Cartier $\mathbb{Z}$ -divisor on $S$ . Suppose that

  1. (i) $D \sim _{{\mathbb{Q}}, f} K_S+\Delta + L$ , where $L$ is $f$ -nef;

  2. (ii) if $Z$ is a log canonical centre of $(S, \Delta )$ , including the irreducible components of $Z$ as well, then

    1. (a) $\dim (f(Z)) \geq 1$ ;

    2. (b) if $F_Z$ is the generic fibre of $Z \to f(Z)$ , then $\dim F_Z =\nu (L|_{F_Z})$ .

Then $R^1f_*\mathcal{O}_S(D)=0$ .

Proof. Let $p \colon \widetilde{S} \to S$ be the double cover of Proposition 2.11. As $2$ is invertible, $\mathcal{O}_S(D)$ is a direct summand of $p_*\mathcal{O}_{\widetilde{S}}(p^*D)$ . We can thus assume that the irreducible components of $S$ are regular in codimension 1. In this case, $(S, \Delta )$ is semi-dlt by Lemma 2.47 and we conclude by Proposition 2.46.

We can prove a further generalisation of Kawamata–Viehweg vanishing for slc surfaces over curves.

Proposition 2.49. Let $(S, \Delta )$ be a semi-snc surface pair with $\Delta$ a reduced divisor, and let $f \colon S \to C$ be a projective surjective contraction onto a normal curve $C$ . Let $D$ be a $\mathbb{Q}$ -Cartier $\mathbb{Z}$ -divisor on $S$ . Suppose that

  1. (i) every log canonical centre $Z$ of $(S, \Delta )$ , including the components of $S$ , dominates $C$ .

  2. (ii) $A$ is an $f$ -nef $\mathbb{Q}$ -Cartier $\mathbb{Q}$ -divisor on $S$ ;

  3. (iii) $D \sim _{f,{\mathbb{Q}}} K_S+\Delta ^{\prime}+A$ , where $0 \leq \Delta ^{\prime} \leq \Delta$ is a $\mathbb{Q}$ -divisor;

  4. (iv) on every connected component $S^{\prime}$ of $S$ there exists an irreducible component $E$ of $S^{\prime}$ such that $A|_{E}$ is $f|_E$ -big.

Then $R^1f_*\mathcal{O}_{S}(D)=0$ .

Proof. We prove the result by induction on the number $n$ of irreducible components of $S$ . If $n=1$ , we conclude by Proposition 2.44.

We prove the induction step. Let $E$ be an irreducible component of $S$ such that $A|_E$ is big over $C$ . Let $T$ be the union of the irreducible components of $S$ except $E$ . Denote $B:=E \cap T$ , and we consider the short exact sequence:

\begin{equation*}0 \to \mathcal {O}_{E}(D|_{E}-B) \to \mathcal {O}_S(D) \to \mathcal {O}_{T}(D|_{T}) \to 0. \end{equation*}

Taking the long exact sequence in cohomology, it is sufficient to show that $R^1g_*\mathcal{O}_{E}(D-B)=R^1g_*\mathcal{O}_{T}(D|_{T})=0$ to conclude that $R^1g_*\mathcal{O}_S(D)=0$ .

Since $K_S|_{E}=K_{E}+B$ , we have $ D|_{E}-B \sim _{g,{\mathbb{Q}}} K_{E} +\Delta ^{\prime}|_{E}+A|_{E}$ ; so by Proposition 2.44, we conclude that $R^1g_*\mathcal{O}_{E}(D-B)=0$ .

Since $K_S|_{T}=K_{T}+B$ , we have that $ D_{T} \sim _{{\mathbb{Q}}, g} K_{T}+\Delta ^{\prime}|_{T}+B+A|_{T},$ and that $B$ is not trivial on some irreducible component of every connected component of $T$ , as $g$ has connected fibres. By hypothesis, $B$ must be a non-empty horizontal divisor; thus it is nef over $C$ , and for every connected component of $T$ , there exists an irreducible component $F$ such that $B|_F$ is $g|_F$ -big. Therefore, we apply the induction hypothesis to deduce $R^1g_*\mathcal{O}_{T}(D|_{T})=0$ .

Proposition 2.50. Let $(S, \Delta )$ be a semi-dlt surface pair such that $\frac{1}{2} \in \mathcal{O}_S$ , and let $g \colon S \to C$ be a projective morphism onto a normal curve $C$ . Let $D$ be a $\mathbb{Q}$ -Cartier $\mathbb{Z}$ -divisor on $S$ . Suppose that:

  1. (i) every log canonical centre $Z$ of $(S, \Delta )$ , including the components of $S$ , dominates $C$ ;

  2. (ii) $A$ is a $\mathbb{Q}$ -Cartier $\mathbb{Q}$ -divisor on $S$ , which is $g$ -nef;

  3. (iii) $D \sim _{g,{\mathbb{Q}}} K_S+\Delta ^{\prime}+A$ , where $0 \leq \Delta ^{\prime} \leq \Delta$ ;

  4. (iv) on every connected component of $S$ , if there exists an irreducible component $E$ such that $A|_{E}$ is $g|_E$ -big.

Then $R^1g_*\mathcal{O}_{S}(D)=0$ .

Proof. As in the proof of Proposition 2.46, it sufficient to combine Lemma 2.45 and Proposition 2.49 with the Leray spectral sequence.

Theorem 2.51. Let $(S, \Delta )$ be a slc surface pair such that $\frac{1}{2} \in \mathcal{O}_S$ , and let $g \colon S \to C$ be a projective morphism onto a normal curve $C$ . Let $D$ be a $\mathbb{Q}$ -Cartier $\mathbb{Z}$ -divisor on $S$ . Suppose that

  1. (i) every log canonical centre $Z$ of $(S, \Delta )$ , including the components of $Z$ , dominates $C$ ;

  2. (ii) $A$ is a $\mathbb{Q}$ -Cartier $\mathbb{Q}$ -divisor on $S$ , which is $g$ -nef;

  3. (iii) $D \sim _{g,{\mathbb{Q}}} K_S+\Delta ^{\prime}+A$ , where $0 \leq \Delta ^{\prime} \leq \Delta$ .;

  4. (iv) on every connected component of $S$ , there exists an irreducible component $E$ such that $A|_{E}$ is $g|_E$ -big;

Then $R^1g_*\mathcal{O}_{S}(D)=0$ .

Proof. We can repeat the same proof of Corollary 2.48 using Proposition 2.50.

2.8 Grauert–Riemenschneider theorem for dlt 3-folds

We recall the Grauert–Riemenschneider (GR) vanishing theorem for excellent dlt 3-folds proven by Kollár and the second author in [Reference Bernasconi and KollárBK23].

Theorem 2.52. [Reference Bernasconi and KollárBK23, Theorem 2]. Let $(X, \Delta )$ be a 3-dimensional dlt pair whose residue fields of closed points are perfect with characteristic $p \neq 2,3, 5$ . Then G–R vanishing holds on $(X, \Delta )$ .

Precisely, let $g \colon Y \to (X, \Delta )$ be a log resolution, and let $D$ be a Weil $\mathbb{Z}$ -divisor on $Y$ such that $D \sim _{g,\mathbb{R}} K_{Y}+\Delta ^{\prime}$ for an effective $\mathbb{R}$ -divisor $\Delta ^{\prime}$ on $Y$ such that $g_*\Delta ^{\prime}\leq \Delta$ and $\lfloor{\mathrm{Ex}}(\Delta ^{\prime}) \rfloor =0$ . Then, $R^ig_*{\mathcal{O}}_{Y}(D)=0$ for $i\gt 0$ .

The main techniques are the vanishing theorem for surfaces of del Pezzo type over perfect fields proven in [Reference Arvidsson, Bernasconi and LaciniABL22] and the MMP for 3-folds [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23]. From the G–R vanishing theorem, one can deduce various rationality and Cohen–Macaulay properties for dlt 3-fold singularities, a result we will frequently use to study depths of log canonical 3-fold singularities in terms of a dlt modifications.

Corollary 2.53 [Reference Bernasconi and KollárBK23, Theorem 17]. Let $(X, \Delta )$ be a 3-dimensional dlt pair whose residue fields of closed points are perfect with characteristic $p \neq 2,3, 5$ . Then

  1. (i) $X$ is Cohen–Macaulay, and has rational singularities;

  2. (ii) every irreducible component of $\lfloor \Delta \rfloor$ is normal;

  3. (iii) if $D$ is a $\mathbb{Z}$ -divisor such that $D+\Delta ^{\prime}$ is $\mathbb{Q}$ -Cartier for some $\mathbb{Q}$ -divisor $0 \leq \Delta ^{\prime}\leq \Delta$ , then $\mathcal{O}_X(D)$ is C–M.

3. Depth of log canonical 3-fold singularities

Setting 3.1. Throughout this section, we suppose $(R, \mathfrak{m})$ is a local ring whose residue field is perfect of characteristic $p \neq 2,3, \text{ and } 5$ . Let $(X={\mathrm{Spec}}(R), x)$ be the associated local scheme, and suppose that there exists a $\mathbb{Q}$ -divisor $\Delta \geq 0$ such that $(X,\Delta )$ is a log canonical 3-dimensional pair.

We are interested in computing the local cohomology group $H^2_x(X,\mathcal{O}_{X})$ when the closed point $x$ is not a minimal log canonical centre of $(X,\Delta )$ . We first show that we can reduce to the case where the minimal log canonical centre is 1-dimensional.

Lemma 3.2. Let $C$ be the minimal log canonical centre of $(X,\Delta )$ passing through $x$ . Suppose one of the following conditions hold:

  1. (i) $x \notin{\mathrm{nklt}}(X,\Delta )$ (that is, $C$ is empty);

  2. (ii) $x \in{\mathrm{nklt}} (X,\Delta )$ and $\dim (C)=2$ .

Then $X$ satisfies Serre’s condition $(S_3)$ .

Proof. Case (a) is proven in Corollary 2.53. In case (b), we deduce $(X, \Delta )$ is plt by 2.26 and we conclude by Corollary 2.53.

By Lemma 3.2, the case of interest, when studying the behavior of local cohomology of ${\mathcal{O}}_X$ , is when $\dim C =1$ . In this case, our main technical result relates the non-vanishing of local cohomology $H^2_x(X, \mathcal{O}_X)$ to the torsion of $R^1g_*\mathcal{O}_E$ , where $E$ is an exceptional divisor over $X$ . More precisely:

Theorem 3.3. Let $C \subset X$ be a 1-dimensional minimal log canonical centre for $(X,\Delta )$ passing through $x$ . Then there exists a projective birational morphism $g \colon Z \to (X, \Delta )$ with reduced exceptional divisor $E$ such that

  1. (i) $Z$ is $\mathbb{Q}$ -factorial klt with $K_Z+g_*^{-1}\Delta +E \sim _{{\mathbb{Q}}} g^*(K_X+\Delta )$ ;

  2. (ii) $E$ is $(S_2)$ ;

  3. (iii) $H^2_x(X,{\mathcal{O}}_X) \simeq H^0_x(C, R^1g_*\mathcal{O}_E)$ .

As the rest of the section is devoted to showing Theorem 3.3, from now on we assume the following:

Setting 3.4. Besides the assumptions and the notation of Setting 3.1, let us also fix a 1-dimensional minimal log canonical centre $C$ of $(X,\Delta )$ passing through $x$ . Moreover, $C$ is irreducible by Lemma 2.26, and we denote by $\eta$ its generic point.

3.1 Construction of minimal étale-dlt modifications

The hypothesis of minimality on $C$ allows us to prove the following technical results, which we will use repeatedly:

Lemma 3.5. Let $\pi \colon (Y, \Delta _Y) \to (X, \Delta )$ be a crepant proper birational morphism of normal log pairs where $(X,\Delta )$ is as in Setting 3.4 . Suppose $Y$ is $\mathbb{Q}$ -factorial, and let $0 \leq \Gamma \leq \Delta _Y$ . If $(Y_{\eta }, \Gamma _{\eta })$ is dlt (resp. étale-dlt), then $(Y, \Gamma )$ is dlt (resp. étale-dlt).

Proof. Suppose that $(Y_\eta, \Gamma _\eta )$ is dlt. If $(Y,\Gamma )$ is not dlt, then there exists an exceptional divisor $E$ with discrepancy $a(E, Y, \Gamma )=-1$ such that ${\mathrm{cent}}_Y(E) \subset Y \setminus{\mathrm{snc}}(Y,\Gamma )$ . Since $(Y_\eta, \Gamma _\eta )$ is dlt, we deduce that ${\mathrm{cent}}_Y(E)$ must be disjoint from $Y_\eta$ . In particular, ${\mathrm{cent}}_X(E)$ is a closed point $c$ in $C$ . As $a(E, Y, \Delta _Y) \leq a(E, Y, \Gamma )=-1$ , this contradicts the minimality of $C$ among the log canonical centres of $(X, \Delta )$ .

The same proof works in the étale-dlt case by replacing $Y \setminus{\mathrm{snc}}(Y,\Gamma )$ with the closed subset $Y \setminus{\mathrm{etsnc}}(Y,\Gamma )$ .

Lemma 3.6. Let $(X,\Delta )$ as in Setting 3.4 . For every exceptional log canonical place $E$ over $X$ , we have ${\mathrm{cent}}_X(E)=C$ .

Proof. If ${\mathrm{cent}}_X(E) \neq C$ , we have ${\mathrm{cent}}_X(E) \cap C= \left \{ x\right \}$ , as $E$ is exceptional. Therefore, $x$ is a log canonical centre by Lemma 2.26, contradicting the minimality of $C$ .

In the next propositions, as in the article in general, ${\mathrm{Ex}}(\pi )$ denotes the divisorial part of the exceptional set of a proper birational morphism $\pi$ , not the entire exceptional set.

Lemma 3.7. Let $\pi \colon (Y, \Delta _Y) \to (X, \Delta )$ be a crepant proper birational morphism of normal log pairs, where $(X,\Delta )$ is as in Setting 3.4 . Suppose that $Y$ is $\mathbb{Q}$ -factorial and that $\Delta _Y \geq E:={\mathrm{Ex}}(\pi )$ . If $E \neq 0$ , then the pair $(Y, \Delta _Y-\varepsilon E)$ is plt for every rational number $\varepsilon \in (0,1]$ .

Proof. Note that as $\pi _\eta \colon Y_\eta \to{\mathrm{Spec}}(\mathcal{O}_{X,\eta })$ is a proper birational morphism of normal surfaces, the support of $E_\eta$ coincides with ${\mathrm{Ex}}(\pi )_\eta$ also set-theoretically.

Write $\Delta _Y-\varepsilon E=\Delta^{\prime}_Y+(1-\varepsilon )E \leq \Delta _Y$ , where $\Delta^{\prime}_Y$ and $E$ are effective $\mathbb{Q}$ -divisors and they have no irreducible components in common. Suppose by contradiction that $\big (Y, \Delta^{\prime}_Y+(1-\varepsilon )E \big )$ is not plt. By definition, there exists a proper birational modification $f \colon Z \to Y$ extracting an exceptional divisor $F$ with discrepancy $a(F, Y, \Delta^{\prime}_Y+(1-\varepsilon )E)=-1$ . By the monotonicity of discrepancies [Reference Kollár and MoriKM98, Lemma 2.27],

\begin{equation*}a(F, Y, \Delta _Y) \leq a(F, Y, \Delta^{\prime}_Y+(1-\varepsilon )E)=-1.\end{equation*}

As $(Y, \Delta _Y)$ is log canonical, we conclude $a(F,Y, \Delta _Y)= -1$ . As $F$ is an exceptional log canonical place over $X$ , then ${\mathrm{cent}}_X(F)=C$ by Lemma 3.6. As ${\mathrm{cent}}_Y(F)$ dominates $C$ , we deduce that ${\mathrm{cent}}_Y(F) \subset E$ (as $E_\eta$ coincides set-theoretically with ${\mathrm{Ex}}(\pi )_\eta$ ). This last containment implies by [Reference KollárKol13, Lemma 2.5] that

\begin{equation*}a(F,Y, \Delta^{\prime}_Y+(1-\varepsilon )E)=a(F, Y,\Delta _Y -\varepsilon E) \gt a(F, Y, \Delta _Y)=-1,\end{equation*}

contradicting the starting assumption $a(F, Y, \Delta _Y-\varepsilon E)=-1$ .

Proposition 3.8. Let $(X,\Delta )$ be as in Section 3.4 . Then there exists a projective birational morphism $g \colon Z \to X$ such that

  1. (i) $\big (Z, g_*^{-1}\Delta +{\mathrm{Ex}}(g)\big )$ is a $\mathbb{Q}$ -factorial log canonical pair such that $K_Z + g_*^{-1}\Delta +{\mathrm{Ex}}(g) = g^*(K_X+\Delta )$ ;

  2. (ii) the pair $(Z, g_*^{-1}\lfloor \Delta \rfloor +{\mathrm{Ex}}(g))$ is étale-dlt;

  3. (iii) for every $\varepsilon \gt 0$ , the pair $\big (Z, g_*^{-1}\Delta +(1-\varepsilon )\;{\mathrm{Ex}}(g) \big )$ is plt;

  4. (iv) $-{\mathrm{Ex}}(g)$ is a $g$ -nef $\mathbb{Q}$ -Cartier divisor;

  5. (v) $g(F)=C$ for every irreducible component $F$ of ${\mathrm{Ex}}(g)$ .

Proof. Let $\varphi \colon W \to X$ be a log resolution of $(X, \Delta )$ such that $\varphi _*^{-1}\Delta$ is regular. In particular, the pair $(W, \varphi _*^{-1}\Delta )$ is plt. Let $\pi \colon Y \to X$ be a log minimal model of this pair over $X$ , which is $\mathbb{Q}$ -factorial by the plt assumption. Write

\begin{equation*} K_Y + \pi ^{-1}_* \Delta + E + B =\pi ^*(K_X+\Delta ), \end{equation*}

where $E$ is an effective $\mathbb{Z}$ -divisor and $\lfloor B \rfloor =0$ . In particular, then $-(E+B)$ is a $\mathbb{Q}$ -Cartier nef divisor over $X$ . We denote by $Y_\eta$ the base change of $Y$ over $X_{\eta }:={\mathrm{Spec}}(\mathcal{O}_{X, \eta })$ , and for a divisor $D$ on $Y$ , we will denote by $D_\eta$ the localisation $D|_{Y_\eta }$ . In particular, $Y_\eta$ is NOT the fibre over $\eta$ .

By Remark 2.15, $Y_\eta$ is a log minimal resolution of the surface $\big ({\mathrm{Spec}} \mathcal{O}_{X, \eta }, \Delta _\eta \big )$ . Let $G$ be the $\mathbb{Z}$ -divisor ${\mathrm{Ex}}(\pi )-E$ , which is supported on the exceptional divisors, which are not log canonical places. Note that ${\mathrm{Supp}}(B) \subseteq{\mathrm{Supp}}(G)$ .

Next, we define a birational model $h : V \to X$ that satisfies the following properties, where the sub-index $V$ denotes the strict transform of the corresponding divisor:

  • $V$ is $\mathbb{Q}$ -factorial;

  • ${\mathrm{Ex}}(h)=E_V$ ;

  • $-E_{V, \eta }$ is nef;

  • $\big (V, E_V + h^{-1}_* \lfloor \Delta \rfloor \big )_{\eta }$ is étale-dlt.

In particular, as ${\mathrm{Ex}}(h)=E_V$ , we conclude $(V, h_*^{-1}\Delta +E_V)$ is crepant birational to $(X,\Delta )$ . We construct $V$ separately in the two cases corresponding to the two points of Proposition 2.20, when Proposition 2.20 is applied to to the minimal resolution $\pi _\eta \colon Y_\eta \to \big ( X_\eta, \Delta _\eta \big )$ .

$\fbox{$Case\ i\ of\ Proposition\ 2.20\textit{:}$}$ in this case we have that $\Delta _\eta =G_{\eta }=0$ and that $E_\eta$ is equal to ${\mathrm{Ex}}(\pi _\eta )$ , it is irreducible, and it is anti-nef. Note that the pair $(Y, \pi ^{-1}_* \Delta + E + B)$ is $\mathbb{Q}$ -factorial log canonical, crepant to $(X, \Delta )$ and by Lemma 3.7 the pair $ \big (Y, \pi ^{-1}_* \Delta + (1- \varepsilon )E + B\big )$ is plt. Additionally, as $G$ is exceptional, it does not have any of the codimension $1$ components of $\pi ^{-1}_* \Delta$ in its support. This implies that we may find another rational number $\varepsilon ^{\prime}\gt 0$ , such that $ \big (Y, \pi ^{-1}_* \Delta + (1- \varepsilon )E + B + \varepsilon ^{\prime} G\big )$ is still plt. Let $V$ be a log minimal model over $X$ of the latter pair. Note that we have

(6) \begin{equation} K_Y+\pi _*^{-1}\Delta + (1- \varepsilon )E+B+\varepsilon ^{\prime} G \equiv _X \varepsilon ^{\prime} G - \varepsilon E. \end{equation}

In particular, this MMP is the identity on $Y_\eta$ , as

\begin{equation*} \big (\varepsilon G - \varepsilon E \big )_{\eta } = -\varepsilon E_\eta, \end{equation*}

is nef. This also yields that $-E_{V, \eta }$ is nef. It even implies $\big (V, E_V + h^{-1}_* \lfloor \Delta \rfloor \big )_{\eta }$ is étale-dlt, as $\big (Y, E + \pi ^{-1}_* \lfloor \Delta \rfloor \big )_{\eta }$ is étale-dlt by point i of Proposition 2.20. Additionally, by the negativity lemma and by Proposition 6, this MMP turns $G$ anti-effective, which means that it contracts it. Hence, ${\mathrm{Ex}}(h)=E_V$ . Finally, $V$ is $\mathbb{Q}$ -factorial as it is a result of a plt MMP.

$\fbox{$Case\ ii\ of\ Proposition\ 2.20\textit{:}$}$ by point ii of Proposition 2.20, we know that $(Y, \pi ^{-1}_* \lfloor{\Delta \rfloor } + E + B)_\eta$ is dlt. Hence, by Lemma 3.5, $(Y, \pi ^{-1}_* \lfloor{\Delta \rfloor } + E + B)$ is also dlt. As the coefficients of $B$ are smaller than $1$ , we may choose a rational number $\varepsilon \gt 0$ such that $\big (Y, \pi _*^{-1}\lfloor{\Delta \rfloor }+ E+B+ \varepsilon G\big )$ is dlt. Let $h : V \to X$ be a log minimal model of this latter pair over $X$ , where $V$ is $\mathbb{Q}$ -factorial as we run a dlt MMP on a $\mathbb{Q}$ -factorial variety. Note that we have

\begin{equation*} K_Y+\pi _*^{-1}\lfloor {\Delta \rfloor }+ E+B+\varepsilon G \equiv _X \varepsilon G - \pi _*^{-1}\left \{ \Delta \right \}. \end{equation*}

Therefore, by the negativity lemma [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Lemma 2.16] this MMP turns $G$ anti-effective, which means that it contracts it, and hence it also contracts $B$ . Hence $E_V={\mathrm{Ex}}(h)$ , and $(V, h^{-1}_* \lfloor \Delta \rfloor + E_V)$ is dlt. The last property we need to show about $V$ is that $-E_{V,\eta }$ is nef. By Lemma 2.20, it is enough to show for this that $-E_\eta - B_\eta$ is nef. However, that is immediate as $-E-B \equiv _X K_Y + \pi ^{-1}_* \Delta$ , which is nef by the construction of $Y$ as a log minimal model.

Having finished the construction and the verification of the properties of $V$ in both cases, by Lemma 3.7 the pair $(V, h^{-1}_* \Delta + (1- \varepsilon ) E_V)$ is plt for every small rational number $\varepsilon \gt 0$ . Let $g\colon Z \to X$ be the log minimal model of this latter pair, which is $\mathbb{Q}$ -factorial. This yields point i and iii. As

\begin{equation*} K_V + h^{-1}_* \Delta + (1- \varepsilon ) E_V \equiv _X - \varepsilon E_V, \end{equation*}

we see that this MMP is the identity in a neighborhood of $V_\eta$ since $-E_{V,\eta }$ is nef, and that $-E_Z=-{\mathrm{Ex}}(g)$ is nef. This yields 4. The MMP being identity over $\eta$ also implies that the exceptional divisor of $Z$ and $V$ are the same, and that $(Z, g^{-1}_* \lfloor \Delta \rfloor + E_Z)_\eta$ is étale-dlt. The former yields point 5 by Lemma 3.6, and the latter together with Lemma 3.5 yields point 2.

3.2 Computing local cohomology

Setting 3.9. For this subsection, let $(X, \Delta )$ be as in Setting 3.4 and let $g \colon Z \to X$ be the birational modification constructed in Proposition 3.8. Set $E:={\mathrm{Ex}}(g)$ and $\Delta _Z:=g_*^{-1} \Delta +E$ .

We note that, by Proposition 3.8 $Z$ is $\mathbb{Q}$ -factorial and klt. Hence, by Corollary 2.53, for every $\mathbb{Z}$ -divisor $D$ on $Z$ , the divisorial sheaf ${\mathcal{O}}_Z(D)$ is Cohen–Macaulay. This also implies that any divisor on $Z$ is $(S_2)$ by [Reference KollárKol13, Corollary 2.61].

The following is the fundamental tool to relate the local cohomology group $H^2_x(X, \mathcal{O}_X)$ to cohomological properties of $g \colon Z \to X$ .

Lemma 3.10. There is an exact sequence as follows:

\begin{equation*}0 \to H^0_x(X, R^1 g_* {\mathcal {O}}_Z) \to H^2_x(X, {\mathcal {O}}_X) \to H^2_{g^{-1}(x)}(Z, {\mathcal {O}}_Z). \end{equation*}

Proof. Note that the composition of derived functors $R \Gamma _x$ and $Rg_*$ satisfies $R \Gamma _x \circ Rg_* = R \Gamma _{g^{-1}x}$ . Then we have the usual five-term short exact sequence:

\begin{equation*} { 0 \to R^1 \Gamma _x R^0 g_* {\mathcal {O}}_Z \to R^1 \Gamma _{g^{-1}(x)} {\mathcal {O}}_Z \to R^0 \Gamma _x R^1 g_* {\mathcal {O}}_Z \to R^2 \Gamma _x R^0 g_* {\mathcal {O}}_Z \to R^2 \Gamma _{g^{-1}(x)} {\mathcal {O}}_Z.} \end{equation*}

To conclude, it is thus sufficient to show that $R^1\Gamma _{g^{-1}(x)}\mathcal{O}_Z$ vanishes. By duality for C–M sheaves (cf. [Reference KollárKol13, Theorem 10.44] and [Reference Kollár and MoriKM98, Theorem 5.71]), it is sufficient to show that $R^2g_*{\mathcal{O}}_Z(K_Z)=0$ . As every irreducible component $F$ of ${\mathrm{Ex}}(g)$ surjects onto $C$ , the fibres of $g$ are at most 1-dimensional and we deduce $R^2g_*{\mathcal{O}}_Z(K_Z)=0$ by dimension reasons.

We now prove a Grauert–Riemenschneider vanishing theorem for the birational contraction $g$ .

Proposition 3.11. Let $D$ be a $\mathbb{Z}$ -divisor on $Z$ such that $D \sim _{\mathbb{Q},X} K_Z+\Delta ^{\prime}$ , where $0 \leq \Delta ^{\prime} \leq g_*^{-1}\Delta$ . Then $R^ig_*\mathcal{O}_Z(D)=0$ for $i\gt 0$ .

Proof. For $i=2$ , it is immediate as the dimension of the fibres of is at most 1 by i of Proposition 3.8. For the case $i=1$ , as $(Z, g_*^{-1}\lfloor{\Delta \rfloor }+E)$ is étale-dlt we can apply Proposition 2.33 to the divisor $\big (D-K_Z-(m+1)E\big )$ for every $m\geq 0$ to obtain the short exact sequence of $\mathcal{O}_Z$ -modules:

\begin{equation*} 0 \to \mathcal {O}_Z(D-(m+1)E) \to \mathcal {O}_Z(D-mE) \to \mathcal {O}_{E} (G_m) \to 0,\end{equation*}

where $G_m$ is a $\mathbb{Q}$ -Cartier $\mathbb{Z}$ -divisor on $E$ . Moreover, there exists a $\mathbb{Q}$ -divisor $\Gamma _m$ such that $0 \leq \Gamma _m \leq{\mathrm{Diff}}_{E}(0)$ and

(7) \begin{equation} \begin{aligned} G_m & \sim _{{\mathbb{Q}}} K_{E} + \big (D- K_Z - (m+1)E\big )|_{E} + \Gamma _m & \\ &\sim _{{\mathbb{Q}}} (D - mE)|_{E} - (K_Z +E)|_{E} + K_{E} + \Gamma _m & \\ & \sim _{{\mathbb{Q}}} (D - mE)|_{E} - \Gamma^{\prime} _m, & \end{aligned} \end{equation}

where $\Gamma^{\prime} _m :={\mathrm{Diff}}_{E}(0)-\Gamma _m \geq 0$ . Passing to cohomology, we obtain the short exact sequence

(8) \begin{equation} R^1g_*\mathcal{O}_Z(D-(m+1)E) \to R^1g_*\mathcal{O}_Z(D-mE) \to R^1g_*\mathcal{O}_{E}(G_m) \to 0. \end{equation}

We now claim that $R^1g_* \mathcal{O}_{E} (G_m)=0$ for all $m \geq 0$ . By applying adjunction, we deduce

(9) \begin{equation} (D - mE)|_{E} \sim _{\mathbb{Q}} (K_Z + \Delta ^{\prime} - mE)|_{E} \sim _{{\mathbb{Q}}} K_{E^\nu } +{\mathrm{Diff}}_{E}(\Delta ^{\prime}) -( m+1)E|_{E}. \end{equation}

Combining (7) and (9) we conclude that

(10) \begin{equation} G_m \sim _{\mathbb{Q}} K_{E} +\Delta _m -(m+1)E|_{E}, \end{equation}

where $\Delta _m:={\mathrm{Diff}}_{E}(\Delta ^{\prime})-\Gamma ^{\prime}_m \leq{\mathrm{Diff}}_{E}(\Delta ^{\prime})$ . Note that $\Delta _m=\big ({\mathrm{Diff}}_{E}(\Delta ^{\prime})-{\mathrm{Diff}}_{E}(0) \big )+\Gamma _m$ and therefore $\Delta _m \geq 0$ . We verify we can apply Theorem 2.51 to $g \colon E \to C$ to show $R^1g_* \mathcal{O}_{E} (G_m)=0$ because

  • every log canonical centre of $(E,{\mathrm{Diff}}_{E}(\Delta ^{\prime}))$ dominates $C$ by v of 3.8;

  • $G_m \sim _{\mathbb{Q}} K_{E}+\Delta _m +A$ , where $0 \leq \Delta _m \leq{\mathrm{Diff}}(\Delta ^{\prime})$ and $A:=(-(m+1)E)|_{E}$ is $g$ -nef by assumption;

  • there is an irreducible component $F$ of $E$ such that $A|_F$ is $g$ -big. If this is not the case then, as the fibres of $g|_E$ are 1-dimensional, $-E_\eta$ is $g_\eta$ -trivial and thus $E_\eta =0$ by the negativity lemma.

Combining the vanishing $R^1g_* \mathcal{O}_{E} (G_m)=0$ with the sequence (8), it is sufficient to show $R^1g_*\mathcal{O}_Z(D-nE)=0$ for $n$ sufficiently large to conclude that $R^1g_*\mathcal{O}_Z(D)=0$ by descending induction. As the pair $(Z, g_*^{-1}\Delta +(1-\varepsilon )E)$ is plt and

\begin{equation*}K_Z +g_*^{-1}\Delta +(1-\varepsilon )E \equiv _X -\varepsilon E,\end{equation*}

is $g$ -nef, we can consider the birational contraction $p \colon Z \to T$ to its canonical model $h \colon T \to X$ . By construction, the pair $(T, h_*^{-1}\Delta +(1-\varepsilon )E_T)$ is plt and $-E \sim _{{\mathbb{Q}}} p^*(-E_T)$ where $-E_T$ is ample over $X$ . In particular, as

\begin{equation*} D-nE \sim _{{\mathbb {Q}}} K_Z +\Delta ^{\prime} -nE \sim _{{\mathbb {Q}}, T} K_Z+\Delta ^{\prime},\end{equation*}

by Theorem 2.52 we deduce $R^ip_*\mathcal{O}_Z(D-nE)=0$ for $i\gt 0$ . For $n$ sufficiently large and divisible, $nE \sim p^*nE_T$ and thus by the Leray spectral sequence and the projection formula we have

\begin{equation*}R^1g_*\mathcal {O}_Z(D-nE) \simeq R^1h_*\big (p_*\mathcal {O}_Z(D-nE)\big ) \simeq R^1h_*\big (p_*\mathcal {O}_Z(D) \otimes \mathcal {O}_T(-nE_T)\big ),\end{equation*}

which is zero for $n$ sufficiently large by Serre vanishing.

As an application of the G–R vanishing, we can finally compute the second local cohomology group at $x$ .

Proposition 3.12. The following equalities hold:

  1. (i) $H^2_{g^{-1}(x)}(Z,{\mathcal{O}}_Z)=0$ ;

  2. (ii) $H^0_x(X, R^1g_*{\mathcal{O}}_Z) \simeq H^0_x(C, R^1g_*{\mathcal{O}}_E)$ .

Proof. To prove i, we note that $H^2_{g^{-1}(x)}(Z,{\mathcal{O}}_Z)=R^1 g_* \mathcal{O}_Z(K_Z)_x$ by local duality for Cohen–Macaulay sheaves and $R^1 g_*{\mathcal{O}}_Z(K_Z)_x$ vanishes by Proposition 3.11.

To prove ii, as $-E \sim _{\mathbb{Q},X} K_Z+g_*^{-1}\Delta$ we can apply Proposition 3.11 to deduce $R^ig_*\mathcal{O}_Z(-E)=0$ for $i\gt 0$ . Then the long exact sequence of cohomology associated to $0 \to \mathcal{O}_Z(-E) \to \mathcal{O}_Z \to \mathcal{O}_E \to 0$ implies that $R^1g_*{\mathcal{O}}_Z\cong R^1g_*{\mathcal{O}}_E$ . If $i \colon C \to X$ denotes the closed immersion, the equality $\Gamma _{C, x}=\Gamma _{X,x} \circ i_*$ holds, which implies $H^0_x(X, R^1 g_*{\mathcal{O}}_E)\simeq H^0_x(C, R^1g_*{\mathcal{O}}_E)$ .

Proof of Theorem 3.3 This is a consequence of Proposition 3.8 and Proposition 3.12.

4. ( ${\boldsymbol{S}}_{\textbf{2}}$ )-condition for locally stable families of surfaces

In this section, we prove the $(S_2)$ -conjecture for locally stable families of surfaces in characteristic $p \neq 2, 3$ and $5$ . An alternative proof of this theorem also appears in [Reference ArvidssonArv23, Corollary 23]. In Subsection 4.2, we use this result to show the properness of $\overline{\mathcal{M}}_{2,v}$ over $\mathbb{Z}[1/30]$ , contingent upon the existence of semi-stable reduction for family of stable surfaces in positive and mixed characteristic.

4.1 Wild fibres

Setting 4.1. In this section, $(R, \mathfrak{m})$ is a DVR of perfect residue field $k=R/\mathfrak{m}$ . We denote by $C$ the spectrum of $R$ and $x$ is its closed point. Given a morphism $f \colon S \to C$ , we denote by $S_x$ the fibre over $x$ .

The terminology of wild fibres was introduced by Bombieri and Mumford in [Reference Bombieri and MumfordBM77] to study elliptic surface fibrations. We present a more general definition for fibrations of surfaces over curves and we collect some foundational results proven by Raynaud in [Reference RaynaudRay70].

Definition 4.2. Let $S$ be a reduced connected surface and let $f \colon S \to C$ be a proper flat morphism such that $f_*\mathcal{O}_S=\mathcal{O}_C$ . Consider the decomposition

\begin{equation*}R^1f_*{\mathcal {O}}_S=\mathcal {M} \oplus \mathcal {T},\end{equation*}

where $\mathcal{M}$ is a locally free sheaf of rank $\dim _{k(C)} H^1(S_{k(C)}, \mathcal{O}_{S_{k(C)}})$ and $\mathcal{T}$ is torsion sheaf supported at $x$ . If $\mathcal{T}_x \neq 0$ , we say that the schematic fibre $f^{-1}(x)$ is a wild fibre of $f$ .

Given a proper flat morphism $f \colon X \to Y$ , we say it is cohomologically flat in degree 0 if for any morphism $ g \colon Y^{\prime} \to Y$ inducing the base change $f^{\prime} \colon X^{\prime}:=X \times _Y Y^{\prime} \to Y^{\prime}$ , then the canonical homomorphism of $\mathcal{O}_{Y^{\prime}}$ -modules $ g^*f_*\mathcal{O}_X \to f^{\prime}_* \mathcal{O}_{X^{\prime}}$ is an isomorphism (see [Reference Fantechi, Göttsche, Illusie, Kleiman, Nitsure and VistoliFGI+05, 8.3.10]).

Lemma 4.3. Let $S$ be a reduced connected surface and let $f \colon S \to C$ be a proper flat morphism such that $f_*\mathcal{O}_S = \mathcal{O}_C$ . If $x$ is a closed point of $C$ , then

\begin{equation*} \mathcal {T}_x \neq 0 \Leftrightarrow \dim _{k(x)} H^0(f^{-1}(x), \mathcal {O}_{f^{-1}(x)}) \geq 2. \end{equation*}

In particular, a wild fibre is not reduced. Moreover, $\mathcal{T} \neq 0$ if and only if $f$ is not cohomologically flat in degree 0.

Proof. For each $i \geq 0$ , consider the natural homomorphism of $k(x)$ -vector spaces obtained from the base change ${\mathrm{Spec}}\big (k(x)\big ) \to C$ :

\begin{equation*}\alpha ^i(x) \colon R^if_*\mathcal {O}_S \otimes k(x) \to H^i(f^{-1}(x), \mathcal {O}_{f^{-1}(x)}).\end{equation*}

As the fibres of $f$ have dimension 1, clearly $\alpha ^2(x)$ is surjective and $R^2f_*\mathcal{O}_S=0$ . Thus we deduce that $\alpha ^1(x)$ is surjective by cohomology and base change for proper morphism [Reference Fantechi, Göttsche, Illusie, Kleiman, Nitsure and VistoliFGI+05, Corollary 8.3.11.b]. Applying once more [Reference Fantechi, Göttsche, Illusie, Kleiman, Nitsure and VistoliFGI+05, Corollary 8.3.11.b], we deduce that $\alpha ^0(x)$ is an isomorphism if and only if $\mathcal{T}=0$ . To conclude, by hypothesis $f_*\mathcal{O}_S \otimes _{\mathcal{O}_C} k(x) \simeq k(x)$ and therefore $\alpha ^0(x)$ is an isomorphism if and only if $\dim _{k(x)} H^0(f^{-1}(x), \mathcal{O}_{f^{-1}(x)}) = 1$ .

Note that if $f^{-1}(x)$ is wild, then $\dim _{k(x)} H^0(f^{-1}(x), \mathcal{O}_{f^{-1}(x)}) \geq 2$ . As $f^{-1}(x)$ is geometrically connected, we conclude $f^{-1}(x)$ is not reduced. The final assertion is shown in [Reference Fantechi, Göttsche, Illusie, Kleiman, Nitsure and VistoliFGI+05, Corollary 8.3.11.a].

A more precise characterisation of wild fibres for $(S_2)$ -surfaces was proven by Raynaud [Reference RaynaudRay70] while investiganting representability criteria for Picard schemes of proper schemes over a DVR.

Proposition 4.4. Let $f \colon S \to C$ be a proper flat morphism such that $f_*\mathcal{O}_S = \mathcal{O}_C$ . Suppose that

  1. (i) $S$ is an $(S_2)$ -surface such that its non-normal locus dominates $C$ ;

  2. (ii) the greatest common denominator of the multiplicities of the geometric special fibre $S_{\overline{k}}:=S_k \times _k \overline{k}$ is equal to 1.

Then $f$ is cohomologically flat in degree 0 and $\mathcal{T}=0$ .

Proof. To verify the statement we can pass to a strict henselianisation $A^{\text{sh}}$ of $A$ . The hypothesis guarantee that $S$ satisfies assumption (N) $^{*}$ of [Reference RaynaudRay70, Definition 6.1.4]. Indeed, $S_x$ is $S_1$ as it is a Cartier divisor on the $(S_2)$ -surface $S$ . Moreover, at every generic point $\eta$ of an irreducible component of $S_x$ we have that $\mathcal{O}_{S,\eta }$ is regular. Then the statement is proven in the implication $(i) \Rightarrow (iv)$ of [Reference RaynaudRay70, Theorem 8.2.1].

We recall that no wild fibres appear when the generic fibre of $f \colon S \to C$ is a tree of conic curves.

Proposition 4.5. Let $f \colon S \to C$ be a proper morphism onto a regular curve such that $f_*\mathcal{O}_S =\mathcal{O}_C$ . Suppose that $S$ is an $(S_2)$ -surface such that each of its irreducible components $S_i$ dominates $C$ and the non-normal locus of each $S_i$ dominates $C$ . If $H^1(S_{k(C)}, \mathcal{O}_{S_k(C)})=0$ , then $\mathcal{T}=0$ .

Proof. As every irreducible component of $S$ dominates $C$ , the morphism $f$ is equi-dimensional. As $S$ has dimension 2, it is Cohen–Macaulay and, as $C$ is regular, $f$ is flat by miracle flatness [Sta, Tag 00R4]. We can thus apply [Reference RaynaudRay70, Proposition 9.3.1].

Remark 4.6. The conditions imposed on $S$ in Proposition 4.4 and Proposition 4.5 are optimal as shown in the examples of [Reference RaynaudRay70, Section 9].

If the generic fibre has arithmetic genus at least 1, then wild fibres can appear when the residue field has characteristic $p\gt 0$ .

Example 4.7. Suppose $k$ is algebraically closed of characteristic $p\gt 0$ . We recall the construction of wild fibres explained by Raynaud [Reference RaynaudRay70]. Let $E_{k(C)}$ be an elliptic curve (ordinary if ${\mathrm{char}}(k(C))\gt 0$ ) such that the special fibre of its Néron model is either a supersingular elliptic curve $E_{k}$ or the multiplicative group $\mathbb{G}_{m,k}$ . Let $S_{k(C)}$ be a regular torsor over $E_{k(C)}$ of order $p^n$ for $n\gt 0$ and let $f \colon S \to C$ be its minimal model. Then $\mathcal{T} \neq 0$ by [Reference RaynaudRay70, Théoréme 9.4.1.b].

Another set of examples, based on Artin–Schreier coverings, is discussed in [Reference Katsura and UenoKU85, Section 8].

4.2 Cohen–Macaulay criteria for log canonical 3-fold singularities

Throughout this section, we suppose $(X, \Delta )$ is 3-dimensional log canonical singularity as in Setting 3.1.

Note that, as proved in [Reference Arvidsson and PosvaAP23, Theorem 1], the 1-dimensional scheme $C$ is normal and thus regular. Using Theorem 3.3 the failure of Cohen–Macaulay-ness is explained by the presence of a wild fibre on a proper birational modification. We use this to show that if the surface singularity at the generic point of $C$ is rational, then $X$ is Cohen–Macaulay.

Proposition 4.8. Let $C \subset (X,\Delta )$ as in Setting 3.4 . If $\mathcal{O}_{X, \eta }$ is a rational surface singularity, then $X$ is $(S_3)$ at $x$ . In particular, if $C \subset{\mathrm{Supp}}(\Delta )$ , then $X$ is $(S_3)$ at $x$ .

Proof. Let $g \colon (Z, g_*^{-1}\Delta +E) \to (X, \Delta )$ be the crepant proper birational morphism constructed in Theorem 3.3. It is sufficient to show that $H^0_x(E, R^1(g|_E)_* \mathcal{O}_E)$ vanishes to conclude. Note that $E$ is $(S_2)$ . Moreover, the irreducible components of $E$ and their non-normal loci dominate $C$ as it is the minimal log canonical centre passing through $x$ . As $\mathcal{O}_{X, \eta }$ is a rational singularity and $C$ is regular, we apply Proposition 4.5 to conclude $H^0_x(C, R^1g_*\mathcal{O}_E)=0$ . For the last assertion, we just observe that $\mathcal{O}_{X,\eta }$ is a rational singularity by [Reference KollárKol13, Proposition 2.28].

Corollary 4.9. Let $C \subset (X,\Delta )$ as in Section 3.4. Let $g \colon (Z, g_*^{-1}\Delta +E) \to (X,\Delta )$ be the modification constructed in Theorem 3.3 . If $H^2_x(X, \mathcal{O}_X) \neq 0$ , then

  1. (i) $\mathcal{O}_{X, \eta }$ is not rational and $C$ is not contained in ${\mathrm{Supp}}(\Delta )$ ,

  2. (ii) the fibre $E_x$ is wild.

Proof. (a) is proven in Proposition 4.8. As $h^1(E_{\eta }, \mathcal{O}_{E_{\eta }}) \neq 0$ and $\mathcal{O}_{X, \eta }$ is log canonical, then $\deg _{\eta } \omega _{E_\eta }=0$ . By Theorem 3.3.iii we have $H^0_x(C, R^1g_*\mathcal{O}_E) \simeq H^2_x(X, \mathcal{O}_X) \neq 0$ , and thus $E_x$ is a wild fibre for $g \colon E \to C$ .

As a byproducts of the results of Section 3 and the properties of wild fibres Proposition 4.4.1, we can prove the $(S_3)$ -condition of log canonical 3-folds pairs in the case where a Cartier divisor is an addendum of the boundary divisor. This answers [Reference KollárKol23a, Question 8] affirmatively if the characteristic of the residue field is different from $2, 3$ and $5$ .

Theorem 4.10. Let $(X,X_0+\Delta )$ be a 3-dimensional log canonical pair and let $x$ be a closed point of $X$ . Suppose $X_0$ is a non-zero effective Cartier divisor such that $x \in X_0$ . Then $X$ is $(S_3)$ at $x$ .

Proof. We can localise at the closed point $x$ . As $X_0$ is effective, $x$ cannot be a minimal log canonical centre for $(X,\Delta )$ . By Lemma 3.2 and Corollary 4.9, we can suppose that

  1. (i) the minimal log canonical centre $C$ of $(X, X_0+ \Delta )$ passing through $x$ has dimension 1;

  2. (ii) if $\eta$ is the generic point of $C$ , then $\mathcal{O}_{X, \eta }$ is a non-rational surface singularity and $\eta \notin{\mathrm{Supp}}(X_0+\Delta )$ .

If $g \colon (Z, g_*^{-1}\Delta +E) \to (X, \Delta )$ is the crepant proper birational morphism constructed in Theorem 3.3, it is sufficient to show that $H^0_x(E, R^1(g|_E)_* \mathcal{O}_E)$ vanishes to conclude. For this we argue by contradiction.

First we note that the pair $(Z, g_*^{-1}\Delta +E+g^*X_0)$ is log canonical and $E$ is $(S_2)$ . By adjunction [Reference KollárKol13, Lemma 4.8] the pair $(E,{\mathrm{Diff}}_E(g^*X_0+g_*^{-1}\Delta ))$ is slc and, as $X_0$ is Cartier, we have ${\mathrm{Diff}}_E(g^*X_0+g_*^{-1}\Delta )=(g^*{X_0})|_E+{\mathrm{Diff}}_E(g_*^{-1}\Delta )$ by [Reference KollárKol13, Lemma 2.5]. As $E_x$ is a wild fibre, by Proposition 4.4 each of its irreducible components is non-reduced. As $X_0$ is an effective Cartier divisor not containing $C$ , then $(g^*X_0)|_E$ must have coefficients strictly larger than 1, contradicting that $(E,{\mathrm{Diff}}_E(g^*X_0+g_*^{-1}\Delta ))$ is slc.

4.3 Properness of the moduli space of stable surfaces

We briefly recall the natural set-up for the study of stable and locally stable families and we refer to [Reference KollárKol23b, Chapter 2] for a thorough discussion.

Let $C={\mathrm{Spec}}(R)$ , where $(R, \mathfrak{m})$ is a DVR with perfect residue field $k := R/\mathfrak{m}$ of characteristic $p\gt 0$ , and fraction field $K := \text{Frac}(R)$ . We say that a morphism $f\colon X\to C$ is family of varieties is $f$ is a flat morphism of finite type such that for every $c \in C$ the fiber $X_c$ is pure dimensional, geometrically reduced and geometrically connected. We denote the special (resp. generic) fibre of $f$ by $X_k$ (resp. $X_K$ ). A family of pairs is $f \colon (X,\Delta ) \to C$ is a family of varieties $f\colon X \to C$ together with an effective Mumford $\mathbb{Q}$ -divisor $\Delta$ on $X$ such that ${\mathrm{Supp}}(\Delta )$ does not contain any irreducible components of $X_k$ and none of the irreducible components of $X_k \cap{\mathrm{Supp}}(\Delta )$ is contained in $\text{Sing}(X_k)$ .

Definition 4.11. We say $f \colon (X, \Delta ) \to C$ is a locally stable (or slc) family if $f$ is a family of pairs and $(X, \Delta +X_k)$ has slc singularities. We say $f$ is a stable family if $f$ is a projective locally stable family such that $K_X+\Delta$ is ample over $C$ .

In [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Corollary 10.2], $\overline{\mathcal{M}}_{2,v}$ is shown to exist as a separated Artin stack of finite type over $\mathbb{Z}[1/30]$ with finite diagonal. The main open question on $\overline{\mathcal{M}}_{2,v}$ is whether it is a proper stack over $\mathbb{Z}[1/30]$ (some cases are discussed in [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Theorem 10.6]).

To prove properness, one has to prove the valutative criterion for families of stable surfaces. As explained in [Reference PosvaPos21b, Section 6], this can be reduced to two problems on locally stable families: the existence of a locally-stable reduction and the $(S_2)$ -condition on stable limits. We recall their precise formulation.

  1. (LSR) Let $X \to C$ be a flat projective morphism where $X$ is a regular 3-fold. Let $E$ be a reduced effective divisor on $X$ such that $(X, E + (X_k)_{\text{red}})$ is snc for every closed point $c \in C$ . Then there exists a finite morphism $C^{\prime} \to C$ such that: if $Y$ is the normalization of $X \times _C C^{\prime}$ and $E_Y$ is the pull-back divisor, then every closed fiber $Y_{k^{\prime}}$ is reduced and every $(Y, E_Y + Y_{k^{\prime}})$ is log canonical.

  2. (S2) Let $(X, \Delta ) \to C$ be a stable family of surface pairs. Then $X_k$ is $(S_2)$ .

In equicharacteristic 0, existence of semi-stable reduction is proven in [Reference Kempf, Knudsen, Mumford and Saint-DonatKKM+73] (see also [Reference Kollár and MoriKM98, Theorem 7.17]) and the $(S_2)$ -property is proven in [Reference AlexeevAle08] (see also [Reference KollárKol23b, Definition-Theorem 2.3]). While semi-stable reduction of surfaces is still an open conjecture, the results of [Reference Bernasconi and KollárBK23] can be used to prove the $(S_2)$ -condition for the closure of the locus of klt stable varieties (see the last lines of the proof of [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Theorem 10.6]). We now settle the general semi-log canonical case.

Theorem 4.12. Suppose $p \neq 2,3$ and $5$ . If $f \colon (X, \Delta ) \to C$ is a stable family of surfaces, then $X_k$ is $(S_2)$ and $(X_k,{\mathrm{Diff}}_{X_k}(\Delta ))$ is slc.

Proof. If $X$ is normal, then $(X,\Delta +X_k)$ is a log canonical pair. For every closed point $p \in X_k$ , the local ring $\mathcal{O}_{X,p}$ is $(S_3)$ by Theorem 4.2.3. As $X_k$ is a Cartier divisor, we deduce $X_k$ is $(S_2)$ by [Reference KollárKol13, Corollary 2.61]. By performing adjunction [Reference KollárKol13, Definition 4.2], we deduce that the normalisation $\big (X^{\nu }_k,{\mathrm{Diff}}_{X^{\nu }_k}(\Delta )\big )$ is log canonical by [Reference KollárKol13, Lemma 4.8]. Therefore $(X_k,{\mathrm{Diff}}_{X_k}(\Delta ))$ is semi-log canonical by definition.

Suppose $X$ is demi-normal and let $\pi \colon Y \to X$ be its normalisation. We write $K_Y+D+\pi ^*\Delta =\pi ^*(K_X+\Delta )$ , where $D$ is the divisorial part of the conductor. Then $(Y,D+\pi ^*\Delta ) \to C$ is a stable family of pairs, where $Y$ is normal. By the previous step, $Y_k$ is $(S_2)$ and the pair $(Y_k,{\mathrm{Diff}}_{Y_k}(\pi ^*\Delta ))$ is slc. We conclude $X_k$ is $S_2$ and $(X_k,{\mathrm{Diff}}_{X_k}(\Delta ))$ is slc by [Reference PosvaPos21a, Proposition 4.2.6].

We now have all the ingredients to prove the main result of this article.

Theorem 4.13. Assume (LSR). Then the moduli stack $\overline{\mathcal{M}}_{2,v}$ is proper over $\mathbb{Z}[1/30]$ and the coarse moduli space $\overline{M}_{2,v}$ is projective over $\mathbb{Z}[1/30]$ .

Proof. The proof of [Reference PosvaPos21b, Theorem 6.0.5] works also in mixed characteristic and thus the (LSR) hypothesis together with Theorem 4.12 conclude the properness of $\overline{\mathcal{M}}_{2,v}$ . The projectivity of $\overline{M}_{2,v}$ is then shown in [Reference PatakfalviPat17, Theorem 1.2].

We conclude by giving an application to the asymptotic invariance of plurigenera for log canonical minimal surface pairs of general type. This generalises the klt case proven in [Reference Bernasconi, Brivio and StigantBBS24, Theorem 4.1].

Corollary 4.14. Suppose $p \gt 5$ . Let $(X,\Delta )$ be a 3-dimensional pair and let $\pi \colon (X, \Delta ) \to C$ be a projective contraction such that $(X_k,{\mathrm{Diff}}_{X_k}(\Delta ))$ is log canonical. If $K_X+\Delta$ is nef and big over $C$ , then there exists $m_0\gt 0$ such that

\begin{equation*} \dim _k H^0(X_k, m(K_{X_k} + \Delta _k)) = \dim _K H^0(X_K, m(K_{X_K} + \Delta _K))\ \textit{ for\ all }\ m \in m_0 \mathbb {N}\end{equation*}

Proof. By inversion of adjunction [Reference Bhatt, Ma, Patakfalvi, Schwede, Tucker, Waldron and WitaszekBMP+23, Corollary 10.1], we conclude $(X,X_k+\Delta )$ is a log canonical pair. We first claim that $K_X+\Delta$ is semi-ample over $C$ . Since the characteristic of the residue field of $R$ is $p\gt 0$ , by [Reference WitaszekWit21, Theorem 2.2] it is sufficient to check semiampleness fiber-wise. For this, note that $K_{X_K}+\Delta _K$ and $(K_{X}+\Delta )|_{X_k} \sim _{\mathbb{Q}} K_{X_k}+{\mathrm{Diff}}_{X_k}(\Delta )$ are semiample by the abundance theorem for log canonical surfaces [Reference TanakaTan20]. Let $f \colon (X,\Delta ) \to (Z, \Delta _Z=f_*\Delta )$ be the semiample birational contraction associated to $K_X+\Delta$ . Note that $f \colon (X, X_k+\Delta ) \to (Z, Z_k+\Delta )$ is also crepant.

By [Reference Bernasconi, Brivio and StigantBBS24, Lemma 2.17], it is sufficient to check that $(f_k)_*\mathcal{O}_{X_k}=\mathcal{O}_{Z_k}$ to conclude. By considering the Stein factorisation $f_k \colon X_k \to Y \to Z_k$ , we are left to show $g \colon Y \to Z_k$ is an isomorphism. As the morphism $g \colon Y \to Z_k$ is a birational morphism and $Y$ is normal, it is sufficient to verify that $Z_k$ is normal to conclude. By construction $(Z,Z_k+{\mathrm{Diff}}_{Z}(\Delta _Z))$ is log canonical and thus $Z_k$ satisfies the $(S_2)$ condition by Theorem 4.12. By Serre’s criterion for normality, we are thus left to show that $Z_k$ is $(R_1)$ , and we argue by contradiction. Suppose there exists a codimension 1 point $\eta$ of $Z_k$ such that $Z_k$ is not normal. Then by inversion of adjunction $\eta$ is the generic point of a log canonical centre of $(Z,Z_k+\Delta )$ and thus it is nodal. By [Reference BrivioBri22, Lemma 2.7] the normalisation of $Z_k$ is a universal homeomorphism and thus we conclude.

Remark 4.15. In [Reference KollárKol23a, Theorem 1], Kollár proves that the moduli space of stable 3-folds is not proper over any field of characteristic $p\gt 0$ . In particular, [Reference KollárKol23a, Example 4] show that Theorem 4.12, Corollary 4.13 and Corollary 4.14 do not generalise to dimension 3, even for large $p$ .

Question 4.16. We leave open the question whether Theorem 4.3.2 hold in characteristic $p \leq 5$ . Note that the examples of non-normal plt centres constructed [Reference Cascini and TanakaCT19] are not Cartier.

5. Counterexamples to local Kawamata–Viehweg vanishing

We conclude by constructing a counterexample to the local Kawamata–Viehweg vanishing theorem for log canonical 3-dimensional singularities in positive and mixed characteristic (Theorem 1.3). The counterexample is obtained by taking the relative cone over an elliptic surface fibration with a wild fibre.

5.1 Relative cone construction

In this section we develop the theory of relative cones, expanding on [Reference KollárKol13, Section 3.2]. Let $f \colon X \to T$ be a projective flat morphism of normal integral schemes with $f_*{\mathcal{O}}_X={\mathcal{O}}_T$ and let $L$ be an $f$ -ample invertible sheaf. We define the affine $T$ -scheme:

\begin{equation*}C_a(X, f, L)= {\mathrm {Spec}}_T \bigoplus _{m \geq 0} f_* \mathcal {O}_X(mL) \to T. \end{equation*}

The scheme $C_a(X,f,L)$ is the relative cone of $f$ with respect to $L$ . The natural subscheme $V_T \subset C_a(X,f, L)$ defined by the ideal sheaf $ \bigoplus _{m \geq 1} f_* \mathcal{O}_X(mL)$ is isomorphic to $T$ and it is called the relative vertex. The variety $C_a^*(X,f,L)=C_a(X, f, L) \setminus V_T \simeq BC_a^*(X, f, L) \setminus E$ is called the relative punctured cone.

We have the following commutative diagram

where $p$ is a birational projective morphism with exceptional divisor $E \simeq X$ onto $V_T$ such that

\begin{equation*}\mathcal {O}_{BC_a(X,f,L)}(E)|_E=L^{\vee }.\end{equation*}

The following is a generalisation of [Reference KollárKol13, Proposition 3.14] to the relative setting.

Proposition 5.1. With the same setting as above, we have

  1. (i) ${\mathrm{Pic}}(C_a(X, f, L)) \simeq{\mathrm{Pic}}(T)$ ;

  2. (ii) ${\mathrm{Cl}}(C_a(X, f, L)) \simeq{\mathrm{Cl}}(X)/\langle L \rangle .$

Let $\Delta _X$ be a $\mathbb{Q}$ -divisor on $X$ , and assume $K_X+\Delta _X$ is $\mathbb{Q}$ -Cartier. We define $\Delta _{BC_a(X,L)}=\pi ^*\Delta$ and $\Delta _{C_a(X,f,L)}=p_*\Delta _{BC_a(X,L)}$ . We have the following

  1. (iii) $K_{BC_a(X,L)}+\Delta _{BC_a(X,L)}+E \sim _{\mathbb{Q}} \pi ^*(K_X+\Delta )$ ,

  2. (iv) $m(K_{C_a(X, f, L)}+\Delta _{C_a(X, f, L)})$ is Cartier iff $m(K_X+\Delta ) \sim _{f} L^{rm}$ for some $r \in{\mathbb{Q}}$ . In this case we have

    \begin{equation*}K_{BC_a(X,L)}+\Delta _{BC_a(X,L)}+(1+r)E \sim _{{\mathbb {Q}}} p^*(K_{C_a(X, f, L)}+\Delta _{C_a(X, f, L)}). \end{equation*}

Proof. Since $BC_a(X,L)$ is an $\mathbb{A}^1$ -bundle over $X$ , we have ${\mathrm{Cl}}(BC_a(X,L))\simeq{\mathrm{Cl}}(X)$ and ${\mathrm{Pic}}(BC_a(X,L)) \simeq{\mathrm{Pic}}(X)$ . Let us note that we have the following commutative diagram:

where the top arrows are all isomorphisms. We prove (i). Let $D$ be an invertible sheaf on $C_a(X, f, L)$ ; then $p^*D|_E$ is the pull-back of a line bundle on $V_T$ , thus proving (i). Items (ii) and (iii) are proven in [Reference KollárKol13, Proposition 3.14]. Recall that since ${\mathrm{Pic}}(C_a^*(X,f,L)) \hookrightarrow$ ${\mathrm{Cl}}(C_a^*(X,f,L)) \simeq{\mathrm{Cl}}(X)/\langle L \rangle$ , the kernel of the morphism $\pi |_{C_a^*(X,f,L)}^* \colon{\mathrm{Pic}}(X) \to{\mathrm{Pic}}(C_a^*(X,f,L))$ is the subgroup generated by $L$ .

As for (iv) $m(K_{C_a(X,f,L)}+\Delta _{C_a(X,f,L)})$ is Cartier if and only if the Weil divisor $m(K_{C_a^*(X,f,L)}+\Delta _{C_a^*(X,f,L)})$ is the pull-back of a Cartier divisor on $T$ by (i). In turn, this is equivalent to asking whether $\pi |_{C_a^*(X,f,L)}^{*}(mK_X+m\Delta )=\pi |_{C_a^*(X,f,L)}^{*}f^* D$ for some Cartier divisor $D$ on $T.$ This is equivalent to $m(K_{X}+\Delta )-f^*D \sim L^{rm}$ for some $r \in{\mathbb{Q}}$ , thus concluding the first part. As for the last equality, let us write

\begin{equation*}K_{BC_a(X,L)}+\Delta _{BC_a(X,L)}+(1+a)E \sim _{{\mathbb {Q}}} p^*(K_{C_a(X, f, L)}+\Delta _{C_a(X, f, L)}). \end{equation*}

By restricting to $E$ , we have $K_X+\Delta +aE|_E \sim _{{\mathbb{Q}},f} 0,$ which becomes $rL -aL=0;$ thus $r=a$ .

As a corollary we have the following result on the singularities of relative cones (to compare with [Reference KollárKol13, Lemma 3.1]).

Proposition 5.2. In the previous setting, assume $K_X+\Delta$ is $\mathbb{Q}$ -Cartier and $K_X+\Delta \sim _{f,{\mathbb{Q}}} rL$ for some $r \in{\mathbb{Q}}$ . Then $(C_a(X,f,L),\Delta _{C_a(X,f,L)})$ is

  1. (i) klt if $r\lt 0$ and $(X,\Delta )$ is klt;

  2. (ii) log canonical if $r \leq 0$ and $(X,\Delta )$ is log canonical.

Proof. By Proposition 5.1, we have

\begin{equation*} \text {discrep}((C_a(X,f,L),\Delta _{C_a(X,f,L)})) =\min \left \{-(1+r), \text {discrep}(BC_a(X,L),\Delta _{BC_a(X,L)}+(1+r)E)\right \}. \end{equation*}

Since $\pi$ is a smooth morphism and $E$ is a section for $\pi$ , we conclude by [Reference KollárKol13, 2.14, Equation (4)] that

\begin{equation*} \text {discrep}(BC_a(X,L),\Delta _{BC_a(X,L)}+E) = \text {totdiscrep}(X,\Delta ). \end{equation*}

Thus (a) and (b) are automatic.

5.2 Failure of the ( ${\boldsymbol{S}}_{\textbf{3}}$ )-condition at a non-minimal lc centre

We construct an example showing that Theorem 1.2 is not valid in general in positive and mixed characteristic, thus showing that the statement of Theorem 4.10 is sharp. We fix $C$ to be the spectrum of a DVR whose closed point is perfect of characteristic $p\gt 0$ .

Proposition 5.3. Let $S$ be a regular surface, and let $f \colon S \to C$ be a minimal elliptic fibration together with a relatively $f$ -ample invertible sheaf $L$ . Then $X:= C_a(S,f,L)$ is a 3-dimensional log canonical singularity, the map $p \colon Y:=BC_a(S,L) \to X$ is a log resolution, and the vertex $V_C$ is the unique log canonical centre of $X$ .

Proof. By Proposition 5.1, we have $K_{Y}+E \sim _{{\mathbb{Q}}} p^* K_X.$ Since $(Y, E)$ is log smooth and $E$ is irreducible, we conclude that $E$ is the unique log canonical place of $X$ . Thus $V_C$ is the unique log canonical centre of $X$ .

In the next lemmas we compute the local cohomology at a closed point in a log canonical place.

Lemma 5.4. Let $D$ be a $\mathbb{Z}$ -divisor on $Y$ . If $D \sim _{p,{\mathbb{Q}}} K_Y$ , then $R^1p_*{\mathcal{O}}_Y(D)=0$ .

Proof. By [Reference TanakaTan18, Theorem 3.3], the relative Kawamata–Viehweg vanishing theorem holds for the morphism $p|_E \colon E \to V_C$ . Since $-E$ is $p$ -ample and $D \sim _{p,{\mathbb{Q}}} (K_Y+E)-E$ , we conclude by [Reference Bernasconi and KollárBK23, Proposition 22].

Proposition 5.5. Let $x \in V_C \simeq C$ . Then $H^2_x(X, \mathcal{O}_X) \simeq H^0_x(C, \mathcal{T}).$

Proof. By the Leray spectral sequence for local cohomology $H^i_x(X, R^j p_*{\mathcal{O}}_Y) \Rightarrow H^{i+j}_{p^{-1}(x)} (Y, \mathcal{O}_Y),$ we have the exact sequence

\begin{equation*}H^0_x(X, R^1 p_* {\mathcal {O}}_Y) \to H^2_x(X, {\mathcal {O}}_X) \to H^2_{p^{-1}(x)}(Y, {\mathcal {O}}_Y). \end{equation*}

Claim 5.6. The following isomorphisms hold:

  1. (i) $H^2_{p^{-1}(x)}(Y,{\mathcal{O}}_Y) =0$ ,

  2. (ii) $R^1p_*{\mathcal{O}}_Y \simeq R^1(p|_E)_*{\mathcal{O}}_E$ .

Proof. To prove $(i)$ , because $Y$ is regular we can apply duality [Reference KollárKol13, 10.44] to deduce $H^2_{p^{-1}(x)}(Y,{\mathcal{O}}_Y)\simeq (R^1p_*{\mathcal{O}}_Y(K_Y))_x$ , and we conclude by Lemma 5.4.

To prove $(ii)$ , it is enough to show that $R^1 p_*{\mathcal{O}}_Y(-E)=0$ as $R^2\pi _*{\mathcal{O}}_Y(-E)=0$ since the fibres of $p$ are at most 1-dimensional. Since $-E \sim _{p,{\mathbb{Q}}} K_Y$ , we conclude again by Lemma 5.4.

Using Corollary 5.6, we have

\begin{equation*}H^2_x(X, {\mathcal {O}}_X) \simeq H^0_x(X, R^1 p_* {\mathcal {O}}_Y) \simeq H^0_x(X, R^1(p|_E)_* {\mathcal {O}}_E).\end{equation*}

We denote by $i \colon V_C \to X$ the natural injection. Then we have the following isomorphism $H^0_x(X, R^1(p|_E)_*{\mathcal{O}}_E)\simeq H^0_x(X, i_*(\mathcal{M} \oplus \mathcal{T})).$ Using again the Leray spectral sequence of local cohomology for $i$ we have $H^0_x(X, i_*(\mathcal{M} \oplus \mathcal{T})) \simeq H^0_x(C, \mathcal{M} \oplus \mathcal{T})=H^0_x(C, \mathcal{T}),$ since $\mathcal{M}$ is locally free thus concluding.

Proof of Theorem 1.3. Let $f \colon S \to C$ be a minimal elliptic fibration such that $\mathcal{T} \neq 0$ (such a surface exists by Example 4.7). By Proposition 5.3, $X=C_a(S,f,L)$ is a 3-dimensional log canonical variety, where the relative vertex $V_C$ is the unique minimal log canonical centre. By Proposition 5.5, we deduce that the local cohomology $H^2_x(X,{\mathcal{O}}_X) \neq 0,$ thus proving (c).

Question 5.7. In Theorem 1.3 we construct a log canonical 3-fold singularity $X$ with a minimal 1-dimensional log canonical centre and not C–M, showing optimality of Proposition 4.2.1 and Theorem 4.2.3 in the case where the exceptional divisor $E_\eta$ is a regular curve of genus 1. We do not know if the failure of Cohen–Macaualy-ness can appear in the case where $E_\eta$ is a nodal curve.

Remark 5.8. A guiding principle in birational geometry in characteristic $p$ says that properties of klt and dlt singularities should behave similarly to characteristic 0 if $p$ is sufficiently large compared to the dimension [Reference TotaroTot19, Section 6]. This principle does not apply to log canonical singularities. For example, in [Reference KollárKol23a, Corollary 6], Kollár shows examples of 4-dimensional log canonical pairs with non-weakly normal lc centres in every characteristic $p\gt 0$ . Theorem 1.3 shows that pathological phenomena already appear in dimension 3 for every prime number.

Acknowledgements

The authors thank J. Baudin, S. Filipazzi, C.D. Hacon, J. Kollár and Q. Posva for interesting discussions and useful comments on the topic of this article. We are grateful to the reviewer for carefully reading our article and for suggesting multiple improvements.

Conflicts of Interest

None.

Funding Statement

EA is supported by SNF #P500PT 203083, FB is partially supported by the NSF under grant number DMS-1801851 and the grant #200021/192035 from the Swiss National Science Foundation, ZsP is supported by the grant #200021/192035 from the Swiss National Science Foundation and the ERC starting grant #804334.

Journal Information

Moduli is published as a joint venture of the Foundation Compositio Mathematica and the London Mathematical Society. As not-for-profit organisations, the Foundation and Society reinvest $100\%$ of any surplus generated from their publications back into mathematics through their charitable activities.

Footnotes

1 This is because for any effective divisor $D$ on a surface $X$ , the strict transform $\pi _*^{-1}D$ is nef over $X$ .

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