1 Introduction
Fano varieties and Calabi–Yau varieties are two of the three building blocks of algebraic varieties. In the former case, the canonical divisor is antiample, while in the latter case it is numerically trivial. In this article, we study the coregularity of Fano and Calabi–Yau varieties. This invariant measures the dimension of the dual complexes corresponding to log Calabi–Yau structures on the variety. We show that if the coregularity is at most two, we can control the index of a Calabi–Yau variety and the complements of a Fano variety. In [Reference Moraga35], the third named author relates various problems about Fano varieties with the concept of coregularity.
1.1 Log Calabi–Yau pairs
A log Calabi–Yau pair
$(X,B)$
is a projective log canonical pair for which
$K_X+B\equiv 0$
. By the abundance conjecture, which is known in this special case [Reference Gongyo21], it is also known that
$K_X+B\sim _{\mathbb {Q}} 0$
. The index of
$(X,B)$
is the smallest positive integer I for which
$I(K_X+B)\sim 0$
. It is conjectured that the index I of
$(X,B)$
admits an upper bound depending on the dimension of X and the set of coefficients of B. This is known as the index conjecture. For instance, if
$(X,B)$
is two-dimensional and the coefficients of B are standard (i.e., of the form
$1-\frac {1}{m}$
for some
$m\in \mathbb {Z}_{>0}$
), then
$I(K_X+B)\sim 0$
for some
$I\leq 66$
(see, e.g., [Reference Ishii26, Theorem 4.11]). The bound
$66$
is optimal, and it can be obtained by considering nonsymplectic finite actions on K3 surfaces [Reference Machida and Oguiso34]. In [Reference Esser, Totaro and Wang9], the authors exhibit a sequence of klt Calabi–Yau varieties
$X_d$
with index
$i_d$
that grows doubly exponentially with the dimension d. The coregularity of a log Calabi–Yau pair
$(X,B)$
is defined to be
$\dim X - \dim \mathcal {D}(X,B)-1$
. Here,
$\mathcal {D}(X,B)$
is the dual complex of
$(X,B)$
. This is a pseudo-manifold that encodes the combinatorial data of log canonical centers of a dlt modification of
$(X,B)$
. The dimension
$\dim \mathcal {D}(X,B)$
is independent of the chosen dlt modification, so it is an intrinsic invariant of
$(X,B)$
. In the following subsection, we present theorems regarding the index of log Calabi–Yau pairs of coregularity
$0$
and
$1$
.
1.2 Index and coregularity of log Calabi–Yau pairs
First, we study log Calabi–Yau pairs of coregularity 0 and 1. We use the language of generalized pairs as in [Reference Birkar3, Reference Filipazzi11]. This gives a larger scope for the theorems and also facilitates inductive arguments. In the case of generalized log Calabi–Yau pairs of coregularity
$0$
, the following theorem is proved in [Reference Filipazzi, Mauri and Moraga13].
Theorem 1. Let
$(X,B,\mathbf {M})$
be a projective generalized log Calabi–Yau pairFootnote
1
of coregularity
$0$
, and let be
$\lambda $
a positive integer. Assume that
$\lambda (K_X+B+{\mathbf {M}_{X}})$
is Weil. Then, we have that
$2\lambda (K_X+B+{\mathbf {M}_{X}})\sim 0$
.
Note that in order to have a linear equivalence
$D\sim 0$
, the divisor D must be Weil. Hence, multiplying
$K_X+B+{\mathbf {M}_{X}}$
by
$\lambda $
is indeed needed to compute its index. In [Reference Filipazzi, Mauri and Moraga13, Example 7.4], the authors give an example for which
$(X,B)$
is log Calabi–Yau of coregularity
$0$
, B is a Weil divisor,
$2(K_X+B)\sim 0$
, and
$K_X+B$
is not linearly equivalent to 0. Hence, the factor
$2\lambda $
in the previous theorem is optimal. Indeed, the factor
$2$
is often related to the orientability of the pseudo-manifold
$\mathcal {D}(X,B)$
(see [Reference Filipazzi, Mauri and Moraga13, § 5]). In [Reference Filipazzi, Mauri and Moraga13], the authors use topological methods and birational geometry to prove the previous theorem. In this article, we recover this statement using birational geometry and the theory of complements.
Our next theorem deals with the index of log Calabi–Yau pairs of coregularity
$1$
. This is a generalization of the previous statement to the case of coregularity
$1$
.
Theorem 2. Let
$(X,B,\mathbf {M})$
be a projective generalized log Calabi–Yau pair of coregularity
$1$
and
$\lambda $
be a positive integer. Assume the two following conditions hold:
-
• the generalized pair
$(X,B,\mathbf {M})$
has Weil index
$\lambda $
; and -
• the variety X is rationally connected or
$\mathbf {M}=0$
.
Then, we have that
$I(K_X+B+{\mathbf {M}_{X}})\sim 0$
for
$I=m\lambda $
with
$m\leq 120\lambda $
.
We emphasize that the previous theorem does not hold if X is not rationally connected and
$\mathbf {M}$
is nontrivial. For instance, we can let X be an elliptic curve and
$\mathbf {M}$
be an I-torsion point in
$\mathrm {Pic}^0(X)$
. Then, we have that
$I(K_X+{\mathbf {M}_{X}})\sim I{\mathbf {M}_{X}} \sim 0$
is minimal and
$(X,\mathbf {M})$
is a generalized log Calabi–Yau pair of coregularity
$1$
. Note that this is not an issue if X is rationally connected. In this case, the torsion of components of the b-nef divisor is controlled by their Weil index. Theorem 1 and Theorem 2 are still valid if the coefficients of B belong to a set of rational numbers satisfying the descending chain condition (DCC) condition. This follows from the global ascending chain condition for generalized log Calabi–Yau pairs with bounded coregularity (see [Reference Figueroa, Moraga and Peng10, Theorem 2]). Finally, in the case of coregularity
$1$
, we obtain the following statement.
Theorem 3. Let
$(X,B,\mathbf {M})$
be a projective generalized log Calabi–Yau pair of coregularity
$1$
. Assume that the following conditions hold:
-
• the coefficients of B are standard;
-
• the divisor
$2\mathbf {M}$
is b-Cartier; and -
• the variety X is rationally connected or
$\mathbf {M}=0$
.
Then, we have that
$I(K_X+B+{\mathbf {M}_{X}})\sim 0$
for some
$I\in \{1,2,3,4,6\}$
.
1.3 Fano varieties
Given a klt Fano variety X, the anticanonical divisor
$-K_X$
is ample. Hence, the linear system
$|-mK_X|$
is basepoint free for m sufficiently large and divisible. In particular, we can find an effective divisor
$B \in |-mK_X|$
such that the pair
$(X,B/m)$
is klt (Kawamata log terminal) and log Calabi–Yau. This means that every Fano variety admits a log Calabi–Yau structure. In [Reference Birkar3], Birkar showed that an n-dimensional Fano variety X admits an
$N(n)$
-complement, that is, a boundary B for which
$(X,B)$
is log canonical and
$N(n)(K_X+B)\sim 0$
. This can be thought of as an effective log Calabi–Yau structure on X. In [Reference Filipazzi, Moraga and Xu15], Filipazzi, Moraga and Xu proved that a 3-fold that admits a
$\mathbb {Q}$
-complementFootnote
2
also admits a
$N_3$
-complement.
Let X be an n-dimensional Fano variety. We can define the absolute coregularity to be:
By definition, the absolute coregularity of X is at most n. It is expected that a Fano variety of absolute coregularity c admits an
$N(c)$
-complement (see, e.g., [Reference Moraga35, Conjecture 4.1]). Indeed, following the philosophy of Kawamata’s X-method, one expects to lift complements from minimal log canonical centers. In the case of a Fano variety of absolute coregularity c, we can produce minimal log canonical centers having dimension c [on a suitable dlt (divisorially log terminal) modification]. In the following subsection, we present some theorems regarding complements of Fano type varieties of absolute coregularity
$0$
and
$1$
.
1.4 Complements and coregularity of Fano type varieties
Our main theorem in this direction states that a Fano type variety of absolute coregularity 0 admits a
$1$
-complement or a
$2$
-complement.
Theorem 4. Let
$(X,B,\mathbf {M})$
be a projective generalized Fano type pair of absolute coregularity
$0$
. Assume that the following conditions hold:
-
• the coefficients of B are standard;
-
• the b-nef divisor
$2\mathbf {M}$
is b-Cartier.
Then, there exists a boundary
$B^+ \geq B$
satisfying the following conditions:
-
• the generalized pair
$(X,B^+,\mathbf {M})$
is generalized log canonical; -
• we have that
$2(K_X+B^{+}+{\mathbf {M}_{X}})\sim 0$
; and -
• the equality
$\mathrm {coreg}(X,B^+,\mathbf {M})=0$
holds.
In the case that
$B=\mathbf {M}=0$
, the previous theorem says that, for a Fano variety X of absolute coregularity
$0$
, the linear system
$|-2K_X|$
contains an element with nice singularities. In particular, the linear system
$|-2K_X|$
is nonempty. In [Reference Totaro42, § 8], Totaro investigates Fano varieties with large bottom weight, which is the smallest positive integer m for which
$H^0(X,-mK_X)\neq 0$
. In particular, [Reference Totaro42, Theorem 8.1] implies the existence of a Fano
$4$
-fold that does not admit an m-complement for
$m\leq 1799233$
. This shows that the constant
$N(4)$
obtained by Birkar in [Reference Birkar3] is at least
$1799233$
. More generally, [Reference Totaro42, Theorem 8.1] shows that
$N(d)$
grows at least doubly exponentially with d. In contrast to this, our statement shows that a Fano variety of absolute coregularity
$0$
either admits a
$1$
-complement or a
$2$
-complement. In [Reference Moraga35, Example 3.15], the third author gives an example of a Fano surface of absolute coregularity
$0$
for which there is no
$1$
-complement. Thus, the previous theorem is sharp. In the case of absolute coregularity
$1$
, we obtain a similar result.
Theorem 5. Let
$(X,B,\mathbf {M})$
be a projective generalized Fano type pair of absolute coregularity
$1$
. Assume that the following conditions hold:
-
• the coefficients of B are standard;
-
• the b-nef divisor
$2\mathbf {M}$
is b-Cartier.
Then, there exists a boundary
$B^+\geq B$
satisfying the following conditions:
-
• the generalized pair
$(X,B^+,\mathbf {M})$
is generalized log canonical; -
• we have that
$N(K_X+B^{+}+\mathbf {M})\sim 0$
, where
$N\in \{1,2,3,4,6\}$
; and -
• the equality
$\mathrm {coreg}(X,B^+,\mathbf {M})=1$
holds.
In Table 1, we summarize the unconditional theorems regarding complements of Fano varieties. The entry
$(d,c)$
in the table corresponds to the minimum integer
$N_{d,c}$
for which every d-dimensional Fano variety of coregularity c admits at most a
$N_{d,c}$
-complement. In the blank spots, there set of such Fano varieties is empty. Due to the work of Liu [Reference Liu33], we know that
$N_2\leq {10^{10}}^{11}$
. However, it is expected that we can take
$N_2=66$
. By the work of Totaro [Reference Totaro42], we know that
$N_d$
grows at least doubly exponentially with d.
Table 1 Dimension, coregularity and complements
1.5 Calabi–Yau pairs of higher coregularity
In the case of higher coregularity, we need to deal with klt Calabi–Yau varieties of higher dimensions. We show that controlling the index of log Calabi–Yau pairs of coregularity c can be reduced to a problem about c-dimensional klt Calabi–Yau pairs. In order to state our next theorem, we need to introduce two conjectures about Calabi–Yau pairs. The first one is the boundedness of the index for klt Calabi–Yau pairs.
Conjecture 1. Let d be a positive integer, and let
$\Lambda $
be a set of rational numbers satisfying the descending chain condition. There exists a constant 
, satisfying the following property. For every projective d-dimensional klt log Calabi–Yau pair
$(X,B)$
such that B has coefficients in
$\Lambda $
, we have that
$$\begin{align*}I(\Lambda,d)(K_X+B)\sim 0. \end{align*}$$
The previous conjecture is stated in [Reference Birkar5, Conjecture 2.33]. The second conjecture is known as the boundedness of B-representations. It predicts that the birational automorphism group of a log Calabi–Yau pair acts on the sections of
$I(K_X+B)\sim 0$
with bounded order (see, e.g., [Reference Fujino18, Conjecture 3.2]).
Conjecture 2. Let d and I be two positive integers. There is a constant 
satisfying the following property. For every projective d-dimensional klt log Calabi–Yau pair
$(X,B)$
with
$I(K_X+B)\sim 0$
, the image of
$\mathrm {Bir}(X,B)$
in
$GL(H^0(I(K_X+B)))\simeq \mathbb {K}^*$
is finite and has order at most b.
Now, we can state our main theorem about the index of log Calabi–Yau pairs. It shows that the boundedness of the index of generalized log Calabi–Yau pairs of coregularity c can be reduced to the previous two conjectures in dimension c.
Theorem 6. Let c and p be positive integers and
$\Lambda \subset \mathbb {Q}$
be a set satisfying the descending chain condition. Assume that Conjecture 1 and Conjecture 2 hold in dimension c. There is a constant 
satisfying the following property. Let
$(X,B,\mathbf {M})$
be a projective generalized log Calabi–Yau pair of coregularity c for which:
-
• either X is rationally connected or
$\mathbf {M}=0$
; -
• the coefficients of B are contained in
$\Lambda $
; and -
• the b-nef divisor
$p\mathbf {M}$
is b-Cartier.
Then, we have that
$I(K_X+B+{\mathbf {M}_{X}})\sim 0$
.
1.6 Fano varieties of higher coregularity.
In the case of Fano varieties of higher absolute coregularity, we get the boundedness of complements of Fano type varieties with bounded absolute coregularity subject to the previous conjectures.
Theorem 7. Let c and p be positive integers and
$\Lambda \subset \mathbb {Q}$
be a closed set satisfying the descending chain condition. Assume that Conjecture 1 and Conjecture 2 hold in dimension c. There is a constant 
satisfying the following. Let
$(X,B,\mathbf {M})$
be a projective generalized Fano type pair of absolute coregularity c for which:
-
• the divisor B has coefficients in
$\Lambda $
; -
• the b-nef divisor
$p\mathbf {M}$
is Cartier where it descends.
Then, there exists a boundary
$B^+\geq B$
satisfying the following conditions:
-
• the generalized pair
$(X,B^+,\mathbf {M})$
is generalized log canonical; -
• we have that
$N(K_X+B^{+}+{\mathbf {M}_{X}})\sim 0$
; and -
• the equality
$\mathrm {coreg}(X,B^+,\mathbf {M})=c$
holds.
We stress that Conjecture 1 is known up to dimension
$3$
. On the other hand, Conjecture 2 is known up to dimension
$2$
. In particular, both Theorem 6 and Theorem 7 hold unconditionally in the case of coregularity 2.
1.7 Coregularity and the canonical bundle formula
The canonical bundle formula plays a fundamental role in the theory of complements. In many cases, we need to lift complements from the base of a log Calabi–Yau fibration. We will prove the following statement that relates the canonical bundle formula with the coregularity.
Theorem 8. Let c and p be nonnegative integers and
$\Lambda \subset \mathbb {Q}$
be a set satisfying the descending chain condition. Assume that Conjecture 1 and Conjecture 2 hold in dimension at most
$c-1$
. There exists a set 
satisfying the descending chain condition and a positive integer 
, satisfying the following property. Let
$\pi \colon X\rightarrow Z$
be a Fano type morphism between projective varieties. Let
$(X,B,\mathbf {M})$
be a projective generalized pair of coregularity c for which:
-
• the generalized pair
$(X,B,\mathbf {M})$
is log Calabi–Yau over Z; -
• the coefficients of B belong to
$\Lambda $
; -
• the b-nef divisor
$p\mathbf {M}$
is Cartier where it descends; -
• the b-nef divisor
$\mathbf {M}$
is
$\mathbb {Q}$
-trivial on the general fiber of
$X\rightarrow Z$
; -
• every generalized log canonical center of
$(X,B,\mathbf {M})$
is a log canonical center of
$(X,B)$
; and -
• every log canonical center of
$(X,B)$
dominates Z.
Then, we can write
$$\begin{align*}q(K_X+B+{\mathbf{M}_{X}}) \sim q\pi^*(K_Z+B_Z+{\mathbf{N}_{Z}}), \end{align*}$$
where the following conditions hold:
-
•
$B_Z$
is the discriminant part of the adjunction for
$(X,B,\mathbf {M})$
over Z; -
• the coefficients of
$B_Z$
belong to
$\Omega $
; and -
• the b-nef divisor
$q\mathbf {N}$
is b-Cartier.
1.8 Kawamata log terminal singularities
Finally, we show some applications of the previous theorems of this article to the study of klt singularities. We obtain the following result about klt singularities of absolute coregularity
$0$
.
Theorem 9. Let
$(X;x)$
be a klt singularity of absolute coregularity
$0$
. Then, there exists a boundary
$\Gamma $
through x satisfying the following conditions:
-
• we have that
$2(K_X+\Gamma )\sim 0$
on a neighborhood of x; -
• the coregularity of
$(X,\Gamma )$
at x is equal to
$0$
.
In particular, the pair
$(X,\Gamma ;x)$
is strictly log canonical at x.
Analogously, we obtain a similar result in the context of klt singularities of absolute coregularity
$1$
.
Theorem 10. Let
$(X;x)$
be a klt singularity of absolute coregularity
$1$
. Then, there exists a boundary
$\Gamma $
through x satisfying the following conditions:
-
• we have that
$N(K_X+\Gamma )\sim 0$
for some
$N\in \{1,2,3,4,6\}$
; -
• the coregularity of
$(X,\Gamma )$
at x is equal to
$1$
.
In particular, the pair
$(X,\Gamma ;x)$
is strictly log canonical at x.
The two previous theorems generalize the
$A,D,E$
-type classification of klt surface singularities to higher-dimensional klt singularities. The A-type klt surface singularities are the toric surface singularities. In the Gorenstein case, these are the
$A_n$
-singularities. The A-type singularities are the klt surface singularities of absolute coregularity
$0$
that admit a
$1$
-complement. The D-type klt surface singularities are quotients of toric singularities via an involution. In the Gorenstein case, these are
$D_n$
-singularities. The D-type singularities are the surface singularities of absolute coregularity
$0$
that admit a
$2$
-complement but no
$1$
-complement. The E-type klt surface singularities are the exceptional surface singularities. In the Gorenstein case, these are exactly the
$E_6$
,
$E_7$
and
$E_8$
singularities. These are the klt surface singularities that have absolute coregularity
$1$
. They admit a
$3$
-,
$4$
- or
$6$
-complement but not a
$1$
-complement or
$2$
-complement. The aforementioned results about complements and coregularity of two-dimensional klt singularities are proved in [Reference Moraga35, Section 3.2].
1.9 On the techniques of the article
The theory of complements was introduced by Shokurov in the early 2000s (see, e.g., [Reference Shokurov40]), although these objects already appeared in the work of Keel and McKernan on quasi-projective surfaces [Reference Kollár, Mori, Clemens and Corti30]. In this work, complements were called tigers. Since then, it has been understood that vanishing theorems, the canonical bundle formula and the minimal model program are indispensable tools to produce complements on a variety (see, e.g., [Reference Prokhorov and Shokurov38, Reference Petersen and Süss37, Reference Kollár, Mori, Clemens and Corti30]). Using the aforementioned techniques, the language of generalized pairs and the boundedness of exceptional Fano varieties, Birkar proved the boundedness of complements for Fano varieties [Reference Birkar3]. Since then, the theory of complements has been expanded to Fano pairs with more general coefficients [Reference Filipazzi and Moraga14, Reference Han, Liu and Shokurov24, Reference Shokurov41], to log canonical Fano varieties [Reference Xu44] and to log Calabi–Yau
$3$
-folds [Reference Filipazzi, Moraga and Xu15]. In this article, we study the theory of complements through the lens of the coregularity. The techniques are similar to the ones in the aforementioned papers. However, in order to obtain novel results, we need to re-prove several parts of this theory keeping track of this new invariant. The fact that our results are independent of dimension imposes an extra difficulty. At the same time, we will need to use some recent results regarding the coregularity and its connections to singularities [Reference Figueroa, Moraga and Peng10] and Calabi–Yau pairs [Reference Filipazzi, Mauri and Moraga13].
Strategy of the proof
In this section, we give a sketch of the proof of the main theorems of this article, namely Theorem 6, Theorem 7 and Theorem 8. The other theorems will be obtained using the same strategy and an analysis of the coefficients throughout the proof. We write Theorem
$X(c)$
for Theorem X in coregularity at most c. Theorem 6
$(0)$
follows from [Reference Filipazzi, Mauri and Moraga13, Theorem 1], while Theorem 8
$(0)$
is trivial. We will prove the following four statements:
We write Theorem
$X(d,c)$
for Theorem X in dimension at most d and coregularity at most c. For instance, Theorem 7
$(d,c)$
is known by [Reference Birkar3, Theorem 1.7]. Thus, we may write
$N(\Lambda ,d,c,p)$
for the positive integer provided by Theorem 7
$(d,c)$
. We may suppress
$\Lambda $
and p from the notation whenever they are clear from the context. Our aim is to show that, once we fix c, there is an upper bound
$N(c)$
for all
$N(d,c)$
. Similarly, Theorem 8
$(d,c)$
is known due to [Reference Birkar3, Proposition 6.3]. We write
$q(d,c)$
for the constant provided by Theorem 8
$(d,c)$
, and we show that
$q(d,c)$
is bounded above by a constant only depending on c. Theorem 6
$(d,c)$
is not known even if we fix the dimension. In this case, the aim is twofold: to prove the existence of an upper bound
$I(d,c)$
for fixed dimension d and to show that all the
$I(d,c)$
are bounded above in terms of c. The proof of implication (i) is similar to that of (iv). In the following three subsections, we sketch the proofs of (ii), (iii) and (iv).
A canonical bundle formula
Let
$(X,B,\mathbf {M})\rightarrow Z$
be as in the setting of Theorem 8
$(d,c)$
.
First, we show that for every
$z\in Z$
closed, we may find a relative
$N(c-1)$
-complement for
$(X,B,\mathbf {M})$
over z. We pick an effective Cartier divisor E on Z through z. We let t be the largest positive number for which
$(X,B+t\pi ^*E,\mathbf {M})$
has generalized log canonical singularities around z. By the connectedness theorem, the coregularity of
$(X,B+t\pi ^*E,\mathbf {M})$
is at most
$c-1$
. Indeed, since all the generalized log canonical centers of
$(X,B,\mathbf {M})$
are horizontal over Z, introducing a vertical generalized log canonical center will strictly decrease the coregularity. Taking a dlt modification of
$(X,B+t\pi ^*E,\mathbf {M})$
, we can produce a new generalized pair
$(X',B',\mathbf {M})$
such that z is contained in the image of a component S of
$\lfloor B'\rfloor $
. By perturbing the coefficients, we may assume that the coefficients of
$B'$
belong to
$\Lambda $
. We replace
$(X,B,\mathbf {M})$
by
$(X',B',\mathbf {M})$
and assume there is a vertical divisorial log canonical center S. Notice that this replacement changes the crepant birational class of the original generalized pair
$(X,B,\mathbf {M})$
in order to create a new log canonical center. Running a suitable Minimal Model Program (MMP) over Z, we reduce to the case in which
$S\rightarrow \pi (S)\ni z$
is a Fano type morphism. The generalized pair
$(S,B_S,{\mathbf {M}_{S}})$
obtained by adjunction of
$(X,B,\mathbf {M})$
to S has dimension at most
$d-1$
and coregularity at most
$c-1$
. If
$q(S)=z$
, then we may apply Theorem 7
$(d-1,c-1)$
to conclude that
$(S,B_S,{\mathbf {M}_{S}})$
admits an
$N(d-1,c-1)$
-complement. Since we are assuming Theorem 7
$(c-1)$
, this is also an
$N(c-1)$
-complement. If
$\dim \pi (S)\geq 1$
, then we construct an
$N(c-1)$
-complement by induction on the dimension. In any case, we obtain an
$N(c-1)$
-complement for
$(S,B_S,{\mathbf {M}_{S}})$
around z. Using Kawamata–Viehweg vanishing, we lift such complement to an
$N(c-1)$
-complement for
$(X,B,\mathbf {M})$
around the fiber of
$z\in Z$
. The details of this proof can be found in § 5, where we discuss relative complements. In § 5.1, we explain how to lift complements from divisors.
Now, we can assume the existence of bounded relative
$N(c-1)$
-complements for
$(X,B,\mathbf {M})\rightarrow Z$
. The existence of bounded relative complements allows us to find q in the statement of Theorem 8
$(d,c)$
. Indeed, we can take
$q(d,c)=N(c-1)$
. The main difficulty is to control the coefficients of
${\mathbf {N}_{Z}}$
in the model where it descends. In order to do so, we will cut the base with hypersurfaces to reduce to the case in which the base is a curve. Once the base is a curve C, we will study the coefficients of a relative complement over a closed point
$c\in C$
. Analyzing the coefficients of this relative complement will show that
$q{\mathbf {N}_{Z}}$
is integral. A similar argument on a suitable resolution
$Z'\rightarrow Z$
proves that
$q{\mathbf {N}_{Z'}}$
is integral, where
$Z'$
is a model on which
${\mathbf {N}_{Z}}$
descends. This finishes the proof of Theorem 8
$(c)$
using Theorem 7
$(c-1)$
. The details of this proof are given in § 6.
Index of log Calabi–Yau pairs
Let
$(X,B,\mathbf {M})$
be a generalized log Calabi–Yau pair as in Theorem 6
$(d,c)$
. By [Reference Figueroa, Moraga and Peng10, Theorem 2], we may assume that the set
$\Lambda $
in the statement of the theorem is finite. By [Reference Filipazzi and Svaldi16, Theorem 4.2], we can replace
$(X,B,\mathbf {M})$
by a Kollár–Xu model (see § 2.7). We have a Fano type contraction
$q\colon X\rightarrow Z$
such that all the generalized log canonical centers of
$(X,B,\mathbf {M})$
dominate the base Z. Both the index and Weil index of
$K_X+B+{\mathbf {M}_{X}}$
are preserved by the Kollár–Xu model. We will proceed with the proof in three different cases, depending on the dimension of the base of the Kollár–Xu model and the coefficient sets of B and
$\mathbf {M}$
. We argue by induction on the dimension d of X. The base of the induction is the klt case which follows by Conjecture 1 (see, e.g., Lemma 2.30).
Case 1: the moduli part
$\mathbf {M}=0$
.
In this case, we know that
$K_X+B\sim _{\mathbb {Q}} 0$
. We do not assume that X is rationally connected. We choose a component S of
$\lfloor B\rfloor $
and run a
$(K_X+B-\epsilon S)$
-MMP. This minimal model program terminates with a Mori fiber space on which S is ample over the base. Observe that the variety S may not be normal. However, the pair obtained by adjunction
$(S,B_S)$
is semilog canonical. In § 4, we show that the statement of Theorem 6
$(d-1,c)$
holds for semilog canonical pairs provided it holds for log canonical pairs. To do so, we use Conjecture 1 and Conjecture 2 in dimension c. Here, it is crucial that we work with pairs instead of generalized pairs. Indeed, Conjecture 2 is not known for generalized pairs, even in dimension
$2$
. Hence, we conclude that
$I(\Lambda ,d-1,c,0)(K_S+B_S)\sim 0$
.
Thus, in this case, we conclude that the index of
$(X,B)$
is at most
$I(\Lambda ,d-1,c,0)$
.
Case 2: the base Z of the Kollár–Xu model is positive-dimensional, the divisor
$\{B\}+{\mathbf {M}_{X}}$
is trivial on the general fiber of
$X\to Z$
and the b-nef divisor
$\mathbf {M}$
is nontrivial.
In this case, we apply Theorem 8
$(c)$
. We can write
$$ \begin{align} q(K_X+B+{\mathbf{M}_{X}}) \sim q \pi^*(K_Z+B_Z+{\mathbf{N}_{Z}}). \end{align} $$
The variety Z has dimension at most c. The integer q only depends on
$\Lambda ,c$
and p. The coefficients of
$B_Z$
belong to a DCC set that only depends on
$\Lambda ,c$
and p. The b-nef divisor
$q\mathbf {N}$
is b-Cartier. The variety X is rationally connected, as we are assuming that the b-nef divisor
$\mathbf {M}$
is nontrivial. Hence, Z is also rationally connected. Let
$Z'\rightarrow Z$
be the model where
${\mathbf {N}_{Z}}$
descends. In particular,
$Z'$
is rationally connected. Note that in general,
${\mathbf {N}_{Z'}}$
may have torsion components. However, since
$Z'$
is rationally connected, the q-th multiple of such torsion components are linearly equivalent to zero (see [Reference Filipazzi, Mauri and Moraga13, Corollary 3.9]). Using Conjecture 1, we will show that the index of
$K_Z+B_Z+{\mathbf {N}_{Z}}$
only depends on
$\Lambda ,c$
and p. Thus, by the linear equivalence (1.1), we conclude that the index of
$(X,B,\mathbf {M})$
is bounded above by a constant
$I_0(\Lambda ,c,p)$
.
Case 3: the divisor
$\{B\}+{\mathbf {M}_{X}}$
is nontrivial on the general fiber of
$X\rightarrow Z$
and the b-nef divisor
$\mathbf {M}$
is nontrivial.
We run a
$(K_X+\lfloor B\rfloor )$
-MMP over Z. Since
$K_X+\lfloor B\rfloor $
is not pseudo-effective over Z, this minimal model program terminates with a Mori fiber space
$p\colon X'\rightarrow W$
over Z. We denote by
$B'$
the push-forward of B on
$X'$
. the divisor
$K_{X'}+\lfloor B'\rfloor $
is antiample over W. Since
$\lfloor B\rfloor $
is big over Z, the divisor
$\lfloor B'\rfloor $
has a component S that dominates W. By construction, the general fibers of
$S\rightarrow W$
are of Fano type. In this case, X and
$X'$
are rationally connected, as we are assuming that the b-nef divisor
$\mathbf {M}$
is nontrivial. Hence, the image W of
$X'$
is rationally connected. Since a general fiber of
$S\rightarrow W$
is of Fano type, they are rationally connected. Thus, S is rationally connected, being the base and general fibers of
$S\rightarrow W$
rationally connected. In particular, if
$(S,B_S+{\mathbf {M}_{S}})$
is the generalized pair obtained by adjunction, then we know that
$I(\Lambda ,d-1,c,p)(K_S+B_S+{\mathbf {M}_{S}})\sim 0$
. Here, we argued by induction on the dimension and used Theorem 6
$(d-1,c)$
. Depending on the dimension of W, we either use Kawamata–Viehweg vanishing or Kollár’s torsion-free theorem to conclude that
$I(\Lambda ,d-1,c,p)(K_{X'}+B'+{\mathbf {M}_{X'}})\sim 0$
. Hence, the index of
$(X,B,\mathbf {M})$
is at most
$I(\Lambda ,d-1,c,p)$
. These lifting arguments are explained in § 5.1.
In summary, a generalized log Calabi–Yau pair
$(X,B,\mathbf {M})$
as in Theorem 6
$(d,c)$
has index at most
$$\begin{align*}\max\{I_0(\Lambda,c,p),I(\Lambda,d-1,c,p),I(\Lambda,d-1,c,0)\}. \end{align*}$$
Thus, we have that
$$\begin{align*}I(\Lambda,d,c,p) \leq \max\{I_0(\Lambda,c,p),I(\Lambda,d-1,c,p),I(\Lambda,d-1,c,0)\}. \end{align*}$$
Hence, there is an upper bound for
$I(\Lambda ,d,c,p)$
which only depends on
$\Lambda ,c$
and p. This finishes the sketch of the proof of Theorem 6
$(c)$
using Theorem 8
$(c)$
.
Complements on Fano varieties
Let
$(X,B,\mathbf {M})$
be a Fano type pair as in Theorem 7
$(d,c)$
. In § 3, we reduce to the case in which
$\Lambda $
finite. This is crucial for lifting complements from divisors (see § 5.1). By the assumption on the absolute coregularity of
$(X,B,\mathbf {M})$
, we may find a generalized log Calabi–Yau structure
$(X,B+\Gamma ,\mathbf {M})$
of coregularity c. By dimensional reasons and the assumption on the absolute coregularity of
$(X,B,\mathbf {M})$
,
$(X,B+\Gamma ,\mathbf {M})$
may be generalized klt only if
$d = c$
and
$(X,B,\mathbf {M})$
is exceptional; this case is settled by [Reference Birkar3, Theorem 1.7] in dimension c. Therefore, in the rest of this sketch, we may assume that
$(X,B+\Gamma ,\mathbf {M})$
is not generalized klt. Let
$(Y,B_Y+\Gamma _Y+E,\mathbf {M})$
be a dlt modification of
$(X,B+\Gamma ,\mathbf {M})$
. Here,
$B_Y$
(resp.
$\Gamma _Y$
) is the strict transform of the fractional part of B (resp.
$\Gamma $
), while we set
$E=\lfloor B_Y+\Gamma _Y+E \rfloor $
. Since
$(X,B+\Gamma ,\mathbf {M})$
is not generalized klt, we have
$E \neq 0$
. Since X is of Fano type, it easily follows that so is Y. In particular, Y is a Mori dream space. We run a
$-(K_Y+B_Y+E+{\mathbf {M}_{Y}})$
-MMP. Note that
$-(K_Y+B_Y+E+{\mathbf {M}_{Y}})$
is a pseudo-effective divisor. Hence, this minimal model program must terminate with a good minimal model Z. We let
$B_Z$
and
$E_Z$
be the push-forwards to Z of
$B_Y$
and E, respectively. In order to produce a complement for
$(X,B)$
, it suffices to produce a complement for
$(Z,B_Z+E_Z,{\mathbf {M}_{Z}})$
. Replacing
$(X,B,\mathbf {M})$
by
$(Z,B_Z+E_Z,{\mathbf {M}_{Z}})$
, we may assume that
$-(K_X+B+{\mathbf {M}_{X}})$
is semiample and
$\mathrm {coreg}(X,B,\mathbf {M})=c$
. Notice that this reduction does not alter the coefficients set for the boundary part of
$(X,B,\mathbf {M})$
, since the only divisors that may have been introduced in the boundary have coefficient 1. Furthermore, by the choice of the MMP run, it follows that E cannot be contracted. In particular, after this reduction, we may assume that
$\lfloor B \rfloor \neq 0$
. We will proceed in three different cases depending on the dimension of the ample model W of the divisor
$-(K_X+B+{\mathbf {M}_{X}})$
.
Case 1: the dimension of W is
$0$
.
In this case, we have that
$K_X+B+{\mathbf {M}_{X}}\sim _{\mathbb {Q}} 0$
. Hence, producing a complement for
$(X,B,\mathbf {M})$
is the same as controlling the index of the generalized pair. Thus, the statement follows from Theorem 6
$(c)$
.
Case 2: the dimension of W is d.
In this case, we have that
$-(K_X+B+{\mathbf {M}_{X}})$
is semiample and big. Furthermore, the round-down
$\lfloor B\rfloor $
is nontrivial. We pass to a suitable birational model of
$(X,B,\mathbf {M})$
where a component S of
$\lfloor B\rfloor $
is of Fano type. Performing adjunction to S, we obtain a log Fano pair of dimension
$d-1$
and coregularity c. Using Theorem 7
$(d-1,c)$
, we produce an
$N(\Lambda ,d-1,c,p)$
-complement on S that can be lifted to an
$N(\Lambda ,d-1,c,p)$
-complement of
$(X,B)$
.
Case 3: The dimension of W is positive and strictly less than d.
The fibration
$\pi \colon (X,B,\mathbf {M})\rightarrow W$
is a log Calabi–Yau fibration for
$(X,B,\mathbf {M})$
. If
$\{B\}+\mathbf {M}$
is big over W, then by perturbing the coefficients of B we reduce to Case 2. Otherwise, we may replace W with the ample model of
$\{B\}+\mathbf {M}$
over W. Doing so, we may assume
$\{B\}+\mathbf {M}$
is trivial on the general fiber of
$X\rightarrow W$
. If all the generalized log canonical centers of
$(X,B)$
dominate W, then we are in the situation of Theorem 8
$(c)$
. The generalized pair
$(W,B_W,{\mathbf {N}_{W}})$
induced on the base is of Fano type and exceptional. By [Reference Birkar3, Theorem 1.7] in dimension c or less, we can find an
$N(\Omega ,c)$
-complement for
$(W,B_W,{\mathbf {N}_{W}})$
. Here,
$\Omega $
only depends on
$\Lambda ,c$
and p. Then, we can pull the complement back via
$\pi $
to obtain an
$N(\Omega ,c)$
-complement for
$(X,B,\mathbf {M})$
. Finally, we may assume that
$\{B\}+\mathbf {M}$
is trivial on the general fiber of
$X\rightarrow W$
and there is some component
$S\subset \lfloor B\rfloor $
that is vertical over W. In this case,
$B_{\mathrm {hor}}$
is big over W. Here,
$B_{\mathrm {hor}}$
stands for the sum of the components of B which are horizontal over W. Again, we can perturb the coefficients of B to reduce to Case 2.
In summary, a generalized pair
$(X,B,\mathbf {M})$
as in Theorem 7
$(d,c)$
admits an N-complement, where
$N\leq \max \{N(\Omega ,c),N(\Lambda ,d-1,c,p)\}$
. Thus, we have
$$\begin{align*}N(\Lambda,d,c,p)\leq \max\{N(\Omega,c),N(\Lambda,d-1,c,p)\}. \end{align*}$$
Hence, there is an upper bound for
$N(\Lambda ,d,c,p)$
which only depends on
$\Lambda ,c$
and p. This finishes the proof of Theorem 7
$(c)$
using Theorem 6
$(c)$
and Theorem 8
$(c)$
.
2 Preliminaries
We work over an algebraically closed field
$\mathbb {K}$
of characteristic zero. Our varieties are connected and quasi-projective unless otherwise stated. In this section, we introduce some preliminaries regarding singularities, Fano varieties, Calabi–Yau pairs and coregularity.
2.1 Divisors, b-divisors and generalized pairs
In this subsection, we recall some basics about b-divisors and generalized pairs.
Definition 2.1. Let X be a normal variety. A b-divisor
$\mathbf {M}$
on X is a function which associates any birational map
$X'\dashrightarrow X$
with an
$\mathbb {R}$
-divisor
${\mathbf {M}_{X'}}$
on
$X'$
. The set of divisors
$\{{\mathbf {M}_{X'}} \colon X'\dashrightarrow X\}$
satisfies the following compatibility condition: If
$g \colon X_1\to X_2$
is a birational morphism over X, then
$g_*{\mathbf {M}_{X_1}} = {\mathbf {M}_{X_2}}$
. We say that a b-divisor
$\mathbf {M}$
on X descends on some birational model
$X'$
of X if
${\mathbf {M}_{X'}}$
is
$\mathbb {R}$
-Cartier and
$\mathbf {M}$
is equivalent to
$( X'\to X, {\mathbf {M}_{X'}})$
. In other words, for any birational map
$h \colon Y\to X'$
over X, we have
$h^*{\mathbf {M}_{X'}} = {\mathbf {M}_{Y}}$
. In the previous case, we say that
$\mathbf {M}$
is a b-
$\mathbb {R}$
-Cartier divisor.
Let
$X\to Z$
be a projective morphism. The b-divisor
$\mathbf {M}$
is said to be b-Cartier (resp. b-nef, b-nef/ Z) if
${\mathbf {M}_{X'}}$
is Cartier (resp. nef, relatively nef over Z) on some birational model
$X'$
over X where
$\mathbf {M}$
descends.
The b-Cartier closure of an
$\mathbb {R}$
-Cartier divisor M is a b-divisor
$\mathbf {M}$
whose trace on every birational model
$f:Y\rightarrow X$
is
$f^*M$
.
Definition 2.2. Let X be a normal variety and
$\pi \colon X\to Z$
be a projective morphism. A generalized pair on X over Z is a triple
$(X,B,\mathbf {M})$
where
-
• B is an effective
$\mathbb {R}$
-divisor on X; -
•
$\mathbf {M}$
is a b-nef/Z b-
$\mathbb {R}$
-Cartier on X; and -
•
$K_X+B+{\mathbf {M}_{X}}$
is
$\mathbb {R}$
-Cartier.
When Z is a point, we simply call
$(X,B,\mathbf {M})$
a generalized pair.
2.2 Singularities of generalized pairs
In this subsection, we define the notions of singularities for generalized pairs.
Definition 2.3. Let X be a normal variety and
$(X,B,\mathbf {M})$
be a generalized pair on X. Let D be a divisor over X. Pick a log resolution
$f \colon X'\to X$
of
$(X,B)$
such that D is a divisor on
$X'$
and
$\mathbf {M}$
descends on
$X'$
. We can write
$$\begin{align*}K_{X'} + B' + {\mathbf{M}_{X'}} = f^*(K_X+B+{\mathbf{M}_{X}}) \end{align*}$$
for some uniquely determined
$B'$
. Define the generalized log discrepancy
$a_D(X,B,\mathbf {M})$
to be
$1-\operatorname {\mathrm {coeff}}_D (B')$
.
We say that
$(X,B,\mathbf {M})$
is generalized log canonical (resp. generalized klt) if
$a_D(X,B,\mathbf {M})$
is nonnegative (resp. positive) for any divisor D over X. A generalized non-klt place (resp. generalized log canonical place) of
$(X,B,\mathbf {M})$
is a prime divisor D over X with
$a_D(X,B,\mathbf {M})\leq 0$
(resp.
$a_D(X,B,\mathbf {M})=0$
). A generalized non-klt center of
$(X,B,\mathbf {M})$
is the image of a generalized non-klt place. We denote the set of generalized non-klt centers of
$(X,B,\mathbf {M})$
by
$\mathrm {Nklt}(X,B,\mathbf {M})$
. A generalized log canonical center of
$(X,B,\mathbf {M})$
is the image Z of a generalized non-klt place such that every generalized non-klt place whose image on X contains Z is a generalized log canonical place.
We say that
$(X,B,\mathbf {M})$
is generalized dlt if it is generalized log canonical and satisfies the following condition: for any generalized log canonical center V of
$(X,B,\mathbf {M})$
, the pair
$(X,B)$
is log smooth around the generic point of V and
$\mathbf {M}$
descends on X in a neighborhood of the generic point of V. We say that
$(X,B,\mathbf {M})$
is generalized plt if it is generalized dlt and every connected component of
$\lfloor B\rfloor $
is irreducible.
Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over a base Z. Let
$f \colon Y\to X$
be a birational morphism and write
$$\begin{align*}K_{Y} + B_Y + {\mathbf{M}_{Y}} = f^*(K_X+B+{\mathbf{M}_{X}}). \end{align*}$$
We say that
$(Y,B_Y,\mathbf {M})$
is a
$\mathbb {Q}$
-factorial generalized dlt modification of
$(X,B,\mathbf {M})$
if the variety Y is
$\mathbb {Q}$
-factorial,
$(Y,B_Y,\mathbf {M})$
is generalized dlt and every f-exceptional divisor appears in
$B_Y$
with coefficient 1.
Lemma 2.4 [Reference Filipazzi and Svaldi16, Theorem 2.9].
Every generalized log canonical pair over a base Z has a
$\mathbb {Q}$
-factorial generalized dlt modification.
The following lemma states that the singularities of the pair
$(X,B)$
are milder than the singularities of
$(X,B,\mathbf {M})$
.
Lemma 2.5 [Reference Birkar and Zhang7, Remark 4.2.(3)].
Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z. Suppose
$K_X+B$
is
$\mathbb {R}$
-Cartier. Then for any divisor D over X, the log discrepancies satisfy
$$\begin{align*}a_D(X,B,\mathbf{M}) \leq a_D(X,B).\end{align*}$$
In particular, the pair
$(X,B)$
is log canonical.
2.3 Crepant birational maps
In this subsection, we recall the notion of crepant birational map and group of crepant birational automorphisms.
Definition 2.6. Let
$(X_1,B_1,\mathbf {M})$
and
$(X_2,B_2,\mathbf {M})$
be generalized pairs over Z. We say that they are crepant if there exists a common resolution
$\alpha _1 \colon X' \rightarrow X_1$
and
$\alpha _2 \colon X' \rightarrow X_2$
, where each
$\alpha _i$
is proper, such that
$$ \begin{align*}{K_{X'}} + B^{\prime}_1 + {\mathbf{M}_{X'}} = {K_{X'}} + B^{\prime}_2 + {\mathbf{M}_{X'}}, \end{align*} $$
holds, where we have
${K_{X'}} + B^{\prime }_i + {\mathbf {M}_{X'}}= \alpha _i^*({K_{X_i}} + B_i + {\mathbf {M}_{X_i}})$
for
$i=1,2$
.
In the case of pairs, we recall the notion of B-birational map, originally due to Fujino [Reference Fujino17, Definition 1.5]. Observe that, for our purposes in later sections, it is important to deal with possibly reducible varieties.
Definition 2.7. Let
$(X,\Delta ) = \sqcup (X_i,\Delta _i)$
and
$(X',\Delta ') = \sqcup (X^{\prime }_i,\Delta ^{\prime }_i)$
be possibly reducible normal pairs. We say that
$f \colon X \dashrightarrow X'$
is a B-birational map if
$(X,\Delta )$
and
$(X',\Delta ')$
are crepant. That is, X and
$X'$
have the same number of irreducible components, and there exists a permutation
$\sigma $
of the index set of the irreducible component such that, for every i, the restriction
$f_i \colon X_i \dashrightarrow X^{\prime }_{\sigma (i)}$
is birational and
$(X_i,\Delta _i)$
is crepant to
$(X^{\prime }_{\sigma (i)},\Delta ^{\prime }_{\sigma (i)})$
.
Definition 2.8. Given a pair
$(X,\Delta )=\sqcup (X_i,\Delta _i)$
as in Definition 2.7, we define
The set
$\mathrm {Bir}(X,\Delta )$
forms a group under composition.
We observe that Definition 2.7 and Definition 2.8 naturally extend to the case of generalized pairs.
2.4 Complements
In this subsection, we introduce the notion of relative complements.
Definition 2.9. A contraction is a projective morphism of quasi-projective varieties
$f \colon X \rightarrow Z$
such that
$f_* {\mathcal {O}_{X}}={\mathcal {O}_{Z}}$
. Notice that, if X is normal, then so is Z. A fibration is a contraction
$X \rightarrow Z$
such that
$\dim Z < \dim X$
.
Definition 2.10. Let
$(X,B)$
be a pair and
$X\to Z$
a contraction. We say that a pair
$(X,B)$
is log Fano (resp. weak log Fano or log Calabi–Yau) over Z if it is log canonical and
$-(K_X+B)$
is ample over Z (resp.
$-(K_X+B)$
is nef and big over Z or
$K_X+B$
is
$\mathbb {R}$
-trivial over Z).
We say that
$(X,B)$
is of Fano type (resp. log Calabi–Yau type) over Z if
$(X,B+\Delta )$
is klt and weak log Fano (resp. log Calabi–Yau) for some choice of
$\Delta \geq 0$
.
If
$(X,0)$
is of Fano type (resp. log Calabi–Yau type) over Z, we say that
$X\to Z$
is a Fano type morphism (resp. log Calabi–Yau type morphism). If
$(X,B)$
is log Fano (resp. log Calabi–Yau, Fano type, Calabi–Yau type) over a point, we simply say that
$(X,B)$
is log Fano (resp. log Calabi–Yau, Fano type, Calabi–Yau type).
Definition 2.11. Let
$X\to Z$
be a contraction and
$(X,B,\mathbf {M})$
be a generalized pair over Z. Let N be a positive integer. An N-complement of
$K_X+B+{\mathbf {M}_{X}}$
over a point
$z\in Z$
is a divisor
$K_X+B^++{\mathbf {M}_{X}}$
such that over some neighborhood of z, we have:
-
•
$(X,B^+,\mathbf {M})$
is generalized log canonical; -
•
$N(K_X+B^++{\mathbf {M}_{X}})\sim _Z 0$
; -
•
$N\mathbf {M}$
is b-Cartier; and -
•
$B^+\geq B$
.
If the above conditions hold for
$K_X+B^++{\mathbf {M}_{X}}$
over every
$z\in Z$
, we say that
$K_X+B^++{\mathbf {M}_{X}}$
is an N-complement of
$K_X+B+{\mathbf {M}_{X}}$
over Z. We say that
$K_X+B^+ + {\mathbf {M}_{X}}$
is a
$\mathbb {Q}$
-complement of
$K_X+B+{\mathbf {M}_{X}}$
over
$z\in Z$
(resp.
$\mathbb {Q}$
-complement of
$K_X+B+{\mathbf {M}_{X}}$
over Z) it is a q-complement for some
$q\in \mathbb {Z}_{>0}$
.
The following lemma states that complements can be pulled back via
$K_X$
-positive birational contractions (see [Reference Birkar3, 6.1.(3)]).
Lemma 2.12. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over a base Z. Suppose
$f \colon X\dashrightarrow X'$
is a
$(K_X+B+{\mathbf {M}_{X}})$
-nonnegative birational contraction over Z. Let
$B'=f_*B$
and N be a positive integer. If
$K_{X'}+B'+{\mathbf {M}_{X'}}$
has an N-complement over
$z\in Z$
, then
$K_X+B+{\mathbf {M}_{X}}$
also has an N-complement over
$z\in Z$
.
The following lemma says that extracting divisors with small log discrepancy from a Fano type variety preserves the Fano type property (see [Reference Birkar3, 6.13.(7)]).
Lemma 2.13. Let
$X\rightarrow Z$
be a contraction. Let X be a Fano type variety over Z and
$(X,B)$
a log Calabi–Yau pair over Z. Let
$f\colon Y\rightarrow X$
be a birational morphism. Suppose that every f-exceptional divisor E satisfies
$a_E(X,B)<1$
. Then Y is of Fano type over Z.
Furthermore, let
$K_Y+B_Y$
be the log pull-back of
$K_X+B$
. If
$K_Y+B_Y$
has an N-complement over
$z\in Z$
, then
$(X,B)$
also has an N-complement over
$z\in Z$
.
2.5 Coefficients under adjunction
In this subsection, we study the coefficients of a pair under adjunction.
Definition 2.14. Let
$\mathcal {R}$
be a set of rational numbers. We define
$I_{\mathcal {R}}$
to be the minimal integer I such that for any
$r\in R$
and
$n \in \mathbb {N}$
, we have that
$$ \begin{align*}\lfloor nI r \rfloor \geq n(I-1) r.\end{align*} $$
If there does not exist such an integer, we define
$I_{\mathcal {R}}$
to be
$0$
.
Note that when the set
$\mathcal {R}$
is finite
$I_{\mathcal {R}}$
exists as the least common multiple of the denominators will satisfy the previous inequality. When
$\mathcal {R}$
is the set of standard coefficients
$I_{\mathcal {R}}$
=1. If
$\mathcal {R}$
is finite, then
$I_{\mathcal {R}}$
is bounded above by the least common multiple of the rational numbers in
$\mathcal {R}$
that are not standard.
Definition 2.15. Let
$\Lambda $
be a set of real numbers in
$[0,1]$
. Define the derived set of
$\Lambda $
as
We also define
$D_{\lambda _0}(\Lambda )\subset D(\Lambda )$
to be the subset in which, in the definition of a, at least one
$\lambda _i$
is equal to
$\lambda _0$
. The set
$\Lambda $
is said to be derived if
$\Lambda =D(\Lambda )$
. If
$\lambda $
is a positive integer, then we set 
.
For instance, the set of standard coefficients 
is derived. The following lemmata describe some properties of derived sets.
Lemma 2.16 [Reference Hacon and Xu22, Proposition 3.4.1].
Let
$\Lambda $
be a set of real numbers in
$[0,1]$
. Then
$D(\Lambda ) = D(D(\Lambda ))$
, that is,
$D(\Lambda )$
is a derived set.
The following lemma allows us to control the coefficients of the generalized pairs obtained by divisorial adjunction. The lemma is a special case of [Reference Birkar3, Lemma 3.3]; we refer to the proof of [Reference Filipazzi, Mauri and Moraga13, Lemma 3.8] for the details of this adaptation.
Lemma 2.17 [Reference Birkar3, Lemma 3.3].
Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z and
$\Lambda $
be a set of rational numbers in
$[0,1]$
. Suppose the coefficients of B and
${\mathbf {M}_{X'}}$
belong to
$\Lambda $
for some model
$X'$
where
$\mathbf {M}$
descends. Let S be the normalization of a component of
$\lfloor B\rfloor $
. Write
$$\begin{align*}(K_X+B+{\mathbf{M}_{X}})|_S\sim K_S+B_S+{\mathbf{N}_{S}}\end{align*}$$
for the generalized adjunction on S, where
$B_S$
is the boundary part and
$\mathbf {N}$
the moduli part. Then the coefficients of
$B_S$
and
${\mathbf {N}_{S'}}$
belong to the derived set
$D(\Lambda )$
for some model
$S'$
where
$\mathbf {N}$
descends.
The following lemma is used in the proof of Theorem 6.1 to control the coefficients of the discriminant part of a log Calabi–Yau fibration over a curve.
Lemma 2.18. Let q be a positive integer. Let
$\Lambda $
be a set of nonnegative rational numbers. Suppose
$\Lambda $
satisfies the DCC and has rational accumulation points. Then the set
satisfies the ascending chain condition and has rational accumulation points.
Proof. We first show that
$\Sigma _q$
satisfies the ascending chain condition. Suppose in
$\Sigma _q$
we can find an increasing sequence
$$\begin{align*}\frac{b_1^+-b_1}{m_1} < \frac{b_2^+-b_2}{m_2} < \cdots < \frac{b_k^+-b_k}{m_k} < \cdots \end{align*}$$
Since
$b_k^+ \in \{i/q \colon 0\leq i\leq q\}$
has only finitely many choices, we may assume, by passing to a subsequence, that all
$b_k^+$
are the same and equal to the number
$b^+$
. Furthermore, note that
$$\begin{align*}m_k < \frac{m_1(b_k^+-b_k)}{b_1^+-b_1} \leq \frac{m_1}{b^+-b_1}. \end{align*}$$
The second inequality holds as
$1\geq b_k^+ \geq b_k^+-b_k$
. Hence, the sequence
$m_k$
is bounded above. Thus, by passing to a subsequence we may assume that
$m_k = m$
for all k. Now, we obtain a decreasing sequence
$$\begin{align*}b_1> b_2 > \cdots > b_k > \cdots, \end{align*}$$
which violates the descending chain condition of
$\Lambda $
. Thus,
$\Sigma _q$
satisfies the ascending chain condition.
Let
$a\neq 0$
be an accumulation point of
$\Sigma _q$
. Since
$\Sigma _q$
satisfies the ascending chain condition, we may find a sequence
$$\begin{align*}\frac{b_1^+-b_1}{m_1} \geq \frac{b_2^+-b_2}{m_2} \geq \cdots \geq \frac{b_k^+-b_k}{m_k} \geq \cdots \end{align*}$$
whose limit is a. We may assume that
$b_k^+ = b^+$
for all k. Then
$$\begin{align*}m_k \leq \frac{b_k^+-b_k}{a} \leq \frac{1}{a}. \end{align*}$$
The second inequality holds as
$1\geq b_k^+ \geq b_k^+-b_k$
. Hence, the sequence
$m_k$
is bounded above. By passing to a subsequence, we may assume that
$m_k = m$
for all k. Since
$\Lambda $
has rational accumulation points,
$$\begin{align*}a = \lim_{k\to \infty} \frac{b^+-b_k}{m} = \frac{b^+}{m} - \frac{1}{m} \lim_{k\to\infty} b_k \in \mathbb{Q}, \end{align*}$$
as desired.
2.6 Coregularity of pairs
In this subsection, we define the coregularity of a generalized pair and prove some of its properties.
Definition 2.19. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair. Let
$f \colon Y \to X$
be a generalized dlt modification, and write
$$\begin{align*}K_Y + B_Y + {\mathbf{M}_{Y}} = f^*(K_X+B+{\mathbf{M}_{X}}). \end{align*}$$
Let
$$\begin{align*}\lfloor B_Y\rfloor = E_1 + E_2 + \cdots + E_r\end{align*}$$
be a simple normal crossing divisor on Y.
The dual complex
$\mathcal {D}(Y,B_Y +{\mathbf {M}_{Y}})$
is a simplicial complex constructed as follows:
-
• For every
$1\leq i\leq r$
, there is a vertex
$v_i$
in
$\mathcal {D}(Y,B_Y+{\mathbf {M}_{Y}})$
corresponding to the divisor
$E_i$
. For every subset
$I\subseteq \{1,2,\ldots ,r\}$
and every irreducible component Z of
$\bigcap _{i\in I} E_i$
, there is a simplex
$v_Z$
of dimension
$\# I - 1$
corresponding to Z; -
• For every
$I\subseteq \{1,2,\ldots ,r\}$
and
$j\in I$
, there is a gluing map constructed as follows. Let
$Z\subseteq \bigcap _{i\in I} E_i$
be any irreducible component. Let W be the unique component of
$\bigcap _{i\in I\setminus \{j\}}E_i$
containing Z. Them, the gluing map is the inclusion of
$v_W$
into
$v_Z$
as the face of
$v_Z$
that does not contain the vertex
$v_i$
.
Define the dimension of
$\mathcal {D}(Y,B_Y+{\mathbf {M}_{Y}})$
to be the smallest dimension of the maximal simplex, with respect to the inclusion, of
$\mathcal {D}(Y,B_Y+{\mathbf {M}_{Y}})$
. When
$\mathcal {D}(Y,B_Y+{\mathbf {M}_{Y}}) = \varnothing $
, set its dimension to be
$-1$
.
The dual complex
$\mathcal {D}(Y,B_Y,{\mathbf {M}_{Y}})$
depends on the dlt modification Y. However, its PL-homeomorphism type is independent of the dlt modification (see, e.g., [Reference Filipazzi and Svaldi16, Theorem 1.6]).
Define the dual complex
$\mathcal {D}(X,B,\mathbf {M})$
associated to the generalized pair
$(X,B,\mathbf {M})$
as the homeomorphism type of the complex
$\mathcal {D}(Y,B_Y+{\mathbf {M}_{Y}})$
. Thus, for any dlt modification we have
$$\begin{align*}\dim \mathcal{D}(X,B,\mathbf{M})= \dim \mathcal{D}(Y,B_Y,{\mathbf{M}_{Y}}).\end{align*}$$
When
$\mathbf {M} = 0$
, we write
$\mathcal {D}(X,B)$
instead of
$\mathcal {D}(X,B,0)$
for simplicity.
Definition 2.20. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z. We define its coregularity to be
Definition 2.21. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z. We define the absolute coregularity over Z of
$(X,B,\mathbf {M})$
, denoted by
$\hat {\mathrm {coreg}}(X/Z,B,\mathbf {M})$
, as follows:
-
• if
$(X,B^+,\mathbf {M})$
is not a generalized log Calabi–Yau pair over Z for every divisor
$B^+\geq B$
, we set
$\hat {\mathrm {coreg}}(X/Z,B,\mathbf {M})$
to be
$\infty $
; -
• otherwise, we set
$\hat {\mathrm {coreg}}(X/Z,B,\mathbf {M})$
to be the smallest value of
$\mathrm {coreg}(X,B^+,\mathbf {M})$
, over all divisors
$B^+\geq B$
for which
$(X,B^+,\mathbf {M})$
is generalized log Calabi–Yau over Z.
Let
$z\in Z$
be a point. We define the absolute coregularity of
$(X,B,\mathbf {M})$
over
$z\in Z$
, denoted by
$\hat {\mathrm {coreg}}_z(X,B,\mathbf {M})$
to be the minimum of
$\hat {\mathrm {coreg}}(\pi ^{-1}(U)/U,B,\mathbf {M})$
where U runs over all neighborhoods of
$z\in Z$
.
By definition, we have that
$$\begin{align*}\hat{\mathrm{coreg}}_z(X,B,\mathbf{M}) \in \{0,\dots, \dim X, \infty\}. \end{align*}$$
If
$X\rightarrow Z$
is the structure morphism of X and
$\mathrm {coreg}(X,B,\mathbf {M})=\dim X$
, then we say that
$(X,B,\mathbf {M})$
is an exceptional generalized pair.
By the negativity lemma, the coregularity is preserved under certain MMP.
Lemma 2.22. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z. Let
$z\in Z$
be a point. Suppose
$f \colon X\dashrightarrow Y$
is a
$(K_X+B+{\mathbf {M}_{X}})$
-nonnegative birational contraction over Z. Write
$B_Y = f_*B$
. Then
$$\begin{align*}\hat{\mathrm{coreg}}_z(Y,B_Y,\mathbf{M}) = \hat{\mathrm{coreg}}_z(X,B,\mathbf{M}). \end{align*}$$
Proof. Up to shrinking Z around z, we can find a generalized log Calabi–Yau pair
$(X,B+\Gamma ,\mathbf {M})$
over Z that computes the absolute coregularity of
$(X,B,\mathbf {M})$
over z. Let
$\Gamma _Y=f_*\Gamma $
. Since
$(X,B+\Gamma ,\mathbf {M})$
is generalized log Calabi–Yau over Z, we conclude that
$(Y,B_Y+\Gamma _Y,\mathbf {M})$
is generalized log canonical. As
$(X,B+\Gamma ,\mathbf {M})$
and
$(Y,B_Y+\Gamma _Y,\mathbf {M})$
are crepant equivalent, we conclude that they have the same coregularity. Hence, we deduce that
$$\begin{align*}\hat{\mathrm{coreg}}_z(Y,B_Y,\mathbf{M}) \leq \hat{\mathrm{coreg}}_z(X,B,\mathbf{M}). \end{align*}$$
On the other hand, up to shrinking Z around z, we can find an effective divisor
$D_Y$
on Y that computes the absolute coregularity of
$(Y,B_Y,\mathbf {M})$
over z. Let
$p\colon W \rightarrow X$
and
$q\colon W\rightarrow Y$
be a common resolution. Write
$$\begin{align*}K_X+B+D+{\mathbf{M}_{X}} = q_*p^*(K_Y+B_Y+D_Y+{\mathbf{M}_{Y}}). \end{align*}$$
By the negativity lemma, we know that D is an effective divisor. Hence,
$(X,B+D,\mathbf {M})$
is a generalized log Calabi–Yau pair over Z. As above, we conclude that the absolute coregularity of
$(X,B,\mathbf {M})$
over
$z\in Z$
is at most the absolute coregularity of
$(Y,B_Y,\mathbf {M})$
over
$z\in Z$
. This finishes the proof.
The following lemma states the coregularity behaves well under adjunction for generalized log Calabi–Yau pairs.
Lemma 2.23. Let
$(X,B,\mathbf {M})$
be a generalized log Calabi–Yau pair over Z. Let
$z\in Z$
be a point. Let S be the normalization of a component of
$\lfloor B\rfloor $
whose image on Z contains z. Let
$B_S$
and
$\mathbf {N}$
be the boundary and moduli parts defined by generalized adjunction, so that
$(K_X+B+{\mathbf {M}_{X}})|_S\sim K_S+B_S+{\mathbf {N}_{S}}.$
Then, we have that
$$\begin{align*}\mathrm{coreg}(S,B_S, \mathbf{N})=\mathrm{coreg}(X,B, \mathbf{M}).\end{align*}$$
holds after possibly shrinking around
$z\in Z$
.
Proof. By passing to a generalized dlt modification, we may assume that both generalized pairs
$(X,B,\mathbf {M})$
and
$(S,B_S,\mathbf {N})$
are generalized dlt. Since any minimal generalized log canonical center of
$(S,B_S,\mathbf {N})$
is a minimal generalized log canonical center of
$(X,B,\mathbf {M})$
, we have that
$\mathrm {coreg}(S,B_S,\mathbf {N})\geq \mathrm {coreg}(X,B,\mathbf {M})$
. On the other hand, let W be a minimal generalized log canonical center of
$(X,B,\mathbf {M})$
whose image on Z contains z. By [Reference Filipazzi and Svaldi16, Theorem 1.4],
$(S,B_S,\mathbf {N})$
admits a generalized log canonical center
$W_S$
that is
$\mathbb {P}^1$
-linked to W, thus
$\dim W_S =\dim W$
. This implies that
$\mathrm {coreg}(X,B,\mathbf {M})\geq \mathrm {coreg}(S,B_S,\mathbf {N})$
.
See [Reference Birkar3, § 3] for the construction of generalized adjunction. By altering the pairs, we can get the same result for pairs with nef anticanonical class.
Lemma 2.24. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z. Assume that
$-(K_X+B+{\mathbf {M}_{X}})$
nef over Z. Let S be the normalization of a component of
$\lfloor B\rfloor $
. Let
$B_S$
and
$\mathbf {N}$
be the boundary and moduli parts defined by generalized adjunction so that
$(K_X+B+{\mathbf {M}_{X}})|_S\sim K_S+B_S+{\mathbf {N}_{S}}$
. Then, we have that
$$\begin{align*}\mathrm{coreg}(S,B_S, \mathbf{N})=\mathrm{coreg}(X,B, \mathbf{M}).\end{align*}$$
Proof. Define 
and let
$\mathbf {P}$
denote its b-Cartier closure. Then,
$\mathbf {P}$
is a b-nef
$\mathbb {Q}$
-Cartier divisor. We can apply Lemma 2.23 to the generalized log Calabi–Yau pair
$(X,B,\mathbf {M}+ \mathbf {P})$
. Therefore,
$\mathrm {coreg} (S,B_S, \mathbf {N}+ \mathbf {P}|_{S} )=\mathrm {coreg} (X,B, \mathbf {M} + \mathbf {P})$
. Since
$\mathbf {P}$
descends on S, we conclude that
$\mathrm {coreg}(S,B_S,\mathbf {N}+\mathbf {P}|_{S})=\mathrm {coreg}(S,B_S,\mathbf {N})$
. Hence,
$\mathrm {coreg}(S,B_S, \mathbf {N})=\mathrm {coreg}(X,B, \mathbf {M})$
.
The following lemma will be used to cut down the dimension of the base Z in a fibration
$X\to Z$
.
Lemma 2.25. Let
$(X,B)$
be a log canonical pair over Z and
$\pi \colon X\to Z$
be a fibration with
$\dim Z\geq 2$
. Suppose
-
• the pair
$(X,B)$
is log Calabi–Yau over Z; -
•
$\phi $
is of Fano type over an open set U of Z; -
• every log canonical center of
$(X,B)$
dominates Z; and -
• the coregularity of
$(X,B)$
is at most c.
Let H be a general hyperplane section of Z and G be the pull-back of H to X. Write
$$\begin{align*}(K_X+B+G)|_G = K_G+B_G. \end{align*}$$
Then we have
-
• the pair
$(G,B_G)$
is log canonical; -
• the pair
$(G,B_G)$
is log Calabi–Yau over H; -
• the induced map
$G\to H$
is of Fano type over
$U\cap H$
; -
• every log canonical center of
$(G,B_G)$
dominates H; and -
• the coregularity of
$(G,B_G)$
is at most c.
Furthermore, let
$B_Z$
and
$B_H$
denote the discriminant parts of the adjunction for
$(X,B)$
over Z and
$(G,B_G)$
over H, respectively. Let D be a prime divisor on Z and C a component of
$D\cap H$
. Then
$$\begin{align*}\operatorname{\mathrm{coeff}}_D(B_Z) = \operatorname{\mathrm{coeff}}_C(B_H). \end{align*}$$
Proof. We follow the proof of [Reference Birkar2, Lemma 3.2].
Since G is the pull-back of a general hyperplane section on Z,
$(X,B+G)$
is log canonical. Thus, by adjunction,
$(G,B_G)$
is log canonical and log Calabi–Yau over H. Moreover, every log canonical center of
$(G,B_G)$
is a component of the intersection of a log canonical center of
$(X,B+G)$
and G, and hence must dominate H. By 2.23, we have an equality
$$\begin{align*}\text{coreg}(G,B_G) = \text{coreg}(X,B) \leq c. \end{align*}$$
Denote the map
$G\to H$
by
$\psi $
. Let t be the log canonical threshold of
$\pi ^*D$
with respect to
$(X,B)$
over the generic point of D. Then there is a non-klt center W of
$(X,B+t\pi ^*D)$
which dominates D and the pair
$(X,B+t\pi ^*D)$
is lc over the generic point of D. Since G is a general pull-back,
$(X,B+G+t\pi ^*D)$
is also lc over the generic point of D. By inversion of adjunction [Reference Kawakita27], there exists a component of
$G\cap W$
which is a non-klt center of
$(G,B_G+t\pi ^*C)$
and
$(G,B_G+t\pi ^*C)$
is lc near the generic point of C. Thus, t is the log canonical threshold of
$\psi ^*C$
with respect to
$(G,B_G)$
. In particular, we have
$$\begin{align*}\operatorname{\mathrm{coeff}}_D(B_Z) = 1-t = \operatorname{\mathrm{coeff}}_C(B_H).\\[-38pt] \end{align*}$$
Definition 2.26. We say that a log canonical threshold
$t=\mathrm {lct}((X,B);\Gamma )$
has coregularity c if
$\mathrm {coreg}(X,B+t\Gamma )=c$
and the support of
$\Gamma $
contains the image on X of a c-dimensional log canonical center on a dlt modification.
2.7 Kollár–Xu models for log Calabi–Yau pairs
In this subsection, we introduce the concept of Kollár–Xu models. Using a theorem due to Filipazzi and Svaldi, we conclude that every generalized log Calabi–Yau pair admits a Kollár–Xu model.
Definition 2.27. Let
$(X,B,\mathbf {M})$
be a projective generalized log Calabi–Yau pair. We say that
$(X,B,\mathbf {M})$
is a Kollár–Xu generalized pair if there exists a projective contraction
$\pi \colon X \rightarrow Z$
for which the following conditions are satisfied:
-
(1) the generalized pair
$(X,B,\mathbf {M})$
is generalized dlt; -
(2) every generalized log canonical center of
$(X,B,\mathbf {M})$
dominates Z; and -
(3) the divisor
$\lfloor B\rfloor $
fully supports a
$\pi $
-big and
$\pi $
-semiample divisor.
In particular, the morphism
$\pi \colon Y\rightarrow Z$
is of Fano type.
Let
$(X,B,\mathbf {M})$
be a generalized log Calabi–Yau pair. Let
$\pi \colon Y\dashrightarrow X$
be a birational map. Assume that
$\pi $
only extracts log canonical places of
$(X,B,\mathbf {M})$
and is an isomorphism over
$X\setminus \operatorname {\mathrm {Supp}} \lfloor B\rfloor $
. If
$(Y,B_Y,\mathbf {M})$
is a Kollár–Xu generalized pair, then we say that
$Y\dashrightarrow X$
is a Kollár–Xu model for
$(X,B,\mathbf {M})$
. We may also say that
$(Y,B_Y,\mathbf {M})$
, together with
$\pi $
, defines a Kollár–Xu model for
$(X,B,\mathbf {M})$
.
The following theorem is a generalization of [Reference Kollár and Xu31, Theorem 49] to the context of generalized pairs. We refer the reader to [Reference Filipazzi and Svaldi16, Theorem 4.2]. It gives a first approximation for the existence of Kollár–Xu models in the following theorem.
Theorem 2.28. Let
$(X,B,\mathbf {M})$
be a projective
$\mathbb {Q}$
-factorial generalized dlt log Calabi–Yau pair. Then, there exists a crepant birational map
$\phi \colon X \dashrightarrow \overline {X}$
, a generalized pair
$(\overline {X}, \overline {B}, \mathbf M)$
and a morphism
$\pi \colon \overline {X} \rightarrow Z$
such that:
-
(1)
$\lfloor \overline {B} \rfloor $
fully supports a
$\pi $
-ample divisor; -
(2) every generalized log canonical center of
$(\overline {X},\overline {B},\mathbf {M})$
dominates Z; -
(3)
$\overline {E} \subset \operatorname {\mathrm {Supp}}\lfloor \overline {B}\rfloor $
for every
$\phi ^{-1}$
-exceptional divisor
$\overline {E} \subset \overline {X}$
; and -
(4)
$\phi ^{-1}$
is an isomorphism over
$\overline {X} \setminus \operatorname {\mathrm {Supp}} \lfloor \overline {B}\rfloor $
.
We observe that the model
$\overline {X}$
in Theorem 2.28 is not necessarily
$\mathbb {Q}$
-factorial. However, using
$\mathbb {Q}$
-factorial dlt modifications, we construct a Kollár–Xu model.
Theorem 2.29. Let
$(X,B,\mathbf {M})$
be a projective generalized log Calabi–Yau pair. Then, it admits a Kollár–Xu model
$Y\dashrightarrow X$
. Furthermore, if
$(X,B,\mathbf {M})$
has coregularity c, then so does
$(Y,B_Y,\mathbf {M})$
.
In the context of Theorem 2.29, if
$c=0$
, then
$Z=\operatorname {Spec} (\mathbb {K})$
and Y is a variety of Fano type.
Proof. Let
$(X,B,\mathbf {M})$
be a generalized pair as in the statement. Then, we first consider a
$\mathbb {Q}$
-factorial generalized dlt modification and then apply Theorem 2.28 to such modification. Call
$(\overline {X},\overline {B},\mathbf {M})$
the resulting model and
$\pi \colon \overline {X} \rightarrow Z$
the morphism claimed in Theorem 2.28. Since
$(X,B,\mathbf {M})$
has coregularity c, then so does
$(\overline {X},\overline {B},\mathbf {M})$
. In particular,
$(\overline {X},\overline {B},\mathbf {M})$
has a c-dimensional generalized log canonical center. Then, by (2) in Theorem 2.28, it follows that Z has dimension at most c. By (1) in Theorem 2.28,
$\overline {B}$
fully supports a
$\pi $
-ample divisor, which we will denote by
$\overline {H}$
. Now, let
$(Y,B_Y,\mathbf {M})$
be a
$\mathbb {Q}$
-factorial generalized dlt modification of
$(\overline {X},\overline {B},\mathbf {M})$
, with morphism
$p \colon Y \rightarrow \overline {X}$
. We denote by
$\pi _Y$
the induced morphism
$\pi _Y \colon Y \rightarrow Z$
. Note that every generalized log canonical center of
$(Y,B_Y,\mathbf {M})$
dominates Z. Then, (2) in Definition 2.27 holds. By [Reference Filipazzi and Svaldi16, Remark 4.3], we have
$\mathrm {Nklt}(\overline {X},\overline {B},\mathbf {M})=\operatorname {\mathrm {Supp}}\lfloor \overline {B}\rfloor $
. Since p only extracts generalized log canonical places, it then follows that every p-exceptional divisor has positive coefficients in 
and that
$\operatorname {\mathrm {Supp}} H_Y= \operatorname {\mathrm {Supp}} \lfloor B_Y \rfloor $
. Then, it follows that
$\lfloor B_Y \rfloor $
fully supports a
$\pi _Y$
-big and
$\pi _Y$
-semiample divisor. Thus, (3) in Definition 2.27 holds. The statements (1) and (3) in Definition 2.27 hold by construction. We conclude that
$(Y,B_Y,\mathbf {M})$
, together with
$\pi _Y$
, are a Kollár–Xu model of
$(X,B,\mathbf {M})$
. Lastly,
$(Y,B_Y,\mathbf {M})$
has coregularity c, since it is crepant to a generalized pair of coregularity c.
2.8 Index of generalized klt pairs
In this subsection, we reduce the index conjecture for generalized klt pairs to the standard index conjecture.
Lemma 2.30. Let d and p be two positive integers. Let
$\Lambda $
be a set of rational numbers satisfying the descending chain condition. Assume Conjecture 1
$(d)$
holds. Then, there exists a positive integer 
, satisfying the following. Let
$(X,B,\mathbf {M})$
be a generalized klt Calabi–Yau pair for which:
-
• the variety X has dimension d;
-
• the coefficients of B belong to
$\Lambda $
; -
• the divisor
$p\mathbf {M}$
is Cartier where it descends.
Then, we have that
$I(K_X+B+{\mathbf {M}_{X}})\sim 0$
.
Proof. By the global ascending chain condition (ACC) [Reference Birkar and Zhang7, Theorem 1.6], we may assume that
$\Lambda $
is a finite set of rational numbers. The statement is clear in dimension
$1$
. We proceed by induction on the dimension. If
$\mathbf {M}=0$
, then the statement follows from the conjecture. Since
$(X,B,\mathbf {M})$
is generalized klt, it admits a small
$\mathbb {Q}$
-factorialization. Therefore, we may assume that X is
$\mathbb {Q}$
-factorial. By the ACC for generalized log canonical thresholds, we may assume
$(X,B,\mathbf {M})$
is
$\epsilon $
-log canonical for some
$\epsilon $
that only depends on d, p and
$\Lambda $
. Then, it follows that X is itself
$\epsilon $
-log canonical. We run a
$K_X$
-MMP which terminates with a Mori fiber space
$X\dashrightarrow X'\rightarrow Z$
. If Z is zero-dimensional, then
$X'$
belongs to a bounded family by [Reference Birkar4]. By [Reference Filipazzi and Moraga14, Theorem 1.2]
$(K_{X'}+B'+{\mathbf {M}_{X'}})$
admits an I-complement for some I that only depends on
$\Lambda ,d$
and p. Since
$K_{X'}+B'+{\mathbf {M}_{X'}}\sim _{\mathbb {Q}} 0$
, we conclude that
$I(K_{X'}+B'+{\mathbf {M}_{X'}})\sim 0$
, so the statement follows for X as well. Now, assume that Z is positive-dimensional. We write
$\pi '\colon X'\rightarrow Z$
for the corresponding contraction. By [Reference Filipazzi and Moraga14, Lemma 5.4], we can write
$$\begin{align*}q(K_{X'}+B'+{\mathbf{M}_{X'}}) \sim q \pi^*(K_Z+B_Z+{\mathbf{N}_{Z}}), \end{align*}$$
where the coefficients of
$B_Z$
belong to
$\Omega $
which satisfies the DCC and only depends on
$\Lambda ,d$
and p. Furthermore, q only depends on
$\Lambda ,d$
and p and
$q\mathbf {N}$
is Cartier where it descends. The generalized pair
$(Z,B_Z, \mathbf {N})$
is generalized log canonical since it comes from the generalized canonical bundle formula [Reference Filipazzi11, Theorem 1.4]. By induction on the dimension, we know that
$I_0(K_Z+B_Z+{\mathbf {N}_{Z}})\sim 0$
for some
$I_0$
that only depends on
$\Lambda ,d$
and p. Thus, we conclude that
$I(K_X+B+{\mathbf {M}_{X}})\sim 0$
, where
$I=\mathrm {lcm}(q,I_0)$
.
2.9 Lifting sections using fibrations
In this subsection, we give some lemmata regarding the lifting of sections using fibrations.
Theorem 2.31. Let
$\lambda ,d$
and c be nonnegative integers. Assume that Theorem 6
$(d-1,c)$
holds, and let 
be the integer provided by this theorem. Let
$(X,B,\mathbf {M})$
be a d-dimensional rationally connected generalized log Calabi–Yau pair. Assume that the following conditions hold:
-
• X is
$\mathbb {Q}$
-factorial and
$(X,B,\mathbf {M})$
is generalized dlt; -
• there is a fibration
$X\rightarrow W$
, which is a
$(K_X + \lfloor B \rfloor )$
-Mori fiber space; -
• a component
$S\subset \operatorname {\mathrm {Supp}}\lfloor B\rfloor $
is rationally connected and ample over W; -
• the coefficients of B belong to
$D_\lambda $
; -
• we have that
$\lambda \mathbf {M}$
is b-Cartier; and -
• the generalized pair
$(X,B,\mathbf {M})$
has coregularity c.
Then, we have that
$I(K_X+B+{\mathbf {M}_{X}})\sim 0$
.
Proof. Let
$(X,B,\mathbf {M})$
, S,
$f \colon X \rightarrow W$
and 
be as in the statement. First, we show that we can apply the inductive hypothesis to S.
Since
$(X,\lfloor B \rfloor )$
is dlt, S is normal. Furthermore, we have
$\mathrm {Nklt}(X,S)=S$
. Since
$-({K_{X}} + S)$
is f-ample, by the connectedness principle [Reference Filipazzi and Svaldi16], it follows that
$S \rightarrow W$
has connected fibers. Now, let
$(S,B_S,\mathbf {N})$
be the generalized pair induced on S by generalized divisorial adjunction. By Lemma 2.23,
$(S,B_S,\mathbf {N})$
has coregularity c. Furthermore, by Lemma 2.17 and Lemma 2.16, it satisfies the assumptions of Theorem 6
$(d-1,c)$
with constant I. Thus, we have
$$ \begin{align} I ({K_{S}} + B_S + {\mathbf{N}_{S}}) \sim 0. \end{align} $$
By [Reference Figueroa, Moraga and Peng10, Theorem 3.1], the coefficients of
$B_S$
belong to a finite set only depending on
$\lambda $
and c. In particular, they are divisible by I, as so are the coefficients of
${\mathbf {N}_{S}}$
. Then, these coefficients control the coefficients of
$\mathrm {Diff}_S(0)$
, as we explain in what follows. By [Reference Kollár29, 3.35], along the codimension 2 points of X contained in S, X has cyclic singularities.
Then, given a prime divisor P in S, an étale local neighbourhood of a general point
$p \in P$
is isomorphic to
$$\begin{align*}(p \in (X, B, \mathbf{M}))\simeq (0 \in (\mathbb{A}^2=(x,y), (x=0) + c(y=0)))/(\mathbb{Z}/m\mathbb{Z})\times \mathbb{A}^{\dim X -2}, \end{align*}$$
where
$Z \simeq (\mathbb {A}^2=(x,y))/(\mathbb {Z}/m\mathbb {Z})$
,
$S=(x=0)$
and
$S'=(y=0)$
. Since the class group of Z is generated by
$S'$
, there exists an integer
$\mu $
such that
$$ \begin{align} I(K_X+B+{\mathbf{M}_{X}}) \sim \mu S'. \end{align} $$
By adjunction,
$S'|_S \sim _{\mathbb {Q}} \frac {1}{m}\{0\}$
. We also have that
$I(K_X+B+{\mathbf {M}_{X}})|_S\sim 0$
, as the denominators of the coefficients of
$B_S$
and
${\mathbf {N}_{S}}$
divide I and hence it is a Cartier divisor on a smooth germ.
Then, we can write
$$\begin{align*}0 \sim I(K_X+B+M)|_S \sim \mu S'|_S \sim \frac{\mu}{m}\{0\}. \end{align*}$$
We conclude that m divides
$\mu $
. In particular, we have that
$\mu S$
is a Cartier divisor, as the Cartier index of any Weil divisor of X through
$\{0\}$
divides m. By the linear equivalence (2.2), we conclude that the divisor
$I(K_X+B+M)$
is Cartier at the generic point of P. Note that this argument is independent of P, so we conclude that
$I(K_X+B+M)$
is Cartier at the generic point of every divisor on S. Thus,
$I(K_X+B+M)$
is Cartier along a set U that contains the generic point of every divisor of S.
Then, by [Reference Birkar3, 2.41 and Lemma 2.42], we have the following short exact sequence
$$ \begin{align} 0 \rightarrow {\mathcal{O}_{X}}(I(K_{X}+B + {\mathbf{M}_{X}})-S) \rightarrow {\mathcal{O}_{X}}(I(K_{X}+B+ {\mathbf{M}_{X}})) \rightarrow {\mathcal{O}_{S}}(I(K_{S}+B_{S}+ {\mathbf{N}_{S}})) \rightarrow 0. \end{align} $$
Since
$I(K_{X}+B + {\mathbf {M}_{X}})-S\sim _{\mathbb {Q},f} -S$
, the divisor
$-S$
is f-ample and
$\dim W < \dim X$
, we have
$$\begin{align*}f_*{\mathcal{O}_{X}}(I(K_{X}+B + {\mathbf{M}_{X}})-S)=0. \end{align*}$$
Similarly, we write
$$\begin{align*}I(K_{X}+B + {\mathbf{M}_{X}})-S\sim_{\mathbb{Q},f} -S \sim_{\mathbb{Q},f} K_X +(B-S+{\mathbf{M}_{X}}). \end{align*}$$
Note that X is klt and
$B-S+{\mathbf {M}_{X}} = B^{<1}+{\mathbf {M}_{X}} + (B^{=1} - S)$
is f-ample since f is a Mori fiber space and the divisor
$B^{<1}+{\mathbf {M}_{X}}$
is f-ample. Thus, by the relative version of Kawamata–Viehweg vanishing, we have
$$\begin{align*}R^1f_*{\mathcal{O}_{X}}(I(K_{X}+B + {\mathbf{M}_{X}})-S)=0. \end{align*}$$
Therefore, by pushing forward (2.3) via f, we obtain
$$\begin{align*}f_* {\mathcal{O}_{X}}(I(K_{X}+B+ {\mathbf{M}_{X}})) \simeq f_* {\mathcal{O}_{S}}(I(K_{S}+B_{S}+ {\mathbf{N}_{S}})). \end{align*}$$
Now, taking global sections, we have
$$ \begin{align} H^0(X, {\mathcal{O}_{X}}(I(K_{X}+B+ {\mathbf{M}_{X}}))) = H^0(S, {\mathcal{O}_{S}}(I(K_{S}+B_{S}+ {\mathbf{N}_{S}})))=H^0(S, {\mathcal{O}_{S}}) \neq 0. \end{align} $$
By Lemma [Reference Filipazzi, Mauri and Moraga13, Lemma 3.1], (2.4) implies that
$I(K_{X}+B+ {\mathbf {M}_{X}}) \sim 0$
.
Theorem 2.32. Let
$\lambda ,d$
and c be nonnegative integers. Assume that Theorem 6
$(d-1,c)$
holds, and let 
be the integer provided by this theorem. Assume that I is divisible by
$2\lambda $
. Let
$(X,B)$
be a d-dimensional log Calabi–Yau pair. Assume that the following conditions hold:
-
• X is
$\mathbb {Q}$
-factorial and klt; -
• there is a fibration
$X\rightarrow W$
; -
• S is a prime component of
$\lfloor B \rfloor $
that is ample over W; -
•
$(X,B-S)$
is dlt; -
• the morphism
$S \rightarrow W$
does not have connected fibers; -
• the coefficients of B belong to
$D_\lambda $
; and -
• the pair
$(X,B)$
has coregularity c.
Then, we have that
$I(K_X+B)\sim 0$
.
Proof. Let
$(X,B)$
, S,
$f \colon X \rightarrow W$
and 
be as in the statement. We will proceed in several steps.
Step 1: In this step, we observe that
$\dim X - \dim W=1$
, f is generically a
${\mathbb {P}^{1}}$
-fibration and
$B_{\mathrm {hor}}=S$
.
Since
$(X,B)$
is log canonical and X is
$\mathbb {Q}$
-factorial, then
$(X,S)$
is log canonical. By considering a general fiber of f, the restriction of S induces a disconnected ample divisor. Therefore, by [Reference Hartshorne25, Exercise III.11.3], it follows that the general fiber of f is a curve. By the log Calabi–Yau condition and the fact that
$0 \neq B_{\mathrm {hor}} \geq S$
, it follows that f is generically a
${\mathbb {P}^{1}}$
-fibration. Since
$S \rightarrow W$
does not have connected fibers and
$\deg K_{{\mathbb {P}^{1}}}=-2$
, it follows that S is the only component of
$\operatorname {\mathrm {Supp}} B$
that dominates W, that is, we have
$B_{\mathrm {hor}} =S$
. In particular, we may find a nonempty open subset
$U \subseteq W$
such that
$K_X+S \sim _{\mathbb {Q}} 0 /U$
.
Step 2: In this step, we show that
$\dim W> 0$
.
By Step 1,
$X \rightarrow W$
is generically a
${\mathbb {P}^{1}}$
-fibration, and S determines two distinct points on the geometric generic fiber of f. Thus, if
$\dim W =0$
, it would follow that
$(X,B) \simeq ({\mathbb {P}^{1}},\{ 0 \} + \{\infty \})$
, with S identified with
$\{ 0 \} + \{\infty \}$
. Since we assumed that S is a prime divisor, this leads to the sought contradiction.
Step 3: In this step, we show that we may replace X birationally so that
$(X,S)$
is plt,
$K_X +S \sim _{\mathbb {Q}} 0/W$
and f is a Mori fiber space.
Since
$(X,B)$
is log canonical and X is
$\mathbb {Q}$
-factorial, then
$(X,S)$
is log canonical. Let
$X'$
be a
$\mathbb {Q}$
-factorial dlt modification of
$(X,S)$
, and let
$S'$
denote the strict transform of S. In particular,
$(X',S')$
is plt. By [Reference Hacon and Xu23, Theorem 1.1],
$(X',S')$
has a relatively good minimal model over W, which we denote by
$(\tilde X, \tilde S)$
. Since
$S'$
dominates W and
$\dim X - \dim W =1$
,
$S'$
is relatively big over W. Therefore,
$S'$
cannot be contracted on
$\tilde X$
, and therefore
$\tilde S$
is a divisor. Since
$(X',S')$
is plt, then so is
$(\tilde X,\tilde S)$
. We denote by
$\tilde W$
the relatively ample model, which is birational to W. Now, we run a
${K_{\tilde X}}$
-MMP with scaling over
$\tilde W$
, which terminates with a Mori fiber space
$\hat f \colon \hat X \rightarrow \hat W$
over
$\tilde W$
. Since
$\dim X -\dim W =1$
, it follows that
$\hat W \rightarrow \tilde W$
is birational. As before, since
$\tilde S$
dominates
$\tilde W$
and is relatively big over
$\tilde W$
as
$\dim X - \dim W =1$
, it follows that
$\tilde S$
cannot be contracted on
$\hat X$
. Let
$\hat S$
be its strict transform on
$\hat X$
. Lastly, as
${K_{\tilde X}} + \tilde S \sim _{\mathbb {Q}} 0 /\tilde W$
and
$\tilde S$
is the only log canonical place of
$(\tilde X,\tilde S)$
,
$\hat S$
is the only log canonical place of
$(\hat X,\hat S)$
. But then, since
$\hat S$
is a divisor on
$\hat X$
, it follows that
$(\hat X,\hat S)$
is plt. In particular,
$\hat S$
is normal. Thus, by [Reference Filipazzi, Mauri and Moraga13, Corollary 3.3], up to replacing X, S and Z with
$\hat X$
,
$\hat S$
and
$\hat Z$
, respectively, in the following of the proof, we may further assume that
$(X,S)$
is plt,
$K_X +S \sim _{\mathbb {Q}} 0/W$
and f is a Mori fiber space.
Step 4: In this step, we introduce a suitable pair structure on the base W.
Let
$(S,B_S)$
denote the pair induced by adjunction from
$(X,B)$
to S. By Lemma 2.23,
$(S,B_S)$
has coregularity c. Then, by Lemma 2.17, the inductive hypothesis applies to
$(S,B_{S})$
for the same value of I. We also let
$(S,\mathrm {Diff}_S(0))$
be the pair structure induced from
$(X,S)$
to S. By Step 1,
$f_S \colon S \rightarrow W$
is generically 2:1 and hence Galois. By [Reference Kollár29, Proposition 4.37.(3)],
$(S,\mathrm {Diff}_S(0))$
is invariant under the rational Galois involution. Then, since
${K_{X}} + S \sim _{\mathbb {Q}} 0 /W$
and f is a Mori fiber space, it follows that
$B-S$
is the pull-back of a
$\mathbb {Q}$
-divisor on W. Then, it follows that also
$(S,B_S)$
is Galois invariant. Then, by considering the Stein factorization of
$S \rightarrow W$
and descending the pair structure thanks to the fact that
${K_{S}} +B_S \sim _{\mathbb {Q}} 0$
, it follows that we can induce a pair structure
$(W,B_W)$
such that
$f_S^*({K_{W}} + B_W)={K_{S}} + B_S$
. Since
$(S,B_S)$
has coregularity c, by [Reference Filipazzi, Mauri and Moraga13, Proposition 3.11], then so does
$(W,B_W)$
. Furthermore, since
$(S,B_S)$
has coefficients in
$D_\lambda $
, then so does
$(W,B_W)$
. Indeed, at the codimension 1 points of W where
$S \rightarrow W$
is étale, we will have the same coefficients on
$B_W$
and
$B_S$
for the corresponding divisors. Then, we can consider a prime divisor
$Q \subset W$
such that
$S \rightarrow W$
ramifies of order 2 at the generic point of Q. Then, over the generic point of Q, by the Riemann–Hurwitz formula, we have
$$\begin{align*}{K_{S}}+ cP=f_S^*\left(K_W+\frac{1}{2}Q+\frac{c}{2}Q \right), \end{align*}$$
where P is the unique prime divisor in S dominating Q, in other words
$\operatorname {\mathrm {coeff}}_P(B_S)= c \in D_\lambda $
and
$\operatorname {\mathrm {coeff}}_Q(B_W)=\frac {1+c}{2}$
. By the definition of
$D_\lambda $
, we must have
$c=\frac {m-1+a\lambda ^{-1}}{m}$
for some
$m \in \mathbb {Z}_{>0}$
and
$a \in \mathbb {Z}_{\geq 0}$
, and it follows that
$$\begin{align*}\frac{1}{2}+\frac{m-1+a\lambda^{-1}}{m}=\frac{2m-1+a\lambda^{-1}}{2m} \in D_\lambda. \end{align*}$$
Thus, by the inductive hypothesis, we have
$$ \begin{align} I(K_W+B_W)\sim 0. \end{align} $$
Step 5: In this step, we introduce a suitable generalized pair structure on W, and we compare it with
$(W,B_W)$
.
By the canonical bundle formula, the lc-trivial fibration
$f \colon (X,B) \rightarrow W$
induces a generalized pair structure
$(W,\Delta _W,\mathbf {N})$
on W. By [Reference Prokhorov and Shokurov38, § 7.5, (7.5.5)] and the fact that the generic fiber of
$f \colon (X,B) \rightarrow W$
is a conic with two points, we have
$$ \begin{align} {K_{X}} + B \sim f^*({K_{W}} + \Delta_W+ {\mathbf{N}_{W}}). \end{align} $$
Furthermore, the representatives of the b-divisor
$\mathbf {N}$
are determined up to
$\mathbb {Z}$
-linear equivalence.
By [Reference Fujino and Gongyo20, proof of Theorem 1.1], in an lc-trivial fibration
$(Y,\Gamma ) \rightarrow C$
, the total space of the fibration and a minimal (with respect to inclusion) log canonical center
$\Xi $
dominating the base C induce the same generalized pair on the base space. More precisely, they induce the same boundary divisor as
$\mathbb {Q}$
-Weil divisor and the same moduli divisor as
$\mathbb {Q}$
-b-divisor class. Yet, this comparison is possible after the base change induced by the Stein factorization of
$\Xi \rightarrow C$
, as
$\Xi \rightarrow C$
may not have connected fibers. We observe that the identification between the boundary divisors can also be obtained by inversion of adjunction together with the connectedness principle.
In our situation, this implies that
$(X,B)$
and
$(S,B_S)$
induce the same generalized pair on W, up to pull-back to the Stein factorization on
$S \rightarrow W$
. In this case, S is generically a 2:1 cover of W. Thus, it follows that
$(W,\Delta _W,\mathbf {N})$
and
$(W,B_W)$
agree once pulled back to S. By construction, we have
$f_S^{\prime *}({K_{W}} + B_W)={K_{S}} + B_S$
, and the moduli b-divisor is trivial. In turn, this implies that
$\Delta _W=B_W$
and
$f_S^* {\mathbf {N}_{W}} \sim 0$
. As for the moduli b-divisor, we only claim
$\mathbb {Z}$
-linear equivalence, as a representative of the b-divisorial class can be replaced in the
$\mathbb {Z}$
-linear equivalence class.
Let
$S'$
denote the Stein factorization of
$S \to W$
, with induced morphism
$f_{S'} \colon S' \rightarrow W$
. Then,
$f_{S'}$
is a finite Galois morphism of degree 2,
$f_{S'}^* {\mathbf {N}_{W}} \sim 0$
. By construction,
$f_{S'}^* {\mathbf {N}_{W}}$
is Galois invariant since it is the
$\mathbb {Q}$
-Cartier pull-back of a
$\mathbb {Q}$
-divisor on W via the finite morphism
$f_{S'}$
. We observe that this implies that
$2 {\mathbf {N}_{W}}$
is a
$\mathbb {Z}$
-divisor and that
$2f_{S'}^* {\mathbf {N}_{W}}$
is the integral pull-back of the integral divisor
$2 {\mathbf {N}_{W}}$
.
Now, let s be a trivializing section of
$f_{S'}^* {\mathbf {N}_{W}}$
, and let
$\tau $
be the nontrivial element in the Galois group of
$S' \rightarrow W$
. By the invariance of
$f_{S'}^* {\mathbf {N}_{W}}$
, we have that
$f_{S'}^* {\mathbf {N}_{W}} + \tau ^*f_{S'}^* {\mathbf {N}_{W}}=2f_{S'}^* {\mathbf {N}_{W}}$
. But then,
$s \otimes \tau ^*s$
is a Galois invariant trivializing section of
$2f_{S'}^* {\mathbf {N}_{W}}$
. Then, this section descends to W, thus implying that
$$ \begin{align} 2{\mathbf{N}_{W}} \sim 0. \end{align} $$
Step 6: In this step, we conclude the proof.
Combining the previous steps and using the fact that
$2|I$
, we have
$$ \begin{align*} I({K_{X}} + B) &\sim If^*({K_{W}} + B_W + {\mathbf{N}_{W}})\\ &\sim If^*({K_{W}}+B_W) + If^* {\mathbf{N}_{W}}\\ &\sim f^*(I({K_{W}} + B_W)) + f^* I{\mathbf{N}_{W}}\\ &\sim f^*0 + f^*0 \sim 0, \end{align*} $$
where the first linear equivalence follows from Equation (2.6), the second one follows from the fact that
$K_W+B_W$
is
$\mathbb {Q}$
-Cartier, the third one follows from the definition of pull-back of
$\mathbb {Q}$
-divisors, while the last line follows from Equations (2.5) and (2.7). This concludes the proof.
3 Finite coefficients
In this section, we explain how to reduce the problem of boundedness of complements from pairs with DCC coefficients to pairs with finite coefficients. First, we prove two lemmata that will be used in the proof of the main proposition of this section.
Lemma 3.1. Let
$\phi \colon X\rightarrow Z$
be a contraction from a projective
$\mathbb {Q}$
-factorial variety X. Let
$(X,B,\mathbf {M})$
be a generalized dlt pair over Z. Assume
$(X,B,\mathbf {M})$
is generalized log Calabi–Yau over Z. Assume there is a component
$S\subseteq \lfloor B\rfloor $
that is vertical over Z. Then, there exists a birational contraction
$X\dashrightarrow X'$
over Z
satisfying the following conditions:
-
(i) the generalized pair
$(X',B',\mathbf {M})$
is generalized log canonical; -
(ii) the strict transform
$S'$
of S in
$X'$
is a divisorial generalized log canonical center of
$(X',B',\mathbf {M})$
; -
(iii) we have that
${\phi '}^{-1}(\phi (S))=S'$
holds set-theoretically; and -
(iv) the generalized pair obtained by adjunction of
$(X',B',\mathbf {M})$
to
$S'$
is generalized semilog canonical.
Proof. By [Reference Moraga and Svaldi36, Lemma 3.5], we may run an MMP for
$(X,B-S,\mathbf {M})$
over Z with scaling of an ample divisor A. By the negativity lemma, the divisor S is not contracted by this MMP. Furthermore, this MMP is
$(K_X+B+{\mathbf {M}_{X}})$
-trivial. Hence, conditions (i) and (ii) hold for any model in this minimal model program.
We argue that after finitely many steps condition (iii) holds. Let
$X_i\dashrightarrow X_{i+1}$
be the i-th step of this MMP and
$\phi _i\colon X_i\rightarrow Z$
be the induced projective morphism. We let
$\lambda _i$
the positive real number for which the birational map
$X_i\dashrightarrow X_{i+1}$
is
$(K_{X_i}+B_i-S_i+{\mathbf {M}_{X_i}}+\lambda _i A_i)$
-trivial. Let
$\lambda _\infty =\lim _i \lambda _i$
. If
$\lambda _\infty>0$
, then the previous MMP is also an MMP for
$(X,B-S+\lambda _\infty A,\mathbf {M})$
. By [Reference Moraga and Svaldi36, Lemma 3.7], this is also an MMP for a klt pair with big boundary over Z which must terminate by [Reference Birkar, Cascini and Hacon6]. Let
$X'$
be the model where this MMP terminates. In
$X'$
, we have that
$-S'$
is nef over Z. So
$S'$
must be the set-theoretic preimage of
$\phi '(S')$
.
From now on, we assume that
$\lambda _\infty =0$
. Let
$W_1,\dots ,W_k$
be the irreducible components of
$\phi ^{-1}(\phi (S))$
different than S. Note that every step of the MMP is S-positive. Thus, if the strict transform of any component
$W_j$
is contained in the exceptional locus of
$X_i\dashrightarrow X_{i+1}$
, then the number of components of
$\phi _i^{-1}(\phi (S))$
drops. Henceforth, it suffices to show that each such component is eventually contained in the exceptional locus of a step of the MMP. Assume
$\phi (W_1)\subseteq \phi (S)$
is maximal among the sets
$\phi (W_j)$
’s with respect to the inclusion. Let
$z\in \phi (W_1)$
be a general point. Up to reordering the
$W_j$
’s, since
$X \rightarrow Z$
has connected fibers, we may assume that
$\phi ^{-1}(z)\cap W_1\cap S$
is nonempty. Hence, for a general point
$w \in \phi ^{-1}(z)\cap W_1$
, we can find a curve C such that
$w \in C$
,
$C \nsubseteq S$
, and C intersects S nontrivially. In particular, we have that
$C\subseteq \mathrm {Bs}_{-}(K_X+B-S+{\mathbf {M}_{X}}/Z)$
. In particular, since we have
$w \in C$
, it follows that
$w \in \mathrm {Bs}_{-}(K_X+B-S+{\mathbf {M}_{X}}/Z)$
. Since w is a general point in
$\phi ^{-1}(z)\cap W_1$
, we also get that
$\phi ^{-1}(z)\cap W_1 \subseteq \mathrm {Bs}_{-}(K_X+B-S+{\mathbf {M}_{X}}/Z)$
. Since z is general, we conclude that
$W_1 \subset \mathrm {Bs}_{-}(K_X+B-S+{\mathbf {M}_{X}}/Z)$
. For
$\lambda _1>0$
small enough, we have that
$$\begin{align*}W_1 \subset \mathrm{Bs}(K_X+B-S+\lambda_1A+{\mathbf{M}_{X}}/Z). \end{align*}$$
Since
$\lambda _\infty =0$
, we conclude that for some i the birational map
$X\dashrightarrow X_i$
is a minimal model for
$(X,B-S+\lambda _1A,\mathbf {M}/Z)$
. In particular,
$W_1$
must be contained in the exceptional locus of
$X\dashrightarrow X_i$
. Hence, after finitely many steps of this MMP, condition (iii) is satisfied.
Let
$X'$
be a model where condition (iii) holds. By construction, the generalized pair
$(X',B',\mathbf {M})$
is obtained by a partial run
$X\dashrightarrow X'$
of the MMP for
$(X,B-S,\mathbf {M})$
. In particular,
$(X',B'-S',\mathbf {M})$
is generalized dlt and
$\mathbb {Q}$
-factorial. Hence,
$(X',B'-\epsilon \lfloor B'\rfloor )$
is klt, where
$0 < \epsilon \ll 1$
. By [Reference Fujino and Gongyo19, Example 2.6], the pair obtained by adjunction of
$(X',B'-\epsilon \lfloor B'\rfloor +\epsilon S')$
to
$S'$
is semilog canonical. In turn, by letting
$\epsilon \to 0$
, it follows that the pair obtained by adjunction of
$(X',B')$
to
$S'$
is semilog canonical. Hence, the generalized pair obtained by adjunction of
$(X',B',\mathbf {M})$
to
$S'$
is generalized semilog canonical.
Lemma 3.2. Let c and p be nonnegative integers and
$\Lambda \subset \mathbb {Q}_{>0}$
be a closed set satisfying the DCC. There exists a finite subset 
satisfying the following. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z and
$X\rightarrow Z$
be a fibration for which the following conditions hold:
-
• the generalized pair
$(X,B,\mathbf {M})$
is log Calabi–Yau over Z; -
• the generalized pair
$(X,B,\mathbf {M})$
has coregularity c; -
•
$p\mathbf {M}$
is b-Cartier; and -
• the coefficients of B belong to
$\Lambda $
.
Then, the coefficients of
$B_{\mathrm {hor}}$
belong to
$\mathcal {R}$
.
Proof. Let
$(X_i,B_i,{\mathbf {M}_{i}})$
be a sequence of generalized pairs as in the statement and
$\phi _i\colon X_i\rightarrow Z_i$
be the corresponding contractions. Assume there exist prime divisors
$P_i\subset X_i$
for which 
is strictly increasing and
$P_i$
dominates
$Z_i$
. Assume that some generalized log canonical center of
$(X_i,B_i,{\mathbf {M}_{i}})$
is vertical over
$Z_i$
. We may replace
$(X_i,B_i,{\mathbf {M}_{i}})$
with a generalized dlt modification and assume there is a component
$S_i\subseteq \lfloor B_i\rfloor $
that is vertical over
$Z_i$
. Furthermore, up to choosing a different vertical component possibly dominating a different subset of
$Z_i$
, we may assume that there is a generalized log canonical center of
$(X_i,B_i,{\mathbf {M}_{i}})$
dimension c contained in
$S_i$
. By Lemma 3.1, up to losing the dlt property for
$(X_i,B_i,{\mathbf {M}_{i}})$
, we may assume that
$S_i$
is the set-theoretic preimage of
$\phi $
. Let
$W_i$
be the normalization of
$S_i$
, and let
$W_i\rightarrow Z_{W_i}$
be the fibration obtained by the Stein factorization of
$W_i\rightarrow \phi _i(S_i)$
. Let
$(W_i,B_i,{\mathbf {N}_{i}})$
be the generalized pair obtained by generalized adjunction of
$(X_i,B_i,{\mathbf {M}_{i}})$
to
$W_i$
. Note that
$P_i\cap S_i$
dominates
$\phi (S_i)$
. Hence, there is a component of
$B_{W_i}$
with coefficient in
$D_{d_i}(\Lambda )$
which is horizontal over
$Z_{W_i}$
(see Lemma 2.17). Observe that the following conditions hold:
-
• the generalized pair
$(W_i,B_i,{\mathbf {N}_{i}})$
is log Calabi–Yau over
$Z_{W_i}$
; -
• the generalized pair
$(W_i,B_i,{\mathbf {N}_{i}})$
has coregularity c; -
•
$p{\mathbf {N}_{i}}$
is b-Cartier; -
• the coefficients of
$B_{W_i}$
belong to
$D(\Lambda )$
; and -
• there is a component
$Q_i$
of
$B_{W_i}$
horizontal over
$Z_i$
whose coefficient belong to
$D_{d_i}(\Lambda )$
.
We replace
$(X_i,B_i,{\mathbf {M}_{i}})$
with
$(W_i,B_{W_i},{\mathbf {N}_{i}})$
and
$P_i$
with
$Q_i$
. After finitely many replacements, we may assume that for every i the generalized log canonical centers of
$(X_i,B_i,{\mathbf {M}_{i}})$
are horizontal over
$Z_i$
. [Reference Figueroa, Moraga and Peng10, Theorem 2] applied to the general fiber of
$X_i\rightarrow Z_i$
implies that the coefficients of
$B_{\mathrm {hor}}$
belong to an ACC set. Thus, we conclude that the coefficients of
$B_{\mathrm {hor}}$
belong to a finite set
$\mathcal {R}$
which only depends on c, p and
$\Lambda $
.
The proof of the following corollary is verbatim from the previous proof by replacing [Reference Figueroa, Moraga and Peng10, Theorem 2] with [Reference Filipazzi, Mauri and Moraga13, Corollary 3].
Corollary 3.3. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z and
$X\rightarrow Z$
be a fibration for which the following conditions hold:
-
• the generalized pair
$(X,B,\mathbf {M})$
is log Calabi–Yau over Z; -
• the generalized pair
$(X,B,\mathbf {M})$
has coregularity
$0$
; -
•
$2\mathbf {M}$
is b-Cartier; and -
• the coefficients of B belong to
$\mathcal {S}$
.
Then, the coefficients of
$B_{\mathrm {hor}}$
belong to
$\{1,\frac {1}{2}\}$
.
Notation 3.4. Let
$\Lambda \subset \mathbb {Q}_{>0}$
be a closed set of rational numbers satisfying the DCC. Given a natural number
$m\in \mathbb {Z}_{>0}$
, we consider the partition
of the interval
$[0,1]$
. Denote by
$I(b,m)$
the interval of
$\mathcal {P}_m$
containing
$b\in \Lambda $
. Define the number
For every positive integer m and every
$b \in \Lambda $
, we have that
$b\leq b_m$
as
$b\in \Lambda \cap I(b,m)$
. If
$b\in \Lambda $
is fixed and m divisible enough, we have that
$b=b_m$
. The set 
is finite, and we have that the set
$$\begin{align*}\Lambda = \bigcup_{m\in \mathbb{Z}_{>0}} \mathcal{C}_m \end{align*}$$
satisfies the DCC. Given a boundary divisor
$B\geq 0$
on a quasi-projective variety X, we can write
$B=\sum _j b^{(j)}B^{(j)}$
in a unique way such that the
$B^{(j)}$
’s are pairwise different prime divisors on X. If the coefficients of B belong to
$\Lambda $
, we define
It follows that
$B\leq B_m$
.
Theorem 3.5. Let c and p be nonnegative integers and
$\Lambda \subset \mathbb {Q}_{>0}$
be a set satisfying the DCC with rational accumulation points. There exists a finite subset 
satisfying the following. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z,
$X\rightarrow Z$
be a contraction and
$z\in Z$
be a point. Assume the following conditions are satisfied:
-
• the variety X is of Fano type over Z;
-
• the divisor B has coefficients in
$\Lambda $
; -
•
$p\mathbf {M}$
is b-Cartier; -
• the generalized pair
$(X,B,\mathbf {M})$
has coregularity c around z; and -
• the divisor
$-(K_X+B+{\mathbf {M}_{X}})$
is nef over Z.
There exists a birational transformation
$X\dashrightarrow X'$
over Z and a generalized pair
$(X',\Gamma ',\mathbf {M})$
satisfying the following:
-
• the coefficients of
$\Gamma '$
belong to
$\mathcal {R}$
; -
• the pair
$(X',\Gamma ',\mathbf {M})$
has coregularity c over z; -
• the divisor
$-(K_{X'}+\Gamma '+{\mathbf {M}_{X'}})$
is nef over a neighborhood of
$z\in Z$
; and -
• if
$(X',\Gamma ',\mathbf {M})$
is N-complemented over
$z\in Z$
, then
$(X,B,\mathbf {M})$
is N-complemented over
$z\in Z$
.
Proof. Let
$(X,B,\mathbf {M})$
be a generalized pair as in the conditions of the theorem. By passing to a
$\mathbb {Q}$
-factorial generalized dlt modification, we may assume the considered generalized pairs are gdlt and
$\mathbb {Q}$
-factorial. We denote by
$m(X,B,\mathbf {M})$
the minimal m for which
$\mathcal {R}=\mathcal {C}_{m}$
satisfies the statement of the theorem for
$(X,B,\mathbf {M})$
. Since
$B_m=B$
for m large enough, then
$m(X,b,\mathbf {M})$
is finite. It suffices to show that
$m(X,B,\mathbf {M})$
is bounded above by a constant that only depends on c, p and
$\Lambda $
. Assume that this is not the case. Then, we may find a sequence of generalized pairs
$(X_i,B_i, {\mathbf {M}_{i}})$
, contractions
$X_i\rightarrow Z_i$
and closed points
$z_i\in Z_i$
, satisfying the conditions of the theorem, for which 
is strictly increasing. In particular, we have that
$B_{i,m_i}-B_i$
is a nontrivial effective divisor. Let
$P_i$
be a prime component of
$B_{i,m_i}-B_i$
that intersects the fiber over z. We study how the singularities of
$(X_i,B_i,{\mathbf {M}_{i}})$
over
$z_i\in Z_i$
and the nefness of
$-(K_{X_i}+B_i+{\mathbf {M}_{i}})$
over
$Z_i$
change as we increase the coefficient at
$P_i$
.
Step 1: For the generalized pair
$(X_i,B_i,{\mathbf {M}_{i}})$
, we will produce a positive real number
$t_i$
which either computes a log canonical threshold or a pseudo-effective threshold.
For each generalized pair
$(X_i,B_i,{\mathbf {M}_{i}})$
, we will define a real number
$t_i$
as follows. We consider the generalized pairs
Let
$t_{i,0}$
be the largest real number for which the generalized pair (3.1) is generalized log canonical over
$z_i\in Z_i$
and
$$\begin{align*}-(K_{X_i}+ B_i + t(\mathrm{coeff}_{P_i}(B_{i,m_i}-B_i))P_i+{\mathbf{M}_{i,X_i}}) \end{align*}$$
is nef over a neighborhood of
$z_i\in Z_i$
. Assume that
$t_{i,0}<1$
. Then, for
$t>t_{i,0}$
close enough to
$t_{i,0}$
one of the following conditions hold:
-
(i) the generalized pair
$(X_i,B_{i,t},{\mathbf {M}_{i}})$
is not generalized log canonical over
$z_i\in Z_i$
; or -
(ii) the divisor
$-(K_{X_i}+B_{i,t}+{\mathbf {M}_{i,X_i}})$
is not pseudo-effective over a neighborhood of
$z_i\in Z_i$
and
$(X_i,B_{i,t},{\mathbf {M}_{i}})$
is generalized log canonical over a neighborhood of
$z_i \in Z_i$
; or -
(iii) the divisor
$-(K_{X_i}+B_{i,t}+{\mathbf {M}_{i,X_i}})$
is pseudo-effective, but it is not nef over every neighborhood of
$z_i\in Z_i$
and
$(X_i,B_{i,t},{\mathbf {M}_{i}})$
is generalized log canonical over a neighborhood of
$z_i \in Z_i$
.
Assume that case (i) holds. Then, we set
We show that
$t_i$
computes a generalized log canonical threshold of coregularity at most c. Indeed, we have that
$$\begin{align*}t_i = \mathrm{glct}((X_i,B_{i}-\mathrm{coeff}_{P_i}(B_i)P_i,{\mathbf{M}_{i}});P_i), \end{align*}$$
so
$t_i$
is a generalized log canonical threshold over
$z_i\in Z_i$
. By construction, the support of
$P_i$
contains a generalized log canonical center of the generalized pair
$(X_i,B_i+t_iP_i,{\mathbf {M}_{i}})$
. Set 
as a nef b-divisor over
$Z_i$
, that is, we set
${\mathbf {N}_{i}}$
to be the b-Cartier closure of
$-(K_{X_i}+B_i+t_iP_i+{\mathbf {M}_{i,X_i}})$
. Then, we have that
$$ \begin{align} (X_i,B_i+t_iP_i,{\mathbf{M}_{i}} + {\mathbf{N}_{i}}) \end{align} $$
is a generalized log Calabi–Yau pair over
$Z_i$
. Furthermore, the generalized log canonical centers of Equation (3.2) are the same as the generalized log canonical centers of
$(X_i,B_i+t_iP_i,{\mathbf {M}_{i}})$
. By [Reference Filipazzi and Svaldi16, Theorem 1.4], up to replacing
$(X_i,B_i+t_iP_i,{\mathbf {M}_{i}})$
with a generalized dlt modification, the support of
$P_i$
contains a generalized log canonical center of
$(X_i,B_i+t_iP_i,{\mathbf {M}_{i}})$
of dimension at most c. Hence,
$t_i$
is a generalized log canonical threshold of coregularity at most c.
Assume that case (ii) holds. Then, we set
In this case, we can find a Mori fiber space structure
$X^{\prime }_i\rightarrow W_i$
over
$Z_i$
such that the following conditions are satisfied:
-
• the generalized pair
$(X^{\prime }_i,B^{\prime }_i-\mathrm {coeff}_{P^{\prime }_i}(B^{\prime }_i)P^{\prime }_i+t_iP^{\prime }_i,{\mathbf {M}_{i}})$
is generalized log Calabi–Yau over
$W_i$
; -
• the prime divisor
$P^{\prime }_i$
is ample over
$W_i$
.
Note that
$(X^{\prime }_i,B^{\prime }_i-\mathrm {coeff}_{P^{\prime }_i}(B^{\prime }_i)P^{\prime }_i+t_iB^{\prime }_i,{\mathbf {M}_{i}})$
has coregularity at most c. We have that
$t_i$
is the coefficient of a component of
$B^{\prime }_i-\mathrm {coeff}_{P^{\prime }_i}(B^{\prime }_i)+t_iP^{\prime }_i$
which is horizontal over
$W_i$
.
From now on, we assume that (i) and (ii) do not happen. Assume that (iii) holds. Then, there exists a birational contraction
$X_i\dashrightarrow X^{\prime }_i$
which is
$(K_{X_i}+B_{i,t_{i,0}}+{\mathbf {M}_{i,X_i}})$
-trivial. Indeed, this contraction is defined by the partial
$-(K_{X_i}+B_{i,t'}+{\mathbf {M}_{i,X_i}})$
-MMP with scaling of
$P_i$
, for
$t'$
close enough to
$t_{i,0}$
as in (iii). By construction, the first scaling factor is
$t'-t_{i,0}$
, and since
$-(K_{X_i}+B_{i,t'}+{\mathbf {M}_{i,X_i}})$
is pseudo-effective over
$Z_i$
and
$X_i \rightarrow Z_i$
is of Fano type, this MMP terminates with a good minimal model. In particular, at the last step of this MMP, the scaling factor is 0. Then,
$X_i'$
is the outcome of the last step where the scaling factor is
$t'-t_{i,0}$
. In particular, we have that
$-(K_{X^{\prime }_i}+B^{\prime }_{i,t}+{\mathbf {M}_{i, X_i'}})$
is nef over
$Z_i$
for
$t>t_{i,0}$
close enough to
$t_{i,0}$
. Note that an N-complement of
$(X_i',B^{\prime }_{i,t_{i,0}},{\mathbf {M}_{X_i'}})$
induces an N-complement of
$(X_i,B_{i,t_{i,0}},{\mathbf {M}_{i}})$
by pulling back, and so an N-complement of
$(X_i,B_i,{\mathbf {M}_{i}})$
. Henceforth, we may replace
$X_i$
with
$X^{\prime }_i$
and keep increasing t. Since
$X_i$
is of Fano type over
$Z_i$
, there are only finitely many birational contractions
$X_i\dashrightarrow X^{\prime }_i$
. Therefore, we can replace
$X_i$
with
$X_i'$
only finitely many times. Thus, after finitely many birational contractions, we either have that
$t_{i,0}=1$
, that
$t_i<1$
is a log canonical threshold or that
$t_i<1$
is a pseudo-effective threshold.
We assume that
$t_{i,0}=1$
. Then there exists a birational contraction
$X_i \dashrightarrow X^{\prime }_i$
and a generalized log canonical pair
$$ \begin{align} (X^{\prime}_i,B^{\prime}_i-(\mathrm{coeff}_{P_i}B^{\prime}_i +\mathrm{coeff}_{P_i}B^{\prime}_{i,m_i})P_i, {\mathbf{M}_{i}}) \end{align} $$
for which the divisor
$$\begin{align*}-(K_{X^{\prime}_i}+B^{\prime}_i-(\mathrm{coeff}_{P_i}B^{\prime}_i +\mathrm{coeff}_{P_i}B^{\prime}_{i,m_i})P_i+{\mathbf{M}_{i,X^{\prime}_i}}) \end{align*}$$
is nef over
$Z_i$
. Note that the coefficients of the boundary of the generalized pair (3.3) belong to
$\Lambda $
and the variety
$X^{\prime }_i$
is of Fano type over
$Z_i$
. The b-nef divisor
$p{\mathbf {M}_{X^{\prime }_i}}$
is b-Cartier. By construction, if the generalized pair (3.3) admits an N-complement, then so does
$(X_i,B_i,{\mathbf {M}_{i}})$
. We can replace
$(X_i,B_i,{\mathbf {M}_{i}})$
with the generalized pair (3.3). By doing so, we decrease the number of components of
$B_{i,m_i}-B_i$
. By the choice of
$m_i$
, the divisor
$B_{i,m_i}-B_i$
cannot be zero after this replacement. Thus, we may pick a new component and start increasing its coefficient (to this end, notice that
$X_i'$
is
$\mathbb {Q}$
-factorial by construction). Note that this process must terminate either with
$t_i<1$
a log canonical threshold or
$t_i<1$
a pseudo-effective threshold. Otherwise, we contradict the definition of
$m_i$
.
Step 2: We show that a subsequence of the
$t_i$
’s is strictly increasing.
Up to passing to a subsequence, we may assume that
$t_i$
is either strictly increasing, strictly decreasing or it stabilizes. The condition
$t_i\in [\mathrm {coeff}_P(B_i),\mathrm {coeff}_P(B_{i,m_i}))$
implies that
$t_i$
must be strictly increasing.
Step 3: We finish the proof of the statement.
If case (i) happens infinitely many times, then we get a contradiction to the ACC for generalized log canonical thresholds with bounded coregularity [Reference Figueroa, Moraga and Peng10, Theorem 1]. If case (ii) happens infinitely many times, then we get a contradiction to Lemma 3.2. In any case, we get a contradiction. Hence, the sequence
$m_i$
has an upper bound.
4 Semilog canonical pairs
In this section, we discuss the index of semilog canonical pairs. We show that to control the index of a semilog canonical log Calabi–Yau pair of coregularity c it suffices to control the index of dlt log Calabi–Yau pairs of coregularity c. To prove the main statement of this section, we will need to use the language of admissible and preadmissible sections. The preliminary results for this section are taken from [Reference Fujino and Gongyo19, Reference Fujino17, Reference Xu44].
The following definition is due to Fujino [Reference Fujino17, Definition 4.1].
Definition 4.1. Let
$(X,B)$
be a possibly disconnected projective semi-dlt pair of dimension n, and assume that
$N(K_X+B)$
is Cartier. Let
$(X',B')$
be its normalization and
$D^n\subset X'$
be the normalization of
$\lfloor B' \rfloor $
. As usual, we denote by
$(D^n,B_{D^n})$
the dlt pair obtained by adjunction of
$(X',B')$
to
$D^n$
. We define the concept of preadmissible and admissible sections in
$H^0(X,{\mathcal {O}_{X}} (I(K_X+B)))$
by induction on the dimension using the two following rules:
-
1. we say that a section
is preadmissible if
$$\begin{align*}s\in H^0(X,\mathcal{O}_X(I(K_X+B))) \end{align*}$$
$s|_{D^n} \in H^0(D^n,\mathcal {O}_{D^n}(I(K_{D^n}+B_{D^n})))$
is admissible. This set is denoted by
$PA(X,I(K_X+B))$
; and
-
2. we say that
is admissible if s is preadmissible and
$$\begin{align*}s\in H^0(X,\mathcal{O}_X(I(K_X+B)) \end{align*}$$
$g^*(s|_{X^{\prime }_i}) = s|_{X^{\prime }_j}$
holds for every crepant birational map
$g\colon (X^{\prime }_i,B_{X^{\prime }_i})\dashrightarrow (X^{\prime }_j,B_{X^{\prime }_j})$
, where
$X'=\sqcup X^{\prime }_i$
are the irreducible components of
$X'$
. The set of admissible sections is denoted by
$A(X,I(K_X+B))$
.
The following lemma is due to Gongyo [Reference Gongyo21, Remark 5.2].
Lemma 4.2. Let
$(X,B)$
be a projective semi-dlt pair for which
$I(K_X+B)\sim 0$
. Let
$\pi \colon (X',B')\rightarrow (X,B)$
be its normalization. Then, a section
$s\in H^0(X,{\mathcal {O}_{X}}(I(K_X+B)))$
is preadmissible (resp. admissible) if and only if
$\pi ^*s \in H^0(X',{\mathcal {O}_{X}}(I(K_{X'}+B')))$
is preadmissible (resp. admissible).
The following lemma allows us to descend linear equivalence from normal varieties to semilog canonical varieties (see, e.g., [Reference Fujino17, Lemma 4.2]).
Lemma 4.3. Let
$(X,B)$
be a projective semilog canonical pair for which
$I(K_X+B)$
is an integral divisor. Let
$(X',B')\rightarrow (X,B)$
be its normalization and
$(Y,B_Y)$
a
$\mathbb {Q}$
-factorial dlt modification of
$(X',B')$
. Assume that
$I(K_Y+B_Y)$
is Cartier. Then, a section
$s\in PA(I(K_Y+B_Y))$
descends to
$H^0(X,{\mathcal {O}_{X}} (I(K_X+B)))$
. In particular, if we have that
$I(K_Y+B_Y)\sim 0$
, and there exists a nowhere vanishing section
$0\neq s\in PA(I(K_Y+B_Y))$
, then we have that
$I(K_X+B)\sim 0$
.
Proof. The first part of the statement is [Reference Fujino17, Lemma 4.2]. Now,
$s \in PA(I(K_Y+B_Y))$
is nowhere vanishing, it descends to a nowhere vanishing section of
${\mathcal {O}_{X}}(I(K_X+B))$
, thus showing that
${I(K_X+B)\sim 0}$
.
In the context of connected dlt pairs, the set of admissible sections is the same as the set of preadmissible sections (see, e.g., [Reference Fujino17, Proposition 4.7]).
Lemma 4.4. Let
$(X,B)$
be a connected projective dlt pair with
$\lfloor B \rfloor \neq 0$
. Assume that
$I(K_X+B)\sim 0$
and I is even. Then, we have that
$$\begin{align*}PA(I(K_X+B)) = A(I(K_X+B)). \end{align*}$$
On the other hand, in the dlt setting, we can lift admissible sections from the boundary to preadmissible sections on the whole pair (see, e.g., [Reference Xu44, Lemma 3.2.14]).
Lemma 4.5. Assume that
$(X,B)$
is a possibly disconnected projective dlt pair. Assume that
$I(K_X+B)\sim 0$
and I is even. Assume that
$$\begin{align*}0\neq s \in A(\lfloor B\rfloor, I(K_X+B)|_{\lfloor B\rfloor}). \end{align*}$$
Then, there exists
$$\begin{align*}0\neq t \in PA(X,I(K_X+B)) \end{align*}$$
for which
$t|_{\lfloor B\rfloor }=s$
.
The following lemma states that the boundedness of indices for klt Calabi–Yau pairs together with the boundedness of B-representations imply the existence of admissible sections (see, e.g., [Reference Xu44, Proposition 3.2.7]).
Lemma 4.6. Let c be a nonnegative integer and
$\Lambda $
be a set of rational numbers satisfying the descending chain condition. Assume Conjecture 1 and Conjecture 2 in dimension c. There is a constant
$I(\Lambda ,c)$
, only depending on
$\Lambda $
and c, satisfying the following. Let
$(X,B)$
be a projective klt log Calabi–Yau pair with coefficients in
$\Lambda $
and dimension c. Then, there is a section
$$\begin{align*}0\neq s \in A(X,I(\Lambda,c)(K_X+B)). \end{align*}$$
Note that for a klt log Calabi–Yau pair an admissible section is nothing else than a section which is invariant under the pull-back via crepant birational transformations.
Finally, we prove the following lemma that allows us to produce admissible sections on possibly disconnected dlt pairs, once we know the existence of admissible sections on connected dlt pairs. The proof is similar to that of [Reference Xu44, Proposition 3.2.8].
Lemma 4.7. Let d be a positive integer. Let
$(X,B)$
be a possibly disconnected projective dlt log Calabi–Yau pair. Assume that for every component
$(X_i,B_i)$
of
$(X,B)$
, we have a nontrivial section on
$A(X_i,I(K_{X_i}+B_i))$
. Then, we have that
$A(X,I(K_X+B))$
admits a nowhere vanishing section.
Proof. Let
$(X,B)$
be a possibly disconnected projective dlt log Calabi–Yau pair. We write
$(X_i,B_i)$
for its components for
$i\in \{1,\dots ,k\}$
. By assumption, for each i, we have
$$\begin{align*}0\neq s_i \in A(X_i,I(K_{X_i}+B_i)). \end{align*}$$
For
$\lambda _i\in \mathbb {C}$
, we define
Let
$G=\mathrm {Bir}(X,B)$
. We claim that the image of G in
$GL(H^0(X,{\mathcal {O}_{X}} (I(K_X+B))))$
is finite. We denote by
$$\begin{align*}\rho_I \colon \mathrm{Bir}(X,B)\rightarrow GL(H^0(X,{\mathcal{O}_{X}}(I(K_X+B)))) \end{align*}$$
the usual map induced by pulling back sections. Thus, we want to show that
$\rho _I(G)$
is finite. By [Reference Fujino and Gongyo19], the finiteness of
$\rho _I(G)$
is known if X is connected. Thus, we need to reduce the disconnected case to the connected one. Note that for every
$g\in G$
, we have that
$\rho _I(g)^{k!}$
has finite order by [Reference Fujino and Gongyo19, Theorem 3.15] and the fact that the order of any permutation in
$S_k$
divides
$k!$
. Hence, we conclude that
$\rho _I(G)$
is a finitely generated subgroup of finite exponent of a general linear group, where the bound is determined by
$k!$
and the least common multiple of the orders of the pluricanonical representations of each irreducible component. Indeed, notice that
$\rho _I(G)$
is finitely generated, as it is the extension of two finite groups: the image via
$\rho _I$
of the subgroup fixing the irreducible components of X, which is isomorphic to the product of the pluricanonical representations of each irreducible component (hence, a finite group by [Reference Fujino and Gongyo19]), and a subgroup of
$S_k$
. By a theorem due to Burnside, known as the bounded Burnside problem for linear groups [Reference Ceccherini-Silberstein and D’Adderio8, Theorem 6.13], we conclude that
$\rho _I(G)$
is finite.
Consider the section
By construction, we have that
$t\in A(X,I(K_X+B))$
. Indeed, t is invariant under the action of any birational transformation of
$(X,B)$
. Thus, the restriction of t to every log canonical center is also invariant. It suffices to show that t is nontrivial on each component of X. By considering orbits of the action, we may assume that
$\mathrm {Bir}(X,B)$
acts transitively on the components of X. Consider the basis
$((0,\dots ,s_i,\dots ,0))_{1 \leq i \leq k}$
of
$H^0(X,{\mathcal {O}_{X}} (I(K_X+B)))$
. Since the sections
$s_i$
are admissible, in this basis, the action of
$\rho _I(g)$
is represented by a matrix whose diagonal entries are either 0 (if
$g(X_i)\neq X_i$
) or 1 (if
$g(X_i)=X_i$
). Hence, by observing that the matrix associated to the identity element of G is the identity matrix, it follows that the action of
$\sum _{\sigma \in G}\sigma $
in this basis is given by a nontrivial matrix whose diagonal entries are all integers greater than or equal to 1. By the transitivity of the action and the fact that the action of
$\sum _{\sigma \in G}\sigma $
is given by a matrix whose diagonal are positive integers, we deduce that we can find
$\lambda _i\in \mathbb {C}$
for which t is nonzero on all components.
Now, we are ready to prove the main theorem of this section.
Theorem 4.8. Let c be a nonnegative integer and
$\Lambda $
be a set of rational numbers satisfying the descending chain condition. Assume Conjecture 1 and Conjecture 2 in dimension c. There is a constant
$I(\Lambda ,c)$
, only depending on
$\Lambda $
and c, satisfying the following. Let
$(X,B)$
be a projective dlt pair with coefficients in
$\Lambda $
and coregularity c. Assume that
$I(\Lambda ,c)(K_X+B)\sim 0$
. Then, there is a nowhere vanishing admissible section
$$\begin{align*}0\neq s \in A(X,I(\Lambda,c)(K_X+B)). \end{align*}$$
Proof. Let
$I(\Lambda ,c)$
be the positive integer given by Lemma 4.6. Without loss of generality, we may assume that
$I(\Lambda ,c)$
is even.
By induction on i, we prove that every i-dimensional log canonical center V of
$(X,B)$
satisfies that
$$ \begin{align} 0\neq s_V \in A(V,I(\Lambda,c)(K_V+B_V)), \end{align} $$
where
$(V,B_V)$
is the pair obtained by dlt adjunction of
$(X,B)$
to V. If
$i=c$
, then the pair is klt and the statement follows from Lemma 4.6.
Now, assume that the statement holds for every irreducible i-dimensional dlt center of
$(X,B)$
. Let W be a log canonical center of
$(X,B)$
of dimension
$i+1$
. The pair
$(W,B_W)$
obtained from adjunction is dlt of dimension
$i+1$
and it holds that
$I(\Lambda ,c)(K_W+B_W)\sim 0$
. Let
$W_0$
be the union of all the log canonical centers of
$(W,B_W)$
. Let
$(W_0,B_{W_0})$
be the pair obtained by performing adjunction of
$(W,B_W)$
to
$(W_0,B_{W_0})$
. Hence,
$(W_0,B_{W_0})$
is an i-dimensional semi-dlt pair with
$I(\Lambda ,c)(K_{W_0}+B_{W_0})\sim 0$
. Observe that
$W_0$
may have multiple irreducible components. Let
$n_U\colon U\rightarrow W_0$
be the normalization of
$W_0$
. Let
$(U,B_{U})$
be the pair obtained by log pull-back of
$(W_0,B_{W_0})$
to U. Then, we have that
$(U,B_{U})$
is a possibly disconnected projective dlt pair of dimension i and coregularity c. By [Reference Filipazzi and Svaldi16, Theorem 1.4], we know that every component has coregularity c. Furthermore, we have that
$I(\Lambda ,c)(K_{U}+B_{U})\sim 0$
. By Equation (4.1) in dimension i, we have that each irreducible component
$U_j$
of U satisfies that
$$\begin{align*}0\neq s_{U,j} \in A(U_j,I(\Lambda,c)(K_{U_j}+B_{U_j})). \end{align*}$$
By Lemma 4.7, we conclude that there exists a nowhere vanishing section
$$\begin{align*}0\neq s_{U} \in A(U,I(\Lambda,c)(K_U+B_U)). \end{align*}$$
By Lemma 4.3, we conclude that this section descends to
$s_{W_0} \in H^0(W_{0},{\mathcal {O}_{W_0}}(I(\Lambda ,c)(K_{W_0}+B_{W_0})))$
. Note that we have
$n_U^* s_{W_0}=s_U$
. By Lemma 4.2, we conclude that
$s_{W_0} \in A(W_0,I(\Lambda ,c)(K_{W_0}+B_{W_0}))$
. By Lemma 4.5, we conclude that there exists
$$\begin{align*}0\neq t_{W} \in PA(W,I(\Lambda,c)(K_W+B_W)). \end{align*}$$
Finally, since W is connected, we conclude by Lemma 4.4, that there is a section
$$\begin{align*}0\neq t_W \in A(W,I(\Lambda,c)(K_W+B_W)). \end{align*}$$
This finishes the inductive step.
We conclude, that for every
$i \in \{c,\dots ,\dim X\}$
, every i-dimensional log canonical center of
$(X,B)$
admits an admissible section. In particular, we get a nowhere vanishing section
$0\neq s_X \in A(X,I(\Lambda ,c)(K_X+B))$
as claimed.
The previous theorem allows controlling the index of semilog canonical pairs once we can control the index of their normalization.
Theorem 4.9. Let c be a nonnegative integer and
$\Lambda $
be a set of rational numbers satisfying the descending chain condition. Assume Conjecture 1 and Conjecture 2 in dimension c. There is a constant
$I(\Lambda ,c)$
, only depending on
$\Lambda $
and c, satisfying the following. Let
$(X,B)$
be a projective semilog canonical pair with coefficients in
$\Lambda $
and coregularity c. Let
$(Y,B_Y)$
be a
$\mathbb {Q}$
-factorial dlt modification of a normalization of
$(X,B)$
. Assume that
$I(\Lambda ,c)(K_Y+B_Y)\sim 0$
. Then, we have that
$I(\Lambda ,c)(K_X+B)\sim 0$
.
Proof. We can consider
$I(\Lambda ,c)$
as in Theorem 4.8. By Theorem 4.8 and Lemma 4.7, we know that there exists a nowhere vanishing preadmissible section
$$\begin{align*}0\neq s_Y \in PA(Y,I(\Lambda,c)(K_Y+B_Y)). \end{align*}$$
By Lemma 4.3, we conclude that the linear equivalence
$I(\Lambda ,c)(K_X+B)\sim 0$
holds.
In the case of dimension 0, Conjecture 1 and Conjecture 2 are trivial. Indeed, the only variety of interest is
$\mathrm {Spec}(\mathbb K)$
, no boundary is allowed for dimensional reasons, and
$\mathrm {Bir}(\mathrm {Spec}(\mathbb K))$
is trivial. Thus, we get the following statement.
Theorem 4.10. Let
$(X,B)$
be a projective semilog canonical Calabi–Yau pair of coregularity 0 and
$\lambda $
be its Weil index. Let
$(Y,B_Y)$
be a
$\mathbb {Q}$
-factorial dlt modification of a normalization of
$(X,B)$
. If
$2\lambda (K_Y+B_Y)\sim 0$
, then
$2\lambda (K_X+B)\sim 0$
.
Finally, Conjecture 1 and Conjecture 2 are known in the case of klt pairs of dimension 1 or 2 (see, e.g., [Reference Xu44]). We get the following statement.
Theorem 4.11. Let
$\Lambda $
be a set of rational numbers satisfying the descending chain condition. There exists a constant
$I(\Lambda )$
, only depending on
$\Lambda $
, satisfying the following. Let
$(X,B)$
be a projective semilog canonical Calabi–Yau pair of coregularity 1 (resp. 2) such that B has coefficients in
$\Lambda $
. Let
$(Y,B_Y)$
be a
$\mathbb {Q}$
-factorial dlt modification of a normalization of
$(X,B)$
. If
$I(\Lambda )(K_Y+B_Y)\sim 0$
, then
$I(\Lambda )(K_X+B)\sim 0$
.
Let us note that Conjecture 1 is known for klt
$3$
-folds (see, e.g., [Reference Xu44]). However, Conjecture 2 is still unknown in the case of klt Calabi–Yau
$3$
-folds.
4.1 Lifting complements from nonnormal divisors in fibrations
In this subsection, we prove a statement about lifting complements from nonnormal divisors in fibrations.
Theorem 4.12. Let
$\lambda $
, d and c be nonnegative integers. Assume that Conjecture 1
$(c)$
and Conjecture 2
$(c)$
hold. Let 
be the integer provided by Theorem 6
$(d-1,c)$
. Up to replacing I with a bounded multiple, further assume that I is divisible by the integer provided by Theorem 4.9
$(D_\lambda ,c)$
. Let
$(X,B)$
be a projective d-dimensional log Calabi–Yau pair. Assume that the following conditions hold:
-
• X is
$\mathbb {Q}$
-factorial and klt; -
• there is a fibration
$X\rightarrow W$
, which is a
$(K_X + B - S)$
-Mori fiber space; -
• a component
$S\subset \lfloor B\rfloor $
which is ample over the base and
$(X,B-S)$
is dlt; -
• the morphism
$S \rightarrow W$
has connected fibers; -
• the coefficients of B belong to
$D_\lambda $
; and -
• the pair
$(X,B)$
has coregularity c.
Then, we have that
$I(K_X+B)\sim 0$
.
Proof. The proof is formally identical to the proof of Theorem 2.31, with the only difference that we need to appeal to the results in § 4 since S may not be normal. For completeness, we include a full proof of the statement.
Let
$(X,B)$
, S,
$f \colon X \rightarrow W$
and 
be as in the statement. First, we show that we can apply the inductive hypothesis to S.
By [Reference Fujino and Gongyo19, Example 2.6], the pair obtained by adjunction of
$(X,B-\epsilon \lfloor B\rfloor +\epsilon S)$
to S is semilog canonical. In particular, S is
$S_2$
. In turn, by letting
$\epsilon \to 0$
, it follows that the pair obtained by adjunction of
$(X,B)$
to S is semilog canonical. In particular, let
$(S,B_S)$
denote the pair obtained by adjunction from
$(X,B)$
, and let
$(S^\nu , {B}_{S^{\nu }})$
denote its normalization. By [Reference Figueroa, Moraga and Peng10, Lemma 2.28],
$(S^\nu ,{B}_{S^{\nu }})$
has coregularity c. Then, by Lemma 2.17,
$(S^\nu ,B _{S^{\nu }})$
satisfies the assumptions of Theorem 6
$(d-1,c)$
with constant I. Then, by Theorem 4.9, we have
$$ \begin{align} I ({K_{S}} + B_S) \sim 0. \end{align} $$
By [Reference Kollár29, Proposition 4.32], S is seminormal. Then, by [Reference Filipazzi and Inchiostro12, Lemma 2.3] and the fact that
$S \rightarrow W$
has connected fibers, we have
$f_* {\mathcal {O}_{S}} = {\mathcal {O}_{W}}$
. Lastly, we observe that, if
$\dim X - \dim W =1$
, since
$S \rightarrow W$
has connected fibers, it follows that
$(B-S)_{\mathrm {hor}} \neq 0$
.
Now, consider the short exact sequence
$$ \begin{align} 0 \rightarrow {\mathcal{O}_{X}}(I(K_{X}+B)-S) \rightarrow {\mathcal{O}_{X}}(I(K_{X}+B)) \rightarrow {\mathcal{O}_{S}}(I(K_{S}+B_{S})) \rightarrow 0. \end{align} $$
The exactness of Equation (4.3) follows verbatim as the exactness of Equation (2.3). Since
$I(K_{X}+B)-S\sim _{\mathbb {Q},f} -S$
, the divisor
$-S$
is f-ample and
$\dim W < \dim X$
, we have
$$\begin{align*}f_*{\mathcal{O}_{X}}(I(K_{X}+B)-S)=0. \end{align*}$$
Similarly, we write
$$\begin{align*}I(K_{X}+B)-S\sim_{\mathbb{Q},f} -S \sim_{\mathbb{Q},f} K_X +(B-S). \end{align*}$$
First, assume that
$B_{\mathrm {hor}} \neq S$
. Note that X is klt and
$B-S$
is f-ample since f is a Mori fiber space and the assumption that
$B_{\mathrm {hor}} \neq S$
. Thus, by the relative version of Kawamata–Viehweg vanishing, we have
$$\begin{align*}R^1f_*{\mathcal{O}_{X}}(I(K_{X}+B)-S)=0. \end{align*}$$
Now, assume that
$B_{\mathrm {hor}}=S$
. By the equality
$B_{\mathrm {hor}}=S$
and the fact that f is a Mori fiber space, we have
$$\begin{align*}I(K_{X}+B)-S\sim_{\mathbb{Q},f} -S \sim_{\mathbb{Q},f} K_X +(B-S) \sim_{\mathbb{Q},f} K_X + B_{\mathrm{ver}} \sim_{\mathbb{Q},f} K_X. \end{align*}$$
Thus, we obtain
$$ \begin{align*}I(K_{X}+B)-S - K_X \sim_{\mathbb{Q},f} 0. \end{align*} $$
Since X is a klt variety, by [Reference Kawamata, Matsuda and Matsuki28, Theorem 1-2-7], we have that
$R^1f_* {\mathcal {O}_{X}}(I(K_X+B)-S)$
is torsion free. To conclude that it vanishes, it suffices to show that it has rank 0. As observed at the end of the previous paragraph, we have that
$\dim X \geq \dim Z +2$
under the additional assumption
$B_{\mathrm {hor}}=S$
. Then, by applying Kawamata–Viehweg vanishing to a general fiber [Reference Kollár, Mori, Clemens and Corti30, Theorem 2.70], we conclude that the rank of
$R^1f_*{\mathcal {O}_{X}}(I(K_{X}+B)-S)$
is 0, thus implying that
$R^1f_*{\mathcal {O}_{X}}(I(K_{X}+B)-S)=0$
.
Therefore, by pushing forward Equation (4.3) via f, we obtain
$$\begin{align*}f_* {\mathcal{O}_{X}}(I(K_{X}+B)) \simeq f_* {\mathcal{O}_{S}}(I(K_{S}+B_{S})). \end{align*}$$
Now, taking global sections, we have
$$ \begin{align} H^0(X, {\mathcal{O}_{X}}(I(K_{X}+B))) = H^0(S, {\mathcal{O}_{S}}(I(K_{S}+B_{S})))=H^0(S, {\mathcal{O}_{S}}) \neq 0. \end{align} $$
By [Reference Filipazzi, Mauri and Moraga13, Lemma 3.1], (4.4) implies that
$I(K_{X}+B) \sim 0$
.
5 Relative complements
In this section, we prove an inductive statement regarding the existence of complements for Fano type morphisms with bounded coregularity.
5.1 Lifting sections from a divisor
In this subsection, we introduce some tools to lift complements from a divisor of a log Fano pair. Let X be a Fano type variety and
$(X,B,\mathbf {M})$
be a generalized log canonical pair for which
$-(K_X+B+{\mathbf {M}_{X}})$
is nef. The main theorem of this subsection implies that we can lift complements for
$(X,B,\mathbf {M})$
from a component S of
$\lfloor B\rfloor $
under some suitable conditions explained in the following theorem.
Theorem 5.1. Let d, c and p be nonnegative integers and
$\mathcal {R} \subset \mathbb {Q}_{>0}$
be a finite set. Let 
be the integer provided by Theorem 7
$(d-1,c)$
. Assume that N is divisible by p and by
$I_{\mathcal {R}}$
. Let
$\pi \colon X \rightarrow Z$
be a Fano type morphism, where X is a d-dimensional variety. Let
$(X,B,\mathbf {M})$
be a generalized log canonical pair over Z and
$z \in Z$
a point satisfying the following conditions:
-
• the generalized pair
$(X,B, \mathbf {M})$
has coregularity at most c over z; -
• the divisor B has coefficients in
$\mathcal {R}$
; -
•
$p\mathbf {M}$
is b-Cartier; and -
• the divisor
$-(K_X+B+{\mathbf {M}_{X}})$
is nef over Z.
Assume that there exists
$B_1\leq B$
and
$\alpha \in (0,1]$
for which:
-
• the generalized pair
$(X,B_1,\alpha \mathbf {M})$
is generalized log canonical but it is not generalized klt over z; -
• the divisor
$-(K_X+B_1+\alpha {\mathbf {M}_{X}})$
is big and nef over Z.
Then,
$(X,B,\mathbf {M})$
admits an N-complement over z.
In order to prove the main theorem of this section, we take inspiration from [Reference Birkar3, § 6.6]. In particular, we will first prove a weaker statement.
Proposition 5.2. Let d, c and p be nonnegative integers and
$\mathcal {R} \subset \mathbb {Q}_{>0}$
be a finite set. Let 
be the integer provided by Theorem 7
$(d-1,c)$
. Assume that N is divisible by p and by
$I_{\mathcal {R}}$
. Let
$\pi \colon X \rightarrow Z$
be a Fano type morphism, where X is a d-dimensional variety. Let
$(X,B,\mathbf {M})$
be a
$\mathbb {Q}$
-factorial generalized log canonical pair over Z and
$z \in Z$
a point satisfying the following conditions:
-
• the generalized pair
$(X,B, \mathbf {M})$
has coregularity at most c over z; -
• the divisor B has coefficients in
$\mathcal {R}$
; -
•
$p\mathbf {M}$
is b-Cartier; and -
• the divisor
$-(K_X+B+{\mathbf {M}_{X}})$
is nef over Z.
Assume there exists a boundary
$\Gamma $
on X and
$\alpha \in (0,1)$
for which:
-
• the generalized pair
$(X,\Gamma ,\alpha \mathbf {M})$
is generalized plt over z; -
• we have that
$S=\lfloor \Gamma \rfloor \subset \lfloor B \rfloor $
intersects the fiber over z; and -
• the divisor
$-(K_X+\Gamma +\alpha {\mathbf {M}_{X}})$
is ample over Z.
Then,
$(X,B,\mathbf {M})$
admits an N-complement over z.
Proof. We will proceed by induction on the dimension, keeping the coregularity constant. Over several steps, we will lift a complement from a divisor. Since the statement is local over
$z \in Z$
, in the course of the proof we are free to shrink Z around z. In particular, all linear equivalences that are relative to Z can be assumed to hold globally. We add the fractions with denominator p to the set
$\mathcal {R}$
. This does not change the value of N, hence proving the statement for this new finite set is the same as proving it for the original
$\mathcal {R}$
.
Step 1. In this step, we reduce to the case where
$(X,B,\mathbf {M})$
is
$\mathbb {Q}$
-factorial generalized dlt.
Let
$(X',B', \mathbf {M})$
be a
$\mathbb {Q}$
-factorial dlt modification of
$(X,B,\mathbf {M})$
. Pick E exceptional such that
$-E$
is ample over X. Notice that the existence of E is guaranteed by the hypothesis that X is
$\mathbb Q$
-factorial. Also, let
$(X',\Gamma ',\alpha \mathbf {M})$
be the trace of
$(X,\Gamma ,\mathbf {M})$
on
$X'$
. We observe that
$\Gamma '$
may no longer be effective.
Since
$(X,\Gamma ,\alpha \mathbf {M})$
is generalized plt with
$\lfloor \Gamma \rfloor \subset \lfloor B \rfloor $
and
$X' \rightarrow X$
only extracts divisor that appear with coeffcient 1 in
$B'$
, for
$0 < \lambda \ll 1$
, the datum of
$(X',(1-\lambda )B'+\lambda \Gamma ',(1-\lambda + \lambda \alpha )\mathbf {M})$
is actually a generalized pair (i.e., its boundary is effective) and it is generalized plt with
$1-\lambda + \lambda \alpha \in (0,1)$
. Furthermore,
$$ \begin{align*}-({K_{X'}} + (1-\lambda)B'+\lambda \Gamma' + (1-\lambda + \lambda \alpha){\mathbf{M}_{X'}}) \end{align*} $$
is the pull-back of a divisor on X that is relatively ample over Z. Thus, for
$\varepsilon>0$
small enough, we have that
$$ \begin{align*}-({K_{X'}} + (1-\lambda)B'+\lambda \Gamma' + \varepsilon E + (1-\lambda + \lambda \alpha){\mathbf{M}_{X'}}) \end{align*} $$
is ample over Z. Hence, up to replacing
$(X,B,\mathbf {M})$
with
$(X',B',\mathbf {M})$
and
$(X,\Gamma ,\alpha \mathbf {M})$
with
$(X',(1-\lambda )B'+\lambda \Gamma ' + \varepsilon E,(1-\lambda + \lambda \alpha )\mathbf {M})$
we can assume that X is
$\mathbb {Q}$
-factorial and
$(X,B, \mathbf {M})$
is generalized dlt.
Step 2. In this step, we prove that
$S \rightarrow \pi (S)$
is a contraction.
As
$\alpha {\mathbf {M}_{X}}$
is the push-forward of a divisor that is nef over Z, its diminished base locus does not contain any divisor. Let
$\pi : X' \rightarrow X$
be a model where
$\mathbf {M}$
descends. Let
$K_{X'}+\Gamma '+\alpha {\mathbf {M}_{X'}}$
be the crepant pullback of
$K_X +\Gamma + \alpha {\mathbf {M}_{X}}$
(this
$\Gamma '$
is different from the one defined in step 1). For any
$0<\delta < 1 $
, we can write
$$\begin{align*}(1-\delta)(K_{X'}+\Gamma' +\alpha {\mathbf{M}_{X'}})=K_{X'}+\Gamma' +(\alpha {\mathbf{M}_{X'}}-\delta (K_{X'}+\Gamma' +\alpha {\mathbf{M}_{X'}})).\end{align*}$$
As
$\alpha {\mathbf {M}_{X'}}$
is nef and
$-(K_{X'}+\Gamma ' +\alpha {\mathbf {M}_{X'}})$
is big and nef over Z, by [Reference Lazarsfeld32, Example 2.2.19] there exists an effective divisor
$E'$
such that
$\alpha {\mathbf {M}_{X'}}-\delta (K_{X'}+\Gamma ' +\alpha {\mathbf {M}_{X'}}) \sim _{\mathbb {Q}} A_{k}'+\frac {1}{k}E'$
, for all positive integers k, where each
$A_k'$
is ample over Z.
So, we can write
$(1-\delta )(K_{X'}+\Gamma ' +\alpha {\mathbf {M}_{X'}})\sim _{\mathbb {Q}} K_{X'}+\Gamma '+A_k'+\frac {1}{k}E' $
. If we choose k large enough and
$A_k'$
generically, then the subpair
$(X',\Gamma '+A_k'+\frac {1}{k}E')$
is sub-plt. With those choices fixed, we define
$A=\pi _\ast A_k'$
,
$E=\frac {1}{k}\pi _\ast E'$
. Therefore,
$$\begin{align*}(1-\delta)(K_{X}+\Gamma +\alpha {\mathbf{M}_{X}})\sim _{\mathbb{Q}} K_X +\Gamma +A+E,\end{align*}$$
with
$(X,A+E+\Gamma )$
being plt. Call 
. For
$\delta $
small enough, we have that
$-(K_X+G)$
is ample over Z and
$\lfloor G \rfloor = S$
. From the exact sequence
$$ \begin{align*}0 \rightarrow \mathcal{O}_X (-S) \rightarrow \mathcal{O}_X\rightarrow \mathcal{O}_S \rightarrow 0, \end{align*} $$
we get the exact sequence
$$ \begin{align*}\pi_* \mathcal{O}_X\rightarrow \pi_* \mathcal{O}_S \rightarrow R^1 \pi_* \mathcal{O}_X(-S). \end{align*} $$
Since
$-S= K_X+G -S -(K_X +G) $
, with
$(X,G-S)$
being klt and
$-(K_X+G)$
being ample over Z, we have that
$R^1 \pi _* \mathcal {O}_X(-S)=0$
by the relative Kawamata–Viehweg vanishing theorem. Therefore,
$\pi _* \mathcal {O}_X \rightarrow \pi _*\mathcal {O}_S$
is surjective.
Let
$g \circ \pi ' \colon S \rightarrow Z' \rightarrow Z$
be the Stein factorization of
$\pi \colon S \rightarrow Z$
. Then
$\mathcal {O}_Z=\pi _* (\mathcal {O}_X)\rightarrow \pi _* \mathcal {O}_S=g_*\mathcal {O}_{Z'}$
is surjective. As
$\mathcal {O}_Z \rightarrow g_*\mathcal {O}_{Z'}$
factors as
$\mathcal {O}_Z \rightarrow \mathcal {O}_{\pi (S)}\rightarrow g_*\mathcal {O}_{Z'}$
, the morphism
$\mathcal {O}_{\pi (S)} \rightarrow g_*(\mathcal {O}_{Z'})$
is surjective. Then, it is an isomorphism, as the map
$Z' \rightarrow Z$
is finite. Hence,
$Z' \rightarrow \pi (S)$
is an isomorphism and
$S \rightarrow \pi (S)$
is a contraction. Restricting
$K_X+G$
to S shows that S is of Fano type over
$\pi (S)$
.
Step 3. In this step, we use adjunction and consider a complement on S.
Consider a log resolution
$f \colon X' \rightarrow X$
of
$(X,B, \mathbf {M})$
such that
$\mathbf {M}$
descends on
$X'$
, and write 
. Let
$S'$
be the strict transform of S and
$g \colon S' \rightarrow S$
be the induced morphism. Let
$(S, B_S, \mathbf {N})$
be the generalized pair obtained by adjunction of
$(X,B,\mathbf {M})$
to S. By Lemma 2.17, the coefficients of
$B_S$
are in
$D(\mathcal {R})$
and the b-divisor
$p\mathbf {N}$
is b-Cartier. By Lemma 2.24, the coregularity of
$(S,B_S,\mathbf {N})$
is at most c. By Theorem 7
$(d-1,c)$
if
$\dim \pi (S) =0$
or by the inductive hypothesis if
$\dim \pi (S)>0$
, the divisor
$K_S+B_S+{\mathbf {M}_{S}}$
has an N complement
$B_{S}^{+}$
over z with coregularity at most c. In the following steps, we will lift
$B_{S}^{+}$
to an N-complement
$B_X^{+}$
of
$K_X+B+{\mathbf {M}_{X}}$
over z with coregularity at most c.
Step 4. In this step, we introduce some divisors and prove some properties of these divisors.
Define 
and 
. We write 
. Now, we define a divisor
$P_{X'}$
in the following way. For any prime divisor
$D_{X'} \neq S'$
, we set
$\operatorname {\mathrm {coeff}}_{D_{X'}}(P_{X'})=-\operatorname {\mathrm {coeff}}_{D_{X'}}\lfloor \Gamma _{X'}+N\Omega _{X'}-\lfloor (N+1)\Omega _{X'} \rfloor \rfloor $
and
$\operatorname {\mathrm {coeff}}_{S'}(P_{X'})=0$
. Hence,
$P_{X'}$
is an integral divisor such that 
is a boundary,
$(X',J_{X'}, \alpha {\mathbf {M}_{X'}})$
is generalized plt and
$\lfloor J_{X'} \rfloor =S'$
. For
$D_{X'}\neq S'$
not exceptional over X, as
$NB$
is integral, we have that
$\operatorname {\mathrm {coeff}}_{D_{X'}}(N\Omega _{X'})$
is an integer. Thus,
$\operatorname {\mathrm {coeff}}_{D_{X'}}\lfloor (N+1)\Omega _{X'}\rfloor = \operatorname {\mathrm {coeff}}_{D_{X'}} (N\Omega _{X'})$
. So,
$\operatorname {\mathrm {coeff}}_{D_{X'}}(P_{X'})=-\operatorname {\mathrm {coeff}}_{D_{X'}}(\Gamma _{X'})=0.$
We conclude that
$P_{X'}$
is exceptional over X.
Step 5. In this step, we lift sections from
$S'$
to
$X'$
using Kawamata–Viehweg vanishing.
Observe that:
$$ \begin{align*} T_{X'}+ P_{X'} &= N \Omega_{X'} - \lfloor (N+1)\Omega_{X'} \rfloor -N (K_{X'}+B_{X'}+{\mathbf{M}_{X'}}) +P_{X'}\\ &= K_{X'} +\Gamma_{X'}-(K_{X'} +\Gamma_{X'}) +N \Omega_{X'} - \lfloor (N+1)\Omega_{X'} \rfloor -N (K_{X'}+B_{X'}+ {\mathbf{M}_{X'}}) +P_{X'}\\ &= K_{X'} +J_{X'} -(K_{X'}+\Gamma_{X'})-N(K_{X'}+B_{X'}+ {\mathbf{M}_{X'}}). \end{align*} $$
Then, we have that
$-(K_{X'}+\Gamma _{X'}+\alpha {\mathbf {M}_{X'}})-N(K_{X'}+B_{X'}+{\mathbf {M}_{X'}})+\alpha {\mathbf {M}_{X'}}$
is big and nef over Z and
$(X',J_{X'}-S')$
is klt. Therefore, up to shrinking Z around z, the relative Kawamata–Viehweg vanishing theorem implies that
$h^1(X',{\mathcal {O}_{X'}}(T_{X'}+P_{X'}-S'))=0$
. So, we obtain
$$ \begin{align*}H^0(X',{\mathcal{O}_{X'}}(T_{X'}+P_{X'})) \rightarrow H^0(X',{\mathcal{O}_{X'}}((T_{X'}+P_{X'} )\mid_{S'})) \rightarrow H^1(X',{\mathcal{O}_{X'}}(T_{X'}+P_{X'}-S')) =0.\end{align*} $$
This means that we can lift sections of
$(T_{X'}+P_{X'})\mid _{S'}$
from
$S'$
to
$X'$
.
Step 6. In this step, we introduce a divisor
$G_{S'}$
which is linearly equivalent to
$(T_{X'}+P_{X'})|_{S'}$
.
We have
$-N(K_S +B_S+{\mathbf {N}_{S}}) = -N(K_S+B^+_S+B_S-B^+_S +{\mathbf {N}_{S}})\sim -N(B_S-B^+_S)=N(B^+_S-B_S) \geq 0$
. Define 
. Then, we have that
$-N(K_{S'}+B_{S'}+{\mathbf {N}_{S'}})\sim Ng^*( B^+_S-B_S) \geq 0$
. Then, it follows that
$-N(K_{X'}+B_{X'}+{\mathbf {M}_{X'}})\mid _{S'}= -N(K_{S'} +B_{S'}+{\mathbf {N}_{S'}})\sim N g^*(B^+_S-B_S)$
. We define 
. By definition, we have
$G_{S'} \sim (T_{X'}+P_{X'})\mid _{S'}$
.
Step 7. In this step, we prove that
$G_{S'}$
is effective and that it lifts to an effective divisor
$G_{X'}$
on
$X'$
.
Assume
$G_{S'}$
is not effective, then there exists some prime divisor
$C_{S'}$
with
$\operatorname {\mathrm {coeff}}_{C_{S'}}(G_{S'})<0$
. As
$N g^*(B^+_S-B_S)$
and
$P_{X'}$
are effective, we must have that
$\operatorname {\mathrm {coeff}} _{C_{S'}}(N \Omega _{X'}\mid _{S'} - \lfloor (N+1)\Omega _{X'}\mid _{S'} \rfloor )$
is negative. Since
$X'$
is a log resolution, we have that the restriction to
$S'$
commutes with taking the integral (resp. fractional) part of a divisor whose support is involved in the log resolution. In particular, observe that
$$\begin{align*}\operatorname{\mathrm{coeff}} _{C_{S'}}(N \Omega_{X'}\mid_{S'} - \lfloor (N+1)\Omega_{X'}\mid_{S'} \rfloor)=\operatorname{\mathrm{coeff}} _{C_{S'}}(-\Omega _{X'}\mid_{S'} + \{ (N+1)\Omega_{X'}\mid_{S'} \}) \geq -\operatorname{\mathrm{coeff}}_{C_{S'}}(\Omega_{X'} \mid_{S'})>-1. \end{align*}$$
As
$G_{S'}$
is integral by the previous inequality its coefficients cannot be negative. Therefore, by Step 4, we can lift
$G_{S'}$
to an effective divisor
$G_{X'} \sim T_{X'}+P_{X'}$
with support not containing
$S'$
and such that
$G_{X'}\mid _{S'} =G_{S'}$
.
Step 8. In this step, we introduce a divisor
$B^+\geq B$
for which
$NB^+ \sim -N(K_X+{\mathbf {M}_{X}})$
.
Since
$NB$
is integral,
$\lfloor (N+1)\Omega \rfloor = N\Omega $
, where
$\Omega $
is the push-forward of
$\Omega _{X'}$
. Similarly, we call T, P and G the push-forwards of
$T_{X'}$
,
$P_{X'}$
and
$G_{X'}$
, respectively. We have that
$P=0$
as
$P_{X'}$
is exceptional and therefore
$T=T+P \sim G$
. Hence, we have that
$-N(K_X+B+{\mathbf {M}_{X}})=T=T+P\sim G \geq 0$
. Therefore,
$N(K_X+B^+ + {\mathbf {M}_{X}})\sim 0$
, where we define 
.
Step 9. In this step, we prove that
$(X,B^+, \mathbf {M})$
is generalized log canonical over some neighbourhood of z, thus proving that
$B^+$
is an N-complement for
$(X,B,\mathbf {M})$
over z.
We first prove that
$\frac {1}{N}G \mid _S =B^+_S-B_S$
. Note that we have the following chain of
$\mathbb {Q}$
-linear equivalences:
Since
$N\Omega $
is integral, we have that
$\lfloor (N+1)\Omega \rfloor =N\Omega $
. Therefore, as
$P_{X'}$
is f-exceptional,
$f_{*}(R_{X'})=G$
and
$R_{X'}$
is the pull-back of G. Observe that
$$\begin{align*}Ng^*(B^+_S-B_S)=G_{S'}-P_{S'} + \lfloor(N+1)\Omega_{X'}\mid_{S'} \rfloor - N\Omega_{X'}\mid_{S'}= (G_{X'}-P_{X'}+\lfloor(N+1)\Omega_{X'} \rfloor - N\Omega_{X'})\mid_{S'}= R_{X'} \mid_{S'}. \end{align*}$$
Therefore,
$g^*(B^+_S-B_S)=\frac {1}{N} R_{X'}\mid _{S'}=g^*(\frac {1}{N}G\mid _{S})$
, implying that
$B^+_S-B_S=\frac {1}{N}G\mid _{S}.$
We now have that
$K_S +B_S^++{\mathbf {N}_{S}}= K_S+B_S+B_S^+-B_S+{\mathbf {N}_{S}}=(K_X+B+\frac {1}{N}R+{\mathbf {M}_{X}})\mid _S=(K_X+B^++{\mathbf {M}_{X}})\mid _S$
. By inversion of adjunction,
$(X,B^+, \mathbf {M})$
is generalized log canonical near S. Moreover, it has coregularity c by [Reference Figueroa, Moraga and Peng10, Lemma 2.30].
If
$(X,B^+, \mathbf {M})$
is not generalized log canonical near the fiber over z, then
$(X,aB^++(1-a)\Gamma ),\mathbf {M} )$
is also not generalized log canonical near the fiber over z for
$a<1$
close enough to 1. The generalized pair
$(X,B^+,\mathbf {M})$
is generalized log canonical near S, therefore a component of the generalized non-klt locus of
$(X,aB^++(1-a)\Gamma ),\mathbf {M} )$
is not near S. But S is also a component of the generalized log canonical locus. Hence, the generalized non-klt locus of
$(X,aB^++(1-a)\Gamma ),\mathbf {M} )$
is disconnected near the fiber over z. This is a contradiction as
$-(K_X+aB^++(1-a)\Gamma +\mathbf {M})=-a(K_X+B^++\mathbf {M})-(1-a)(K_X+\Gamma +\mathbf {M})$
, is big and nef over Z, so the connectedness principle can be applied (see, e.g., [Reference Birkar3, Lemma 2.14]). Therefore,
$(X,B^+, \mathbf {M})$
is generalized log canonical near the fiber over z.
Proof of Theorem 5.1.
We will proceed in several steps to reduce to Proposition 5.2. Without loss of generality, we may replace X with a small
$\mathbb {Q}$
-factorial modification.
Step 1. In this step, we define a boundary divisor
$B_2 \leq B_1$
and reduce to the case where
$-(K_X+B_2+\alpha b {\mathbf {M}_{X}})$
is big and nef for some
$b \in (0,1)$
.
For any
$0 < a < 1$
, we have that
$$\begin{align*}a( K_X+B+{\mathbf{M}_{X}})+(1-a)(K_X+B_1+\alpha {\mathbf{M}_{X}})=K_X+(aB+(1-a)B_1)+(a+(1-a)\alpha) {\mathbf{M}_{X}}\end{align*}$$
is antibig and anti-nef, hence we can replace
$B_1$
by
$aB+(1-a)B_1$
and
$\alpha $
by
$a+(1-a)\alpha $
to obtain
$B_1$
with coefficients as close as needed to the coefficients of B.
Let 
for some
$b <1$
. Since X is of Fano type over Z,
$-(K_X+B_1+\alpha {\mathbf {M}_{X}} )$
defines a contraction
$X \rightarrow V$
over Z. We run an MMP on
$-(K_X+B_2+\alpha b {\mathbf {M}_{X}})$
over V. In the resulting model
$-(K_{X'}+B_2'+\alpha b {\mathbf {M}_{X'}})$
is big and nef over V. By the definition of V,
$-(K_{X'}+B_2'+\alpha b {\mathbf {M}_{X'}})(1-t)-(K_{X'}+B_1'+\alpha {\mathbf {M}_{X'}})t$
is nef over Z for t close enough to 1, which is equivalent to saying that
$-(K_{X'}+B_2'+ \alpha b {\mathbf {M}_{X'}})$
is nef over Z for b close enough to 1.
By taking a close enough to 1, we have that
$K_X+B+{\mathbf {M}_{X}}$
is nonnegative over V, hence the MMP we ran is
$(K_X+B+{\mathbf {M}_{X}})$
-nonnegative. So, by Lemma 2.22 the coregularity of
$(X,B, {\mathbf {M}_{X}})$
remains unchanged.
Then, we can replace
$(X,B,\mathbf {M})$
with
$(X',B', \mathbf {M})$
,
$B_1$
with
$B_1'$
and
$B_2$
with
$B_2'$
to have also that
$-(K_{X'}+B_2'+\alpha b {\mathbf {M}_{X'}})$
is big and nef over Z. As
$-(K_X+B_1+\alpha {\mathbf {M}_{X}})$
is big and nef over Z, we have that there is A ample and E effective, such that
$-(K_X+B_1+\alpha {\mathbf {M}_{X}}) \sim _{\mathbb {Q},Z} A+E$
.
Step 2. In this step, we separate into cases depending on whether the generalized log canonical centers of
$(X,B_1,\alpha \mathbf {M})$
are contained in the support of E.
We can take a generalized dlt modification of
$(X,B_1, \alpha {\mathbf {M}_{X}})$
, so we can assume that
$(X,B_1, \alpha {\mathbf {M}_{X}})$
is generalized dlt. If
$\operatorname {\mathrm {Supp}}{E}$
contains no generalized log canonical center of
$(X,B_1,\alpha \mathbf {M})$
, then
$(X,B_1+\varepsilon E,\alpha \mathbf {M})$
is generalized dlt for
$\varepsilon>0$
small enough.
We have that
$-(K_X+B_1+\varepsilon E+\alpha {\mathbf {M}_{X}}) \sim _{\mathbb {Q}.Z}(1-\varepsilon )( \frac {\varepsilon }{1-\varepsilon }A+-(K_X+B_1+\alpha {\mathbf {M}_{X}}))$
is ample over Z. Hence, by altering the coefficients of
$B_1+\varepsilon E$
, we can produce a divisor
$\Gamma $
that lets us conclude by Proposition 5.2.
If
$\operatorname {\mathrm {Supp}}{E}$
does contain some generalized log canonical center of
$(X,B_1,\alpha \mathbf {M})$
, then for
$0<r<1$
we define 
and 
. Then, we define
$t_r$
to be the generalized log canonical threshold of
$E+B_1-B_r$
with respect to
$(X,B_r,\alpha _r \mathbf {M})$
over z. Since X is of Fano type, it is klt. Furthermore, since
$(X,B,\mathbf {M})$
is generalized log canonical and
$0 <b,r < 1$
, it follows that
$(X,B_r,\alpha _r \mathbf {M})$
is generalized klt. In particular, we have
$t_r>0$
. We have
$$ \begin{align*} -(K_X+B_r+t_r(E+B_1-B_r)+ \alpha_r {\mathbf{M}_{X}})&=-(K_X+B_1+\alpha{\mathbf{M}_{X}})+B_1-B_r-t(E+B_1-B_r)+ (\alpha-\alpha_r) {\mathbf{M}_{X}}\\ &\sim_{\mathbb{R},Z} A+E +(1-t_r)(B_1-B_r)-tE+(\alpha-\alpha_r) {\mathbf{M}_{X}}\\ &=t_rA+(1-t_r)(A+E+(B_1-B_r))+ (\alpha-\alpha_r) {\mathbf{M}_{X}}\\ &\sim_{\mathbb{R},Z} t_rA -(1-t_r)(K_X+B_r+\alpha {\mathbf{M}_{X}})+ (\alpha-\alpha_r){\mathbf{M}_{X}}\\ &\sim_{\mathbb{R},Z} t_rA -(1-t_r)(K_X+B_r+\alpha_r {\mathbf{M}_{X}})+ t_r(\alpha-\alpha_r){\mathbf{M}_{X}}\\ &=t_r(A+(\alpha-\alpha_r) {\mathbf{M}_{X}})-(1-t_r)(K_X+B_r+\alpha_r {\mathbf{M}_{X}}). \end{align*} $$
If we pick r close enough to 1, then
$\alpha -\alpha _r$
tends to
$0$
, hence
$A-(\alpha -\alpha _r) {\mathbf {M}_{X}}$
is ample over Z for r close enough to 1. Fixing such an r, it follows that
$-(K_X+B_r+t_r(E+B_1-B_r)+ \alpha _r {\mathbf {M}_{X}})$
is ample over Z.
Step 3. In this step, we separate into cases according to the round-down of the divisor 
.
If we have
$\lfloor \Theta \rfloor =0$
, then we let
$(X',\Theta ',\alpha _r \mathbf {M})$
be a dlt modification of
$(X,\Theta ,\alpha _r \mathbf {M})$
. We can assume that every component of
$\lfloor \Theta ' \rfloor $
intersects the fiber over z, after shrinking Z. Furthermore, since
$(X,B_r,\alpha _r \mathbf {M})$
is generalized klt,
$\lfloor \Theta ' \rfloor $
is the exceptional divisor of
$X' \rightarrow X$
. An MMP on
$K_{X'}+\lfloor \Theta ' \rfloor +\alpha b {\mathbf {M}_{X'}}$
over X ends with X, as
$\lfloor \Theta ' \rfloor $
is the exceptional divisor of
$X' \rightarrow X$
and X is klt and
$\mathbb {Q}$
-factorial. The last step of this MMP would be a divisorial contraction
$X"\rightarrow X$
contracting one prime divisor
$S"$
with
$(X",S", \alpha _r{\mathbf {M}_{X"}})$
generalized plt and
$-(K_{X"}+S"+ \alpha _r{\mathbf {M}_{X"}})$
ample over X. Furthermore
$S"$
is a component of both
$\Theta "$
and
$B_1"$
, where
$K_{X"}+\Theta "$
and
$K_{X"}+B_1"$
are the pull-backs of
$K_X+\Theta $
and
$K_X+B_1$
, respectively.
As
$-(K_X+\Theta +\alpha _r {\mathbf {M}_{X}})$
is ample over Z and
$-(K_{X"}+S"+\alpha _r {\mathbf {M}_{X"}})$
is ample over X, a linear combination of
$S"$
and
$\Theta "$
yields
$\Gamma "$
such that
$-(K_{X"}+\Gamma "+\alpha _r {\mathbf {M}_{X"}})$
is ample over Z and
$(X",\Gamma ",\alpha _r {\mathbf {M}_{X"}})$
is plt with
$\lfloor \Gamma " \rfloor =S"$
. We can apply Proposition 5.2 here. As an N-complement on
$X"$
would induce an N-complement on X, we have reduced to the case where
$\lfloor \Theta \rfloor \neq 0$
.
It only remains to deal with the case where
$\lfloor \Theta \rfloor \neq 0$
. In this case, there is a component S of
$\lfloor \Theta \rfloor \leq \lfloor B_1 \rfloor \leq \lfloor B \rfloor $
. On a dlt modification of
$(X,S, \alpha _r {\mathbf {M}_{X}})$
, we can perturb the coefficients of
$\Theta '$
to get that
$\lfloor \Theta " \rfloor $
is irreducible and
$-(K_{X'} +\Gamma + \alpha _r {\mathbf {M}_{X}})$
is ample. Therefore, we can obtain the N-complement by Proposition 5.2, as desired. As an N-complement on
$X"$
induces an N-complement on X, we are done.
5.2 Relative complements
In this subsection, we study the existence of complements in the relative setting. The main theorem of this subsection states that we can lift complements from lower coregularity pairs when all the generalized log canonical centers are horizontal over the base.
Theorem 5.3. Let d, c and p be nonnegative integers and
$\Lambda \subset \mathbb {Q}$
be a closed set satisfying the DCC. Assume Theorem 7
$(c-1)$
holds. There exists a constant 
satisfying the following.
Let
$\pi \colon X \rightarrow Z$
be a Fano type morphism, where X is a d-dimensional variety, and
$\dim Z>0$
. Let
$(X,B, \mathbf {M})$
be a generalized log canonical pair over Z and
$z \in Z$
a point satisfying the following conditions:
-
• the generalized pair
$(X,B, \mathbf {M})$
has coregularity at most c over z; -
• the coefficients of B belong to
$\Lambda $
; -
• every generalized log canonical center of
$(X,B,\mathbf {M})$
dominates Z; -
•
$p \mathbf {M}$
is b-Cartier; and -
• the divisor
$-(K_X+B+{\mathbf {M}_{X}})$
is nef over Z.
Then, there exists an N-complement for
$(X,B,\mathbf {M})$
over z.
Proof. We will proceed in several steps to be able to lift complements using Theorem 5.1.
Step 1. In this step, we reduce to the case in which the boundary coefficients belong to a finite set,
$(X,B, \mathbf {M})$
has coregularity
$c-1$
over, and
$\lfloor B \rfloor $
has a vertical component intersecting the fiber over
$z.$
By Theorem 3.5, there exists a finite set
$\mathcal {R}$
and a relative pair
$(X',B',\mathbf {M})$
with
$\operatorname {\mathrm {coeff}}(B')\subset \mathcal {R}$
such that if
$(X',B',\mathbf {M})$
is N-complemented, then so is
$(X,B,\mathbf {M})$
. So, we can replace our generalized pair
$(X,B,\mathbf {M})$
with
$(X',B',\mathbf {M})$
. Hence, we may assume the coefficients of B belong to the finite set
$\mathcal {R}$
. Up to taking a
$\mathbb {Q}$
-factorial dlt modification, we may further assume that X is
$\mathbb {Q}$
-factorial.
We pick an effective Cartier divisor N on Z passing through z. We let t be the generalized log canonical threshold of
$q^*N$
with respect to
$(X,B, \mathbf {M})$
over z. By the connectedness principle [Reference Filipazzi and Svaldi16, Theorem 1.7] and the assumption that all the generalized log canonical centers of
$(X,B,\mathbf {M})$
dominate Z, we know that the coregularity of
$(X,B+tq^*N,\mathbf {M})$
is at most
$c-1$
.
Let
$(X',T', \mathbf {M})$
be a generalized dlt modification of
$(X,B+tq^*N,\mathbf {M})$
over z. Let
$B'$
be the strict transform of B on
$X'$
. Let
$\Omega '$
be a boundary such that
$B' \leq \Omega ' \leq T'$
,
$\operatorname {\mathrm {coeff}}(\Omega ')\subset \mathcal {R} $
and some component S of
$\lfloor \Omega ' \rfloor $
is vertical over Z intersecting the fiber
$\pi ^{-1}(z)$
. Let
$\Omega = \pi _\ast \Omega '$
.
We run an MMP over Z on
$-(K_{X'}+\Omega '+{\mathbf {M}_{X'}})$
. As
$-(K_{X'}+\Omega '+{\mathbf {M}_{X'}})=-(K_{X'}+T'+{\mathbf {M}_{X'}})+(T'-\Omega '),$
with
$-(K_{X'}+T'+\mathbf {M}'.)$
nef over Z and
$(T'-\Omega ')$
effective, the MMP ends with a minimal model, which we denote by
$X"$
.
If
$(X",\Omega ", {\mathbf {M}_{X"}})$
has an N-complement over z, then
$(X',\Omega ', {\mathbf {M}_{X'}})$
has an N-complement over z by Lemma 2.12. As
$B \leq \Omega $
, we have that also
$(X,B, {\mathbf {M}_{X}})$
has an N-complement by Lemma 2.13. So, we can replace
$(X,B, {\mathbf {M}_{X}})$
with
$(X",\Omega ", {\mathbf {M}_{X"}})$
, to obtain
$\lfloor B \rfloor $
having a component intersecting the fiber over z, with
$-(K_X+B+{\mathbf {M}_{X}})$
nef over Z. Notice that, after this reduction, the coregularity has decreased, and it is no longer the case that all generalized log canonical centers dominate Z.
Step 2. In this step, we define a divisor
$B_1$
which satisfies the hypothesis of Theorem 5.1.
For any prime divisor D that vertical is over Z, we set 
. For any prime divisor D horizontal over Z, we set 
for
$a<1$
, close enough to 1.
As X is of Fano type over Z, we have that
$-K_X$
is big over Z. Therefore,
$-(K_X+aB+a {\mathbf {M}_{X}})=-a(K_X+B+{\mathbf {M}_{X}})-(1-a)K_X$
and
$-(K_X+ B_1+a{\mathbf {M}_{X}})$
are big over Z. The generalized pair
$(X,B_1, a\mathbf {M})$
is generalized log canonical as
$B_1 \leq B$
and
$\lfloor B_1 \rfloor $
contains the same vertical component as
$\lfloor B \rfloor $
intersecting the fiber of z.
Step 3. In this step, we reduce to the case in which
$-(K_X+B_1+{\mathbf {M}_{X}})$
is big and nef over Z.
Since
$\pi $
is a Fano type morphism and
$-(K_X+B+{\mathbf {M}_{X}})$
is nef over Z,
$-(K_X+B+{\mathbf {M}_{X}})$
is semiample over Z. Let
$X \rightarrow V$
over Z be the contraction defined by
$-(K_X+B+{\mathbf {M}_{X}})$
. We run an MMP on
$-(K_X+B_1+a{\mathbf {M}_{X}})$
over V. In the resulting model
$-(K_X'+B_1'+a{\mathbf {M}_{X'}})$
is big and nef over V. By the definition of V,
$-(K_{X'}+B_1'+a{\mathbf {M}_{X'}})(1-t)-(K_{X'}+B'+{\mathbf {M}_{X'}})t$
is nef over Z for t close enough to 1, which is equivalent to picking a close enough to 1. We have that
$K_X+B+{\mathbf {M}_{X}}$
is trivial over V, hence the MMP is
$(K_X+B+{\mathbf {M}_{X}})$
-nonnegative. Applying Lemma 2.22, the coregularity of
$(X,B,\mathbf {M})$
remains unchanged after this MMP. Thus, we can replace
$(X,B,\mathbf {M})$
, with
$(X',B', \mathbf {M})$
and
$B_1$
with
$B_1'$
with a close enough to 1.
Step 4. In this step, we conclude by applying Theorem 5.1.
Let
$N(\mathcal {R},c-1,p)$
be the positive integer provided by Theorem 7
$(c-1)$
. Taking N to be the least common multiple of
$N(\mathcal {R},c-1,p)$
,
$I_{\mathcal {R}}$
and p. Hence, N depends only on
$\Lambda $
,
$c-1$
and p. Indeed,
$\mathcal {R}$
only depends on
$\Lambda ,c$
and p. By Theorem 5.1 the generalized pair
$(X,B, \mathbf {M})$
admits an N-complement, where N only depends on
$\Lambda $
, c and p.
6 Canonical bundle formula
In this section, we prove a special version of the canonical bundle formula. We obtain an effective canonical bundle formula that is independent of the dimension of the domain. It only depends on the coregularity of the fibers.
Theorem 6.1. Let d, c be nonnegative integers and
$\Lambda \subset \mathbb {Q}$
be a closed set satisfying the descending chain condition. Assume Theorem 7
$(c-1)$
holds. There exists a set 
satisfying the descending chain condition and a positive integer 
satisfying the following. Let
$\pi \colon X\rightarrow Z$
be a fibration from a d-dimensional projective variety X to a projective base Z with
$\dim Z> 0$
. Let
$(X,B)$
be a log canonical pair satisfying the following conditions:
-
• the fibration
$\pi $
is of Fano type over a nonempty open set U of Z; -
• every log canonical center of
$(X,B)$
is horizontal over Z; -
• the pair
$(X,B)$
is log Calabi–Yau over Z; -
• the coefficients of B are in
$\Lambda $
; and -
• the coregularity of
$(X,B)$
is at most c.
Then, we can write
$$\begin{align*}q(K_X+B)\sim q\pi^*(K_Z+B_Z+{\mathbf{N}_{Z}}), \end{align*}$$
where
$(Z,B_Z,\mathbf {N})$
is a generalized log canonical pair such that
-
•
$B_Z$
is the discriminant part of the adjunction for
$(X,B)$
over Z; -
• the coefficients of
$B_Z$
belong to
$\Omega $
; and -
• the divisor
$q\mathbf {N}$
is b-nef and b-Cartier.
Proof. The proof is given in several steps. In Step 1, we make a choice of q and
$\mathbf {N}$
. In Steps 2–4, we find
$\Omega $
and show that the coefficients of
$B_Z$
belong to
$\Omega $
. We also prove that
$q{\mathbf {N}_{Z}}$
is integral. In Step 5, we show that
$q\mathbf {N}$
is b-Cartier. We observe that, by the assumptions on the log canonical centers of
$(X,B)$
and on the coregularity of
$(X,B)$
, it follows that
$\dim Z \leq c$
.
Step 1. In this step, we find q and make a choice of
$\mathbf {N}$
.
Let q be the integer N in the statement of Theorem 5.3
$(d,c-1)$
. Here, we assumed Theorem 7
$(c-1)$
. Fix a general closed point
$z\in U$
. Let H be a general hyperplane section of U passing through z. Then
$(X,B+\pi ^*H)$
is log Calabi–Yau and satisfies
$$\begin{align*}\text{coreg}(X,B+\pi^*H) \leq c-1. \end{align*}$$
This implies that the absolute coregularity of
$(X,B)$
over z is at most
$c-1$
. By Theorem 5.3
$(d,c-1)$
, there is a q-complement
$K_X+B^+$
of
$K_X+B$
over z with
$B^+\geq B$
. Note that q only depends on
$\Lambda $
and c. Since
$K_X+B$
is
$\mathbb {Q}$
-trivial over Z,
$B^+-B\sim _{\mathbb {Q}}0$
over z and hence
$B^+=B$
near the generic fiber of
$\pi $
. Therefore,
$q(K_X+B)\sim 0$
over the generic point of Z. Thus, we can find a rational function s on X such that 
is zero over the generic point of Z. Note that
$L\sim _{\mathbb {Q}} 0$
over Z, so we can write
$L = \pi ^* L_Z$
for some
$\mathbb {Q}$
-Cartier
$\mathbb {Q}$
-divisor
$L_Z$
on Z. Define
where
$B_Z$
is the discriminant part of adjunction for
$(X,B)$
over Z. Similarly, for any birational morphism
$g \colon Z'\to Z$
, we can define
${\mathbf {N}}_{Z'}$
as follows. Let
$f \colon X'\to X$
be a higher birational model of X such that the rational map
$X'\dashrightarrow Z'$
is a morphism. Write
$K_{X'} + B_{X'} $
for the pull-back of
$K_X+B$
and
$B_{Z'}$
be the discriminant part of adjunction for
$(X', B_{X'})$
over
$Z'$
. We define
The data of
${\mathbf {N}_{Z'}}$
, for all birational models
$Z'\to Z$
, determine a b-divisor
$\mathbf {N}$
on Z.
Step 2. In this step, we reduce to the case when the base Z is a curve.
Assume
$\dim Z \geq 2$
. Let H be a general hyperplane section of Z and G be the pull-back of H to X. By adjunction, we can write
$$\begin{align*}(K_X+B+G)|_G = K_G + B_G \end{align*}$$
for some divisor
$B_G$
on G. By Lemma 2.17, there exists a set
$\Lambda '$
satisfying the DCC, having rational accumulation points and depending only on
$\Lambda $
such that the coefficients of
$B_G$
belong to
$\Lambda '$
. We may replace
$\Lambda $
with
$\Lambda '$
to assume that the coefficients of
$B_G$
belong to
$\Lambda $
. Since
$\dim Z \leq c$
, this replacement can only happen at most
$c-1$
times and is hence allowed. By Lemma 2.25, the pair
$(G,B_G)$
over H satisfies the same conditions as
$(X,B)$
over Z in the statement of this theorem. Furthermore, let
$B_H$
denote the discriminant part of the adjunction for
$(G,B_G)$
over H. Let D be any prime divisor on Z and C a component of
$D\cap H$
. Then
$$\begin{align*}\operatorname{\mathrm{coeff}}_D(B_Z) = \operatorname{\mathrm{coeff}}_C(B_H). \end{align*}$$
Pick a general
$H'\sim H$
, and let
$K_H = (K_Z+H')|_H$
, which is properly defined as a Weil divisor. Define
$$\begin{align*}{\mathbf{N}_{H}}' = (L_Z+H')|_H - (K_H+B_H). \end{align*}$$
Similarly to the way we defined the b-divisor
$\mathbf {N}$
on Z, we can define
$\mathbf {N}'$
as a b-divisor on H. Then, we have
$$\begin{align*}q(K_G+B_G) \sim q(L+G)|_G \sim q\psi^*(L_Z+H')|_H \sim q\psi^*(K_H+B_H+{\mathbf{N}_{H}}'). \end{align*}$$
Thus,
${\mathbf {N}_{H}}'$
is the moduli part of
$(G,B_G)$
over H. Moreover, we have
$B_H+{{\mathbf {N}_{H}}'} = (B_Z+{\mathbf {N}_{Z}})|_H$
. This implies that
$ \operatorname {\mathrm {coeff}}_C(B_H+{{\mathbf {N}_{H}}'} ) = \operatorname {\mathrm {coeff}}_D(B_Z + {\mathbf {N}_{Z}}) $
and hence
$ \operatorname {\mathrm {coeff}}_C({{\mathbf {N}_{H}}'} ) = \operatorname {\mathrm {coeff}}_D({\mathbf {N}_{Z}}). $
In particular,
$q{\mathbf {N}_{H}}'$
is integral if and only if
$q{\mathbf {N}_{H}}$
is integral.
As a result, to prove that
$\operatorname {\mathrm {coeff}}(B_Z)$
belongs to a fixed set
$\Omega $
and that
$q{\mathbf {N}_{Z}}$
is integral, we may replace
$(X,B) \to Z$
with
$(G,B_G)\to H$
. By repeating this process until the base of the fibration is a curve, we may assume that
$\dim Z = 1$
.
Step 3. In this step, we show the existence of
$\Omega $
.
By Step 2, we can assume
$\dim Z = 1$
. By [Reference Birkar3, Lemma 2.11], the variety X is of Fano type over Z. Pick any closed point
$z\in Z$
. Let t be the log canonical threshold of
$\pi ^*z$
with respect to
$(X,B)$
around z. Set
$\Gamma = B+t\pi ^*z$
, and let
$(X',\Gamma ')$
be a
$\mathbb {Q}$
-factorial dlt modification of
$(X,\Gamma )$
. Then
$K_{X'}+\Gamma ' \sim _{\mathbb {Q}} 0$
over Z and
$\Gamma '$
has a component with coefficient 1 mapping to z. Pick a boundary
$B'$
on
$X'$
satisfying the following conditions:
-
• we have
$\tilde {B}\leq B'\leq \Gamma '$
, where
$\tilde {B}$
is the strict transform of B on
$X'$
; -
• the coefficients of
$B'$
are in
$\Lambda $
; and -
• the divisors
$B'$
and
$\Gamma '$
have the same round-down, that is,
$\lfloor B'\rfloor = \lfloor \Gamma '\rfloor $
.
By construction,
$\operatorname {Supp}(\Gamma '-B')$
is contained in the strict transform of
$\operatorname {Supp}(\pi ^*z)$
. If
$t<1$
,
$\lfloor B'\rfloor $
has a component T mapping to z which is exceptional over X. Note that
$X'$
is of Fano type over Z. We run a
$-(K_{X'}+B')$
-MMP with scaling over Z. Since
$-(K_{X'}+B')\sim _{\mathbb {Q}} \Gamma '-B'$
is pseudo-effective, this MMP terminates with a model
$(X",B")$
such that
$-(K_{X"}+B")$
is semiample over Z by [Reference Birkar1, Theorem 1.1]. The divisor T is not contracted by this MMP because
$T\not \subseteq \operatorname {Supp}(\Gamma '-B')$
. Furthermore, by Lemma 2.22, we have
$$\begin{align*}\mathrm{coreg}(X",B") = \mathrm{coreg}(X',B')\leq \mathrm{coreg}(X',\Gamma') \leq c. \end{align*}$$
As a result, up to losing the dlt condition, we may replace
$(X',B')$
by
$(X",B")$
to assume that the following properties hold:
-
•
$X'$
is Fano type over Z; -
•
$(X',B')$
is a log canonical pair over Z; -
• the coefficients of
$B'$
are in
$\Lambda $
; -
•
$\mathrm {coreg}(X',B')\leq c$
; -
•
$-(K_{X'}+B')$
is semiample over Z; and -
•
$\lfloor B'\rfloor $
has a component mapping to z.
If
$t = 1$
, we may simply take
$B' = \Gamma '$
so the above conditions hold as well for
$(X',B')$
.
By Theorem 5.1 and our choice of q, the pair
$(X',B')$
has a q-complement
$(X',B^+)$
over z with
$B^{\prime }+\geq B'$
. Pushing forward
$B^{\prime }+$
to X gives a q-complement
$(X,B^+)$
of
$(X,B)$
over z with
$B^+\geq B$
. Furthermore,
$K_X+B^+$
has a non-klt center mapping to z, since its pull-back
$K_{X'}+B^{\prime }+$
does. Note that
$B^+-B\sim _{\mathbb {Q}} 0$
over z, so
$B^+-B$
must be a multiple of
$\pi ^*z$
over z. This implies that
$B^+ = B+t\pi ^*z$
over z since
$K_X+B^+$
has a non-klt center mapping to z.
Pick a component S of
$\pi ^*z$
. Let b,
$b^+$
and m be the coefficients of S in B,
$B^+$
and
$\pi ^*z$
, respectively. Then
$b^+ = b+tm$
and
$t = \frac {b^+-b}{m}$
. By construction,
$qb^+$
and m are integers,
$b^+\leq 1$
and
$b\in \Lambda $
. By Lemma 2.18, t belongs to a fixed set
$\Sigma $
(depending only on
$I,\Lambda $
) which satisfies ACC and has rational accumulation points. Since the coefficient of z in
$B_Z$
is
$1-t$
, it belongs to a set
$\Omega $
depending only on I and
$\Lambda $
such that
$\Omega $
satisfies DCC and has rational accumulation points.
Step 4. In this step, we show that
$q{\mathbf {N}_{Z}}$
is integral.
By Step 2, we can assume that Z is a curve. By Step 1, the equivalence
$q(K_X+B)\sim 0$
holds over some nonempty open subset
$V\subseteq Z$
such that
$\operatorname {\mathrm {Supp}} B_Z \subseteq Z\setminus V$
. Let
$$\begin{align*}\Theta = B + \sum_{z\in Z\setminus V} t_z \pi^*z, \end{align*}$$
where
$t_z$
is the log canonical threshold of
$\pi ^*z$
with respect to
$(X,B)$
over z. Note that
$K_X+\Theta \sim _{\mathbb {Q}} 0$
over Z. Let
$\Theta _Z$
be the discriminant part of adjunction for
$(X,\Theta )$
over Z. Then
$$\begin{align*}\Theta_Z = B_Z + \sum_{z\in Z\setminus V} t_z z = \sum_{z\in Z\setminus V} z \end{align*}$$
is an integral divisor. Moreover, by Step 3, the pair
$(X,\Theta )$
is a q-complement of
$(X,B)$
over each
$z\in Z\setminus V$
. Over V, we have
$q(K_X+\Theta ) \sim q(K_X+B)\sim 0$
. Thus,
$q(K_X+\Theta ) \sim 0$
over Z by [Reference Birkar3, Lemma 2.4]. Furthermore, from the equalities
$$\begin{align*}q(K_X+\Theta) = q(K_X+B) + q(\Theta-B) \sim q\pi^*(K_Z+B_Z+{\mathbf{N}_{Z}}) + q\pi^*(\Theta_Z-B_Z) \sim q\pi^*(K_Z+\Theta_Z+{\mathbf{N}_{Z}}), \end{align*}$$
we obtain that
$q(K_Z+\Theta _Z+{\mathbf {N}_{Z}})$
is an integral divisor and hence
$q{\mathbf {N}_{Z}}$
is integral.
Step 5. In this step, we show that
$q{\mathbf {N}_{Z'}}$
is nef Cartier on some resolution
$Z'\to Z$
.
The nefness follows from [Reference Birkar3, Theorem 3.6], so we just need to show that
$q{\mathbf {N}_{Z'}}$
is integral. Denote the birational morphism
$Z'\to Z$
by g. As in Step 1, let
$f \colon X'\to (X,B)$
be a log resolution such that the rational map
$\pi ' \colon X'\dashrightarrow Z'$
is a morphism. Let
$U_0\subseteq U$
be a nonempty open set such that 
is an isomorphism. Let
$\Delta '$
be the sum of the birational transform of B and reduced exceptional divisors of f but with all components mapping outside of
$U_0$
removed. Then, the generic point of every log canonical center of
$(X',\Delta ')$
lies inside
$U_0$
.
Let T be the normalization of the main component of
$Z'\times _Z X$
. Run an MMP on
$K_{X'}+\Delta '$
over T with scaling of some ample divisor. This MMP terminates with a
$\mathbb {Q}$
-factorial dlt pair
$(X",\Delta ")$
such that
$K_{X"}+\Delta "$
is nef over T. Let
$X_0 = \pi ^{-1}(U_0)$
. Over
$U_0\cong U_0'$
, we have
$Z'\times _Z X\cong X_0$
, and hence
$K_{X"}+\Delta "$
is nef over
$X_0\subseteq X$
. By the negativity lemma, over
$U_0'$
, the divisor
$K_{X"}+\Delta "$
is equal to the log pull-back of
$K_X+B$
. This shows that
$(X",\Delta ")$
is a dlt modification of
$(X,B)$
over
$U_0$
. In particular,
$X"$
is Fano type over
$U_0'$
. Furthermore, every log canonical center of
$(X",\Delta ")$
dominates
$U_0'$
. Indeed,
$(X,B)$
satisfies the same property and the generic point of every log canonical center of
$(X",\Delta ")$
lies inside
$U_0'$
. Thus, we have
$$\begin{align*}\text{coreg}(X", \Delta" ) = \text{coreg} (X,B) \leq c. \end{align*}$$
By [Reference Birkar1, Theorem 1.4], we can run an MMP on
$K_{X"}+\Delta '$
over
$Z'$
which terminates with a good minimal model over
$Z'$
. Since this MMP is trivial over
$U_0'$
, the dual complex and hence the coregularity of
$(X",\Delta ")$
does not change under this MMP. Abusing the notation, we again denote the good minimal model by
$X"$
. Let
$\pi " \colon X"\to Z"$
over
$Z'$
be the morphism induced by the relatively semiample divisor
$K_{X"}+\Delta "$
. Since
$K_{X"}+\Delta "\sim _{\mathbb {Q}} 0$
over
$U_0'$
,
$Z"\to Z'$
is birational and
$U_0"$
, the preimage of
$U_0'$
in
$Z"$
, is isomorphic to
$U_0'$
. Thus, every log canonical center of
$(X",\Delta ")$
also dominates
$Z"$
.
Let W be a common resolution of X and
$X"$
, and set
$\alpha \colon W\to X$
and
$\beta \colon W\to X"$
. By construction, over the preimage of
$U_0$
in W, we have
$\alpha ^*(K_X+B) = \beta ^*(K_{X"}+\Delta ")$
. Write
$K_{X"}+B" = \beta _*\alpha ^*(K_X+B)$
and
$L" = \beta _*\alpha ^*L$
, where
$qL = q(K_X+B) + \text {Div}(s)$
as in Step 1. Let
$P" = \Delta "-B"$
, which is
$\mathbb {Q}$
-trivial over
$Z"$
and supported outside of
$U_0"$
. Hence,
$P" = \pi ^{\prime }{\prime }*P_{Z"}$
for some
$\mathbb {Q}$
-divisor
$P_{Z"}$
on
$Z"$
. Let
$\Delta _{Z"}$
be the discriminant part of adjunction for
$(X",\Delta ")$
on
$Z"$
. Let
$B_{Z"} = \Delta _{Z"} - P_{Z"}$
, then
$B_{Z"}$
is the discriminant part of adjunction for
$(X",B")$
on
$Z"$
. By the definition of
$\mathbf {N}$
in Step 1, we have
$$\begin{align*}q(K_{X"}+\Delta") = q(K_{X"}+B"+P") \sim q\pi^{\prime}{\prime}*(K_{Z"}+ B_{Z"} + {\mathbf{N}_{Z"}} + P_{Z"}) \sim q\pi^{\prime\prime}*(K_{Z"}+\Delta_{Z"}+{\mathbf{N}_{Z"}}). \end{align*}$$
Here,
$L_{Z"}$
is the pull-back of
$L_Z$
in Step 1. This shows that
${\mathbf {N}_{Z"}}$
is the moduli part of
$(X",\Delta ")$
over
$Z"$
. Since the coefficients of
$\Delta "$
are in
$\Lambda $
and the coregularity of
$(X",\Delta ")$
is at most c, we may apply Steps 2–4 to show that
$q {\mathbf {N}_{Z"}}$
is an integral divisor. Thus,
$q{\mathbf {N}_{Z'}}$
is also an integral divisor and hence Cartier as
$Z'$
is smooth.
We show that Theorem 6.1 also holds for generalized pairs
$(X,B,\mathbf {M})$
in the special case that
${\mathbf {M}_{X}}\sim _{\mathbb {Q}} 0$
over the base Z.
Theorem 6.2. Let d, c and p be nonnegative integers and
$\Lambda \subset \mathbb {Q}$
be a closed set satisfying the descending chain condition. Assume Theorem 7
$(c-1)$
holds. There exists a set 
satisfying the descending chain condition and a positive integer 
, both
$\Omega $
and q only depending on
$\Lambda $
and c, and satisfying the following. Let
$\pi \colon X\rightarrow Z$
be fibration from a d-dimensional projective variety X to a projective base Z with
$\dim Z> 0$
. Let
$(X,B,\mathbf {M})$
be a generalized pair for which
-
• the generalized pair
$(X,B,\mathbf {M})$
is generalized log canonical; -
• the fibration
$\pi $
is of Fano type over a nonempty open set U of Z; -
• every generalized log canonical center of
$(X,B,\mathbf {M})$
is horizontal over Z; -
• the divisors
$K_X+B+{\mathbf {M}_{X}}$
and
${\mathbf {M}_{X}}$
are
$\mathbb {Q}$
-trivial over Z; -
• the coefficients of B are in
$\Lambda $
, -
•
$p\mathbf {M}$
is b-Cartier; and -
• the coregularity of
$(X,B)$
is at most c.
Then, we can write
$$\begin{align*}q(K_X+B+{\mathbf{M}_{X}} )\sim q\pi^*(K_Z+B_Z+{\mathbf{N}_{Z}}), \end{align*}$$
where
$(Z,B_Z,\mathbf {N})$
is a generalized log canonical pair such that
-
•
$B_Z$
is the discriminant part of the adjunction for
$(X,B,\mathbf {M})$
over Z; -
• the coefficients of
$B_Z$
belong to
$\Omega $
; and -
• the divisor
$q\mathbf {N}$
is b-nef and b-Cartier.
Proof. We proceed in several steps. In the first step, we apply the canonical bundle formula for pairs. In the rest of the proof, we show that
$\mathbf {M}$
is the pull-back of a b-nef divisor on the base and control the Cartier index of this b-nef divisor where it descends.
Step 1. We show that the pair
$(X,B)$
satisfies the conditions in the statement of Theorem 6.1.
By Lemma 2.5,
$(X,B)$
is log canonical. Furthermore, every log canonical center of
$(X,B)$
is also a log canonical center of
$(X,B,\mathbf {M})$
, and hence it dominates U.
Thus, by Theorem 6.1, there exists
$\Omega $
and I, depending only on
$\Lambda $
and c such that
$$\begin{align*}q(K_X+B) \sim q \pi^*(K_Z+B_Z+{\mathbf{P}_{Z}}), \end{align*}$$
where
$B_Z$
and
$\mathbf {P}$
are the discriminant and moduli part of adjunction for the fibration
$(X,B) \to Z$
. Since
$(X,B)$
is log canonical,
$(Z,B_Z,\mathbf {P})$
is generalized log canonical. Furthermore, the coefficients of
$B_Z$
belong to
$\Omega $
and
$q\mathbf {P}$
is nef Cartier on any high resolution of Z. By replacing q with
$pq$
, we can assume that q is a multiple of p.
Step 2. In this step, we express
$\mathbf {M}$
as a pull-back of some b-divisor from Z.
Let
$g \colon Z'\to Z$
be a log resolution of
$(Z,B_Z+\mathbf {P})$
such that
$\mathbf {P}$
descends on
$Z'$
and
${\mathbf {P}_{Z'}}$
is nef. Let
$f \colon X'\to X$
be a resolution such that the rational map
$\pi ' \colon X'\dashrightarrow Z'$
is a morphism and
${\mathbf {M}_{X'}}$
is nef. By the negativity lemma, we can write
$$\begin{align*}f^* {\mathbf{M}_{X}} = {\mathbf{M}_{X'}} +E_{X'} \end{align*}$$
for some effective f-exceptional
$\mathbb {Q}$
-divisor
$E_{X'}$
. Since
${\mathbf {M}_{X}} \sim _{\mathbb {Q}} 0$
over Z,
$E_{X'}$
is vertical over Z, so there is a nonempty subset of U over which
$E_{X'}=0$
and
${\mathbf {M}_{X'}}\sim _{\mathbb {Q}} 0$
. Since
$\pi $
is of Fano type over U, the general fibers of
$\pi $
are of Fano type and hence rationally connected. Thus, the general fibers of
$\pi '$
are also rationally connected. By [Reference Birkar3, Lemma 2.44], after replacing
$X'$
and
$Z'$
with possibly higher birational models, we can write
$$\begin{align*}p{\mathbf{M}_{X'}} \sim p \pi^{\prime}* T_{Z'} \end{align*}$$
for some
$\mathbb {Q}$
-divisor
$T_{Z'}$
on
$Z'$
such that
$pT_{Z'}$
is nef Cartier. Let
$\mathbf {T}$
be the b-divisor on Z with the data
$g \colon Z'\to Z$
and
$T_{Z'}$
(i.e.,
$\mathbf {T}$
descends on
$Z'$
as
$T_{Z'}$
).
Step 3. In this step, we show that
$q{\mathbf {M}_{X}} \sim q\pi ^* {\mathbf {T}_{Z}}$
.
As in Step 2, write
$$\begin{align*}f^*{\mathbf{M}_{X}} = {\mathbf{M}_{X'}} + E_{X'}. \end{align*}$$
Then
$E_{X'}$
is vertical and
$\mathbb {Q}$
-linearly trivial over
$Z'$
(since
${\mathbf {M}_{X'}} \sim _{\mathbb {Q}} 0$
over
$Z'$
), so we can write
${E_{X'} = \pi ^{\prime }* E_{Z'}}$
for some effective
$\mathbb {Q}$
-divisor
$E_{Z'}$
. If
$E_{Z'}$
has a component
$D_{Z'}$
which maps onto a divisor D in Z, then
$E_{X'} = \pi ^{\prime }*E_{Z'}$
has a component mapping onto D, contradicting the fact that
$E_{X'}$
is f-exceptional. Thus,
$E_{Z'}$
is g-exceptional. Note that
$\pi ^{\prime }*({\mathbf {T}_{Z'}} + E_{Z'}) = {\mathbf {M}_{X'}}+E_{X'} \sim _{\mathbb {Q}} 0$
over Z, so
${\mathbf {T}_{Z'}} +E_{Z'} \sim _{\mathbb {Q}}0$
over Z. This implies that
$g^*{\mathbf {T}_{Z}} = {\mathbf {T}_{Z'}} + E_{Z'}$
. Now, we have
$$\begin{align*}qf^*{\mathbf{M}_{X}} = q({\mathbf{M}_{X'}} + E_{X'}) \sim q \pi^{\prime}*({\mathbf{T}_{Z'}}+ E_{Z'}) = q \pi^{\prime}* g^*{\mathbf{T}_{Z}} = q f^*\pi^*{\mathbf{T}_{Z}} \end{align*}$$
and hence
$q{\mathbf {M}_{X}}\sim q\pi ^*{\mathbf {T}_{Z}}$
. In particular,
$q\mathbf {T}$
is a b-Cartier divisor. From now on, we consider
$(Z, B_Z,\mathbf {P} + \mathbf {T})$
as a generalized pair, with moduli part
$\mathbf {P}+\mathbf {T}$
.
Step 4. In this step, we show that the generalized pair
$(Z,B_Z,\mathbf {P}+\mathbf {T})$
is generalized log canonical.
Write
$K_{X'}+B_{X'} = f^*(K_X+B)$
. Let
$B_{Z'}$
be the discriminant part of the adjunction for
$(X',B_{X'})$
over
$Z'$
. We can assume that
$(Z', \operatorname {\mathrm {Supp}} B_{Z'}+\operatorname {\mathrm {Supp}} E_{Z'}+\operatorname {\mathrm {Supp}} {\mathbf {P}_{Z'}}+\operatorname {\mathrm {Supp}}{\mathbf {T}_{Z'}})$
is log smooth. By construction, we have
$$\begin{align*}K_{Z'} + B_{Z'} + E_{Z'} + {\mathbf{P}_{Z'}} + {\mathbf{T}_{Z'}}= g^*(K_Z+B_Z+{\mathbf{P}_{Z}}+{\mathbf{T}_{Z}}). \end{align*}$$
Thus, it suffices to show that every coefficient of
$B_{Z'} + E_{Z'}$
is at most one. Let D be a prime divisor on
$Z'$
. Let
$t_D$
be the log canonical threshold of
$(X',B_{X'})$
with respect to
$\pi ^{\prime }*D$
over the generic point of D. Since
$(X,B,\mathbf {M})$
is generalized log canonical,
$(X',B_{X'}+E_{X'})$
is sublog canonical. Furthermore,
$E_{X'} = \pi ^{\prime }*E_{Z'}$
, so the coefficient of D in
$E_{Z'}$
is at most
$t_D$
(otherwise
$E_{X'}\geq (t_D+\epsilon )\pi ^{\prime }*D$
for some
$\epsilon> 0$
and this violates the sublog canonical condition). By definition,
$\operatorname {\mathrm {coeff}}_D(B_{Z'}) = 1-t_D$
. Thus,
$\operatorname {\mathrm {coeff}}_D(B_{Z'}+E_{Z'}) \leq 1-t_D + t_D = 1$
, as desired.
Step 5. In this step, we conclude that the generalized pair
$(Z, B_Z, \mathbf {P}+\mathbf {T})$
satisfies the desired properties.
By Step 1, the coefficients of
$B_Z$
belong to
$\Omega $
and
$q\mathbf {P}$
is b-nef and b-Cartier. By Steps 2 and 3,
$q\mathbf {T}$
is b-Cartier. By Step 4,
$(Z,B_Z, \mathbf {P}+\mathbf {T})$
is generalized log canonical. Finally, by Steps 1 and 3, we have
$$\begin{align*}q(K_X+B+{\mathbf{M}_{X}})\sim q\pi^*(K_Z+B_Z+{\mathbf{P}_{Z}} + {\mathbf{T}_{Z}}).\\[-38pt] \end{align*}$$
Proof. Theorem 7
$(c-1)$
implies that Theorem 6.2
$(c)$
holds.
Let
$(X,B,\mathbf {M})$
be a generalized pair in the statement of Theorem 8
$(c)$
. We may replace
$(X,B,\mathbf {M})$
by a
$\mathbb {Q}$
-factorial generalized dlt modification and assume that
$(X,B,\mathbf {M})$
is
$\mathbb {Q}$
-factorial generalized dlt. Since X is of Fano type over Z, we can run an MMP on
${\mathbf {M}_{X}}$
over Z to get a model
$(X',B',\mathbf {M})$
such that
${\mathbf {M}_{X'}}$
is semiample over Z. After replacing
$(X,B,\mathbf {M})$
with
$(X',B',\mathbf {M})$
, up to losing the generalized dlt property for
$(X,B,\mathbf {M})$
, we may assume that
${\mathbf {M}_{X}}$
is semiample over Z. Let
$X\to Z'$
be the morphism induced by
$\mathbf {M}$
. Since
$\mathbf {M}$
is trivial on a general fiber of
$\pi $
, the morphism
$Z'\to Z$
is birational. After replacing Z with
$Z'$
, we may assume that
$\mathbf {M}\sim _{\mathbb {Q}}0$
over Z. Now, the result follows from Theorem 6.2
$(c)$
.
7 Proof of the theorems
In this section, we prove the main theorems of this article. In this section, we use the notation from Section: ‘Strategy of the Proof’, we write Theorem
$X(d,c)$
for Theorem X in dimension d and coregularity at most c. The following is the boundedness of complements for Fano type pairs of coregularity
$0$
. Note that the following theorem is an unconditional version of Theorem 7
$(0)$
.
Theorem 7.1. Let p be a positive integer. Let
$\Lambda \subset \mathbb {Q}$
be a closed set satisfying the descending chain condition. There exists a constant 
satisfying the following. Let X be a Fano type variety and
$(X,B,\mathbf {M})$
be a generalized pair of absolute coregularity
$0$
. Assume that the following conditions hold:
-
• the coefficients of B belong to
$\Lambda $
; -
•
$p\mathbf {M}$
is b-Cartier.
Then, there exists a boundary
$B^+\geq B$
such that
-
• the generalized pair
$(X,B^+,\mathbf {M})$
is generalized log canonical; -
• we have that
$N(K_X+B^+ +\mathbf {M})\sim 0$
; and -
• the equality
$\mathrm {coreg}(X,B^+,\mathbf {M})=0$
holds.
Proof. First, we replace
$\Lambda $
with its derived closure (see Lemma 2.16). We let 
be the finite subset provided by Theorem 3.5. This finite subset only depends on
$\Lambda $
and p.
By [Reference Filipazzi and Moraga14, Theorem 1.2], there is a constant
$N(\Lambda ,d,0,p)$
such that every generalized pair
$(X,B,\mathbf {M})$
as in the statement and of dimension at most d admits an
$N(\Lambda ,d,0,p)$
-complement. We will proceed by induction on d. We may assume that
$N(\Lambda ,d,0,p)$
is divisible by
$I(\Lambda )$
and p for every d. Throughout the proof, we assume that
$N(\Lambda ,d,0,p)$
is minimal with such properties.
By Theorem 3.5, we may assume that the coefficients of B belong to
$\mathcal {R}$
. Let
$B+\Gamma $
be a
$\mathbb {Q}$
-complement of
$(X,B,\mathbf {M})$
of coregularity
$0$
. Let
$(Y,B_Y+\Gamma _Y,\mathbf {M})$
be a generalized dlt modification of
$(X,B+\Gamma ,\mathbf {M})$
. Here,
$\Gamma _Y$
is the strict transform of the fractional part of
$\Gamma $
and
$B_Y$
is the reduced exceptional plus the strict transform of
$B+\lfloor \Gamma \rfloor $
. By Lemma 2.13, Y is a Fano type variety. Thus, we may run a
$-(K_Y+B_Y+{\mathbf {M}_{Y}})$
-MMP which terminates with a good minimal model Z since
$-(K_Y+B_Y+{\mathbf {M}_{Y}})\sim _{\mathbb {Q}}\Gamma _Y$
is effective. Let
$B_Z$
be the strict transform of
$B_Y$
on Z and
${\mathbf {M}_{Z}}$
be the trace of
$\mathbf {M}$
on Z. Note that
$(Z,B_Z,\mathbf {M})$
is a generalized pair of coregularity
$0$
and
$-(K_Z+B_Z+{\mathbf {M}_{Z}})$
is a semiample divisor. In order to produce an N-complement for
$(X,B,\mathbf {M})$
, it suffices to produce an N-complement for
$(Z,B_Z,\mathbf {M})$
(see Lemma 2.12 and Lemma 2.13). Hence, we may replace
$(X,B,\mathbf {M})$
with
$(Z,B_Z,\mathbf {M})$
and assume that
$-(K_X+B+{\mathbf {M}_{X}})$
is semiample and that
$(X,B,\mathbf {M})$
has coregularity 0. By [Reference Filipazzi and Moraga14, Theorem 1.2], then this reduction shows that Theorem 7
$(d,0)$
holds for any d; this will be used to then appeal to Theorem 5.1.
If
$K_X+B+{\mathbf {M}_{X}} \sim _{\mathbb {Q}} 0$
, then the statement follows from [Reference Filipazzi, Mauri and Moraga13, Theorem 1]. Hence, we may assume that the ample model W of
$-(K_X+B+{\mathbf {M}_{X}})$
is positive-dimensional. Since
$(X,B,\mathbf {M})$
has coregularity
$0$
and
$\dim W>0$
, then some generalized log canonical center of
$(X,B,\mathbf {M})$
is vertical over W. We may replace
$(X,B,\mathbf {M})$
with a generalized dlt modification and assume that some
$S\subset \operatorname {\mathrm {Supp}} \lfloor B\rfloor $
is vertical over W. Write
$\Xi =B-S$
. Let
$X'$
be the ample model of
$\Xi +{\mathbf {M}_{X}}$
over W. Notice that, since X is of Fano type and S is vertical over W,
$X \dashrightarrow X'$
is a birational contraction. Let
$\Xi ', B'$
be the push-forward of
$\Xi , B$
on
$X'$
. Note that S is not contained in
$\mathrm {Bs}(\Xi +{\mathbf {M}_{X}}/W)$
. Hence, S is a generalized log canonical place of
$(X',B'-\epsilon \Xi ',(1-\epsilon )\mathbf {M})$
for every
$\epsilon>0$
small enough. Let
$(Y,B_Y,\mathbf {M})$
be a
$\mathbb {Q}$
-factorial generalized dlt modification of
$(X',B',\mathbf {M})$
. Let
$\pi \colon Y\rightarrow X'$
be the associated projective morphism. We write
$\Xi _Y+{\mathbf {M}_{Y}}=\pi ^*(\Xi +{\mathbf {M}_{X}})$
.
By construction, the following conditions hold:
-
• the generalized pair
$(Y,B_Y,\mathbf {M})$
is generalized dlt and
$-(K_Y+B_Y+{\mathbf {M}_{Y}})$
is nef; -
• the generalized pair
$(Y,B_Y-\epsilon \Xi _Y,(1-\epsilon )\mathbf {M})$
is generalized dlt, it is not generalized klt, and the divisor
$-(K_Y+B_Y-\epsilon \Xi _Y+(1-\epsilon ) {\mathbf {M}_{Y}})$
is big and nef.
By Lemma 2.12 and Lemma 2.13, an N-complement of
$(Y,B_Y,\mathbf {M})$
induces an N-complement of
$(X,B,\mathbf {M})$
. By Theorem 5.1, we conclude that
$(Y,B_Y,\mathbf {M})$
admits an
$N(D(\mathcal {R}),d-1,0,p)$
-complement. Notice that we can rely on Theorem 5.1 in lower dimension, since we are proceeding by induction on d, and the conjectures to which Theorem 5.1 is conditional are known in coregularity 0 (by the remarks under the statement of Theorem 7). Hence,
$(X,B,\mathbf {M})$
admits a
$N(D(\mathcal {R}),d-1,0,p)$
-complement. Note that
$D(\mathcal {R})\subset \Lambda $
. So this is also a
$N(\Lambda ,d-1,0,p)$
-complement. Thus, by the minimality of
$N(\Lambda ,d,0,p)$
, we have that
$$\begin{align*}N(\Lambda,d,0,p) \leq N(\Lambda,d-1,0,p). \end{align*}$$
This implies that
$N(\Lambda ,d,0,p)$
is bounded above by
$N(\Lambda ,1,0,p)$
. This finishes the proof.
Proof of Theorem 4.
We follow the notation of the proof of Theorem 7.1. By [Reference Filipazzi, Mauri and Moraga13, Corollary 3], a log Calabi–Yau pair with standard coefficients and coregularity
$0$
has coefficients in
$\left \{\frac {1}{2},1\right \}$
. In particular, a generalized log canonical threshold with standard coefficients and coregularity
$0$
belongs to
$\left \{\frac {1}{2},1\right \}$
(see Definition 2.26 and [Reference Figueroa, Moraga and Peng10, Theorem 4.3]). On the other hand, by Corollary 3.3, a generalized pseudo-effective threshold with standard coefficients and coregularity 0 is either
$\frac {1}{2}$
or
$1$
. In the proof of Theorem 3.5, the set
$\mathcal {R}(\mathcal {S},0,2)$
only consists of log canonical thresholds of coregularity 0 and pseudo-effective thresholds of coregularity 0. Hence, by the proof of Theorem 3.5, we may assume that the coefficients of B belong to
$\{\frac {1}{2},1\}$
, that is, we have that
Note that
$I_{\mathcal {S}}=1$
(see Definition 2.14) and
$p=2$
in this case. By the proof of Theorem 7.1, we conclude that
$$\begin{align*}N(\mathcal{S},d,0,2) = N(\mathcal{R}_0,d,0,2) \leq N(\mathcal{R}_0,d-1,0,2), \end{align*}$$
for every
$d\geq 2$
. Then, the proof follows as
$N(\mathcal {S},1,0,2)=2$
.
Proof. By Lemma 2.16, we may assume that
$\Lambda $
is derived. By [Reference Filipazzi, Mauri and Moraga13, Theorem 2], we may assume that the coefficients of B belong to a finite subset
$\Lambda _0\subset \Lambda $
. Let
$\lambda _0$
be the smallest positive integer such that
$\lambda _0\Lambda _0 \subset \mathbb {Z}$
and p divides
$\lambda _0$
. Let
$I(\Lambda _0,c,d,p)$
be the smallest positive integer that is divisible by the index of all the generalized pairs as in the statement of dimension at most d. A priori,
$I(\Lambda _0,c,d,p)$
may not exist. However, due to Conjecture 1 and Lemma 2.30, we know that
$I(\Lambda _0,c,c,p)$
is finite. We proceed by induction on the dimension d. Assume that
$I(\Lambda _0,d-1,c,p)$
is finite. We may assume that
$I(\Lambda _0,d-1,c,p)$
is divisible by
$\lambda _0$
. Let
$(X,B,\mathbf {M})$
be a d-dimensional generalized pair as in the statement. We write
$I(X,B,\mathbf {M})$
for the index of this generalized log Calabi–Yau pair.
By Theorem 2.29, we may replace
$(X,B,\mathbf {M})$
with a Kollár–Xu model and assume the following conditions hold:
-
• the generalized pair
$(X,B,\mathbf {M})$
is generalized dlt; -
• there is a contraction
$\pi \colon X\rightarrow Z$
for which
$\lfloor B\rfloor $
fully supports a
$\pi $
-semiample and
$\pi $
-big divisor; and -
• every generalized log canonical center of
$(X,B,\mathbf {M})$
dominates Z.
In particular, we know that Z has dimension at most c.
We will proceed in two different cases, depending on the coefficients of
$B+{\mathbf {M}_{X}}$
and the rational connectedness of X.
Case 1: We assume that
$\mathbf {M}$
is numerically nontrivial and X is rationally connected.
We will proceed in two different sub-cases, depending on the coefficients of
$\{B\}+{\mathbf {M}_{X}}$
.
Case 1.1: We assume that
$\{B\}+{\mathbf {M}_{X}}$
is
$\mathbb {Q}$
-trivial on the general fiber of
$\pi $
.
We observe that, given the running assumption that
$\mathbf {M}$
is numerically nontrivial, in this subcase we have
$\dim Z> 0$
. By Theorem 8
$(c)$
, we can write
$$\begin{align*}q(K_X+B+{\mathbf{M}_{X}}) \sim q\pi^*(K_Z+B_Z+{\mathbf{N}_{Z}}), \end{align*}$$
where
$(Z,B_Z,\mathbf {N})$
is a generalized klt log Calabi–Yau pair and the positive integer q only depends on
$\Lambda _0$
, c and p. The coefficients of
$B_Z$
belong to a set
$\Omega $
, which satisfies the DCC, and only depends on
$\Lambda _0$
, c and p. Finally, the divisor
$q\mathbf {N}$
is b-Cartier. We conclude that
$$\begin{align*}I(X,B,\mathbf{M}) \leq \mathrm{lcm}(q,I(\Omega,c,c,q)). \end{align*}$$
Note that the value on the r.h.s. only depends on
$\Lambda _0,c$
and p.
Case 1.2: We assume that
$\{B\}+{\mathbf {M}_{X}}$
is nontrivial on the general fiber of
$\pi $
.
We run a
$(K_X+\lfloor B\rfloor )$
-MMP over Z. Since
$K_X+\lfloor B\rfloor $
is not pseudo-effective over Z, this minimal model program terminates with a Mori fiber space
$\pi '\colon X' \rightarrow W$
over Z. We denote the push-forward of B to
$X'$
by
$B'$
. We may replace
$(X,B,\mathbf {M})$
with
$(X',B',\mathbf {M})$
and assume that
$K_X+\lfloor B\rfloor $
is antiample over W. In this reduction, we may give up the generalized dlt property for
$(X,B,\mathbf {M})$
, while
$(X,\lfloor B \rfloor ,\mathbf {M})$
remains generalized dlt. By the reduction to the Kollár–Xu model, the divisor
$\lfloor B\rfloor $
contains a prime component S which dominates W. By construction, the general fiber of
$S\rightarrow W$
is rationally connected. Since W is rationally connected, we conclude that S is rationally connected. Since
$(X,\lfloor B \rfloor ,\mathbf {M})$
is generalized dlt, S is normal. Let
$(S,B_S,\mathbf {N})$
be the generalized pair obtained by adjunction. Then, by Lemma 2.17 and [Reference Figueroa, Moraga and Peng10, Theorem 2], we know that the coefficients of
$B_S$
belong to
$\Lambda _0$
and
$p\mathbf {N}$
is b-Cartier. We conclude that
$$\begin{align*}I(\Lambda_0,d-1,c,p)(K_S+B_S+{\mathbf{N}_{S}})\sim 0. \end{align*}$$
By Theorem 2.31, we conclude that
$$\begin{align*}I(\Lambda_0,d-1,c,p)(K_X+B+{\mathbf{M}_{X}})\sim 0. \end{align*}$$
Putting Case 1.1 and Case 1.2 together, we conclude that if
$\mathbf {M}$
is numerically nontrivial and X is rationally connected, then we have that
$$\begin{align*}I(X,B,\mathbf{M}) \leq \max\{I(\Lambda_0,d-1,c,p), \mathrm{lcm}(q,I(\Omega,c,c,q))\}. \end{align*}$$
Case 2: We assume that either
$\mathbf {M}$
is the trivial b-divisor or
$\mathbf {M}$
is numerically trivial and X is rationally connected.
In the latter case, by [Reference Filipazzi, Mauri and Moraga13, Lemma 3.9] we know that
$p{\mathbf {M}_{X'}}\sim 0$
where
$X'\rightarrow X$
is a resolution on which
$\mathbf {M}$
descends. Replacing
$\mathbf {M}$
with
$p\mathbf {M}$
, we may assume that the first case holds.
Let
$(X,B)$
be a log Calabi–Yau pair as in the statement. We assume that the coefficients of B belong to
$\Lambda _0$
. We may assume that
$d>c$
. We replace
$(X,B)$
with a
$\mathbb {Q}$
-factorial dlt modification. Let
$S\subset \lfloor B\rfloor $
be a prime component. We run a
$(K_X+B-S)$
-MMP. This terminates with a Mori fiber space
$\pi '\colon X'\rightarrow W$
. We denote by
$B'$
the push-forward of B to
$X'$
. We replace
$(X,B)$
with
$(X',B')$
. Note that S is ample over the base W and
$(X,B-S)$
is dlt. Let
$(S,B_S)$
be the pair obtained by adjunction. Then,
$(S,B_S)$
is a semilog canonical log Calabi–Yau pair by [Reference Fujino and Gongyo19, Example 2.6]. Furthermore, by Lemma 2.17 and [Reference Figueroa, Moraga and Peng10, Theorem 2], the coefficients of
$B_S$
belong to
$\Lambda _0$
. By Theorem 4.9, up to replacing
$I(\Lambda _0,d-1,c)$
with
$\mathrm {lcm}(I(\Lambda _0,d-1,c),I_a(\Lambda _0,c))$
, we may assume that
$$\begin{align*}I(\Lambda_0,d-1,c,0)(K_S+B_S)\sim 0. \end{align*}$$
Here,
$I_a(\Lambda _0,c)$
is the constant from Theorem 4.9. By construction, we have that
$(X,B-S)$
is dlt, X is
$\mathbb {Q}$
-factorial and klt, and
$S\subset \lfloor B\rfloor $
is ample over W. If the fibers of
$S\rightarrow W$
are connected, then we can apply Theorem 4.12, to conclude that
$$\begin{align*}I(\Lambda_0,d-1,c,0)(K_X+B)\sim 0. \end{align*}$$
Otherwise, we can apply Theorem 2.32, to conclude that
$$\begin{align*}I(\Lambda_0,d-1,c,0)(K_X+B)\sim 0. \end{align*}$$
Putting Case 1 and Case 2 together, we conclude that every generalized pair
$(X,B,\mathbf {M})$
of dimension d as in the statement satisfies that
$$\begin{align*}I(X,B,\mathbf{M}) \leq \max\{ I(\Lambda_0,d-1,c,p), \mathrm{lcm}(q,I(\Omega,c,c,q)) \}. \end{align*}$$
Hence, we have that
$$\begin{align*}I(\Lambda_0,d,c,p) \leq \max\{ I(\Lambda_0,d-1,c,p), \mathrm{lcm}(q,I(\Omega,c,c,q)) \}. \end{align*}$$
Proceeding inductively, we conclude that
$$\begin{align*}I(\Lambda_0,d,c,p) \leq \max\{ I(\Lambda_0,c,c,p),qI(\Omega,c,c,c) \}. \end{align*}$$
The r.h.s. does not depend on d. This finishes the proof of the proposition.
Lemma 7.3. Let
$\lambda $
be a positive integer. Let
$(\mathbb {P}^1,B_{\mathbb {P}^1},{\mathbf {M}_{\mathbb {P}^1}})$
be a generalized log Calabi–Yau pair. Assume that the coefficients of
$B_{\mathbb {P}^1}$
belong to
$D_\lambda $
and
$2\lambda {\mathbf {M}_{\mathbb {P}^1}}$
is Weil. Then,
$I(K_{\mathbb {P}}^1+B_{\mathbb {P}^1}+{\mathbf {M}_{\mathbb {P}^1}})\sim 0$
for some
$I=m\lambda $
, where
$m \leq 120\lambda $
is an even positive integer. Furthermore, if
${\mathbf {M}_{\mathbb {P}^1}}=0$
, then
$H^0(\mathbb {P}^1,\mathcal {O}_{\mathbb {P}^1}(I(K_{\mathbb {P}}^1+B_{\mathbb {P}^1})))$
admits an admissible section.
Proof. We prove the second statement. Let
$G=\mathrm {Aut}(\mathbb {P}^1,B_{\mathbb {P}^1})$
. The group G is a finite extension of a torus. First, we assume that G is finite, which turns to imply that
$B_{\mathbb {P}^1}$
is supported in at least three points. Let
$(\mathbb {P}^1,B_{\mathbb {P}^1})\rightarrow (\mathbb {P}^1,B^{\prime }_{\mathbb {P}^1})$
be the quotient by G given by the Hurwitz formula. By pulling back to
$\mathbb {P}^1$
, it suffices to show that
$$\begin{align*}h^0(\mathbb{P}^1,\mathcal{O}_{\mathbb{P}^1}(I(K_{\mathbb{P}^1}+B^{\prime}_{\mathbb{P}^1}))) \neq 0 \end{align*}$$
for some
$I=m\lambda $
, where
$m\leq 120\lambda $
. We write
$$\begin{align*}B^{\prime}_{\mathbb{P}^1}=\sum_{i=1}^k\left( 1-\frac{1}{m_i}+\frac{\sum_{j=1}^{l_k}\frac{p_{j,k}}{\lambda}}{m_i} \right)\{p_i\}, \end{align*}$$
where the
$p_{j,k}$
’s are positive integers. We may assume that
$m_1\geq \dots \geq m_k$
. If
$m_1\leq 5$
, then for
$I=120\lambda $
, we have that
$IB^{\prime }_{\mathbb {P}^1}$
is Weil. If
$m_1>5$
, then
$m_3=\dots =m_k=1$
. If
$m_2>2\lambda $
, then
$m_1>2\lambda $
and
$$\begin{align*}\mathrm{coeff}_{p_1}(B^{\prime}_{\mathbb{P}^1}) + \mathrm{coeff}_{p_2}(B^{\prime}_{\mathbb{P}^1}) + \mathrm{coeff}_{p_3}(B^{\prime}_{\mathbb{P}^1})> \left(1-\frac{1}{2\lambda}\right) + \left(1-\frac{1}{2\lambda}\right) +\frac{1}{\lambda} = 2. \end{align*}$$
This leads to a contradiction. Hence, we may assume that
$m_2\leq 2\lambda $
. In this case, we have that
$m_2\lambda B^{\prime }_{\mathbb {P}^1}$
is Weil. Thus, it suffices to take
$I=m_2\lambda $
with
$m_2\leq 2\lambda $
.
Now, we assume that G is a finite extension of a torus. This implies that
$B_{\mathbb {P}^1}$
is supported in two points, so we may assume that
$B_{\mathbb {P}^1}=\{0\}+\{\infty \}$
and that
$G\simeq \mathbb {G}_m\rtimes \mathbb {Z}_2$
. Note that
$\mathbb {G}_m$
acts trivially on B-representations as it is connected. Hence, in this case,
$2(K_{\mathbb {P}^1}+B_{\mathbb {P}^1})$
admits an admissible section.
In the first statement, we need to control the index of the generalized pair. The same argument we used in the previous paragraph to control the index of
$(\mathbb {P}^1,B^{\prime }_{\mathbb {P}^1})$
applies to
$(\mathbb {P}^1,B_{\mathbb {P}^1},{\mathbf {M}_{\mathbb {P}^1}})$
. The only difference is that due to the presence of
$\mathbf {M}$
, it could be that
$B_{{\mathbb {P}^{1}}}$
is supported at only one point or it could even be empty. In this case,
$2\lambda (K_{{\mathbb {P}^{1}}}+ B_{{\mathbb {P}^{1}}} + {\mathbf {M}_{\mathbb {P}^1}})$
is integral, and the claims follow.
Proof of Theorem 2.
Let
$(X,B,\mathbf {M})$
be a d-dimensional generalized log Calabi–Yau pair as in the statement. We follow the proof of Proposition 7.2. In Case 1.1, we can write
$$\begin{align*}q(\lambda)(K_X+B+{\mathbf{M}_{X}}) \sim q(\lambda) \pi^*(K_{\mathbb{P}^1}+B_{\mathbb{P}^1}+{\mathbf{M}_{\mathbb{P}^1}}), \end{align*}$$
where
$(\mathbb {P}^1,B_{\mathbb {P}^1},{\mathbf {M}_{\mathbb {P}^1}})$
is a generalized log Calabi–Yau pair for which the coefficients of
$B_{\mathbb {P}^1}$
belong to a DCC set
$\Omega $
and
$2\lambda {\mathbf {M}_{\mathbb {P}^1}}$
is Weil. Here, we can take
$q(\lambda )=2\lambda $
. Indeed, the constant
$q(\lambda )$
in the canonical bundle formula depends on the existence of bounded complements with standard coefficients and relative absolute coregularity
$0$
. By Theorem 5.3 and Theorem 4 such relative complement can be chosen to be a
$2\lambda $
-complement. On the other hand, we can take
$\Omega =D_\lambda $
. Indeed, in this case,
$(X,B,\mathbf {M})$
admits a log canonical center which has a finite dominant map to
${\mathbb {P}^1}$
. Thus, the coefficients of
$B_{\mathbb {P}^1}$
can be computed by the adjunction formula and Riemann–Hurwitz. By Lemma 7.3, we conclude that
$I(K_{\mathbb {P}^1}+B_{\mathbb {P}^1}+{\mathbf {M}_{\mathbb {P}^1}})\sim 0$
for some integer
$I=m\lambda $
where
$m\leq 120\lambda $
. We conclude that
$I(K_X+B+{\mathbf {M}_{X}})\sim 0$
for the same choice of I.
In Case 1.2 and Case 2, the index of
$(X,B,\mathbf {M})$
divides the index of a possibly nonnormal log Calabi–Yau pair of coregularity 1 and dimension
$d-1$
. Inductively, we reduce to the one-dimensional case which follows by Theorem 4.9 and Lemma 7.3.
Proof of Theorem 3.
In a similar fashion as the proof of Theorem 2, this follows from the proof of Proposition 7.2 and the classification of log Calabi–Yau pair structures on
$\mathbb {P}^1$
with standard coefficients.
Proposition 7.4. Assume that Theorem 6
$(c)$
holds and Theorem 8
$(c)$
holds. Then, Theorem 7
$(c)$
holds.
Proof. By Lemma 2.16, we may assume that
$\Lambda $
is derived. Let
$N(\Lambda ,d,c,p)$
be the smallest positive integer for which every generalized pair
$(X,B,\mathbf {M})$
of dimension d as in the statement admits an N-complement. By Theorem 3.5, there exists a finite subset
$\mathcal {R}\subset \Lambda $
for which
$$\begin{align*}N(\mathcal{R},d,c,p)=N(\Lambda,d,c,p) \end{align*}$$
for every d. We proceed by induction on d. We may assume that every complement throughout the proof is divisible by p and
$I_{\mathcal {R}}$
. We write
$N(X,B,\mathbf {M})$
for the smallest positive integer for which
$(X,B,\mathbf {M})$
admits an N-complement of coregularity c. Let
$B+\Gamma $
be a
$\mathbb {Q}$
-complement of
$(X,B,\mathbf {M})$
that computes the absolute coregularity. Let
$(Y,B_Y+\Gamma _Y+E,\mathbf {M})$
be a generalized
$\mathbb {Q}$
-factorial dlt modification of
$(X,B+\Gamma _Y,\mathbf {M})$
, where
$B_Y$
(resp.
$\Gamma _Y$
) is the strict transform of the fractional part of B (resp.
$\Gamma $
). Then, the generalized pair
$(Y,B_Y+E,\mathbf {M})$
has coregularity c. We run a
$-(K_Y+B_Y+E)$
-MMP with scaling, which terminates with a good minimal model Z. By Lemma 2.22, the generalized pair
$(Z,B_Z+E_Z)$
has coregularity c. By Lemma 2.13 and Lemma 2.12, we have that
$N(X,B,\mathbf {M})\leq N(Z,B_Z+E_Z,\mathbf {M})$
. In order to give an upper bound for
$N(X,B,\mathbf {M})$
, we may replace
$(X,B,\mathbf {M})$
with
$(Z,B_Z+E_Z,\mathbf {M})$
. Thus, we may assume that
$\mathrm {coreg}(X,B,\mathbf {M})=c$
and
$-(K_X+B+{\mathbf {M}_{X}})$
is semiample. Let W be the ample model of
$-(K_X+B+{\mathbf {M}_{X}})$
. We proceed in three different cases, depending on the dimension of W.
Case 1: In this case, we can assume that
$\dim W=0$
.
Then, we have that
$N(K_X+B+{\mathbf {M}_{X}})\sim 0$
for some N that only depends on
$\Lambda $
, c and p by Theorem 6
$(c)$
.
Case 2: In this case, we assume that
$\dim W=\dim X$
.
In this case, we have that
$-(K_X+B+{\mathbf {M}_{X}})$
is a nef and big divisor. We may assume that
$(X,B,\mathbf {M})$
is
$\mathbb {Q}$
-factorial and generalized dlt. By Theorem 5.1, we conclude that
$N(X',B',\mathbf {M})\leq N(\Lambda ,d-1,c,p)=N(\mathcal {R},d-1,c,p)$
. In this case, we conclude that
$$\begin{align*}N(X,B,\mathbf{M})\leq N(\Lambda,d-1,c,p)=N(\mathcal{R},d-1,c,p). \end{align*}$$
Case 3: In this case, we assume that
$0<\dim W < \dim X$
.
We run a
$(\{B\}+{\mathbf {M}_{X}})$
-MMP over W which terminates with a good minimal model
$X\dashrightarrow X'\rightarrow W$
over W. By Lemma 2.22, the coregularity of
$(X,B,\mathbf {M})$
is unaffected by this MMP. Let
$W'\rightarrow W$
be the ample model of
$\{B\}+{\mathbf {M}_{X}}$
over the base. First, assume that
$\dim W'=\dim X$
. In this case,
$\{B'\}+{\mathbf {M}_{X'}}$
is big over W. Hence, for
$\epsilon>0$
small enough, we have that the generalized pair
$(X',B'-\epsilon \{B'\},(1-\epsilon )\mathbf {M})$
is generalized log canonical but not generalized klt and the divisor
$$\begin{align*}-(K_{X'}+B'-\epsilon \{B'\}+(1-\epsilon){\mathbf{M}_{X'}}) \end{align*}$$
is big and nef. Note that
$N(X,B,\mathbf {M})=N(X',B',\mathbf {M})$
. By Theorem 5.1, we conclude that
$$\begin{align*}N(X,B,\mathbf{M})\leq N(\Lambda,d-1,c,p)=N(\mathcal{R},d-1,c,p). \end{align*}$$
From now on, we assume that
$0<\dim W' < \dim X$
. We separate in two cases, depending on the log canonical centers of
$(X',B',\mathbf {M})$
.
Case 3.1: In this case, we assume that there is a generalized log canonical center of
$(X',B',\mathbf {M})$
that is vertical over
$W'$
.
We may assume that
$(X',B',\mathbf {M})$
is generalized dlt. Let
$S'\subset \lfloor B'\rfloor $
be a prime component that is vertical over
$W'$
. In this case,
$B^{\prime }_{\mathrm {hor}}$
is big over the base. We run a
$B^{\prime }_{\mathrm {hor}}$
-MMP over
$W'$
which terminates with a good minimal model
$X^{\prime }_0$
, and we consider its ample model
$X"$
over
$W'$
. We have the following commutative diagram:
Note that all the previous models are crepant. Hence, we have that
$$ \begin{align} N(X,B,\mathbf{M})= N(X',B',\mathbf{M})= N(X",B",\mathbf{M}). \end{align} $$
By construction, the following conditions are satisfied:
-
• the variety W is an ample model for
$-(K_X+B+{\mathbf {M}_{X}})$
; -
• the variety
$W'$
is an ample model for
$\{B'\}+M_{X'}$
over W; -
• the variety
$X^{\prime }_0$
is a good minimal model for
$B^{\prime }_{0,\mathrm {hor}}$
over
$W'$
; and -
• the variety
$X"$
is an ample model for
$B^{\prime \prime }_{\mathrm {hor}}$
over
$W'$
.
We conclude that the divisor
$$\begin{align*}-(K_{X"}+B"-\epsilon\{B"\}-\delta B^{\prime\prime}_{\mathrm{hor}}+ (1-\epsilon){\mathbf{M}_{X"}}) \end{align*}$$
is ample for
$\epsilon \gg \delta>0$
small enough. We claim that the generalized pair
$$\begin{align*}(X",B"-\epsilon\{B"\}-\delta B^{\prime\prime}_{\mathrm{hor}}, (1-\epsilon)\mathbf{M}) \end{align*}$$
is generalized log canonical but not generalized klt. Note that
$(X^{\prime }_0, B^{\prime }_0-\epsilon \{B^{\prime }_0\}-\delta B^{\prime }_{0,\mathrm {hor}},(1-\epsilon )\mathbf {M})$
is generalized log canonical and not generalized klt as
$S^{\prime }_0$
is a component of
$\lfloor B^{\prime }_0-\epsilon \{B^{\prime }_0\}-\delta B^{\prime }_{0,\mathrm {hor}}\rfloor $
. The morphism
$\psi $
is
$(K_{X_0'}+B_0'-\epsilon \{B_0'\}-\delta B^{\prime }_{0,\mathrm {hor}}+(1-\epsilon )\mathbf {M}_{X^{\prime }_0})$
-trivial, so the claim follows. By Theorem 5.1 and the sequence of equalities (7.1), we conclude that
$$\begin{align*}N(X,B,\mathbf{M})\leq N(\Lambda,d-1,c,p)=N(\mathcal{R},d-1,cp). \end{align*}$$
Thus, in this case, we have that
$N(X,B,\mathbf {M})\leq N(\mathcal {R},d-1,c)$
.
Case 3.2: In this case, we assume that all the generalized log canonical centers of
$(X',B',\mathbf {M})$
are horizontal over
$W'$
.
Let
$\pi '\colon X'\rightarrow W'$
be the projective contraction. We may apply Theorem 8
$(c)$
to obtain a linear equivalence:
$$\begin{align*}q(K_{X'}+B'+{\mathbf{M}_{X'}})\sim q\pi^{\prime}\ast(K_{W'}+B_{W'}+{\mathbf{N}_{W'}}), \end{align*}$$
where the following conditions are satisfied:
-
• the generalized pair
$(W',B_{W'},\mathbf {N})$
is of Fano type, has dimension
$d_{W'}\leq c$
and is exceptional (i.e., its absolute coregularity is equal to its dimension
$d_{W'}$
); -
• the positive integer q only depends on
$\Lambda $
, c and p; -
• the coefficients of
$B_{W'}$
belong to a DCC set
$\Omega $
which only depends on
$\Lambda $
, c and p; and -
• the b-nef divisor
$q\mathbf {N}$
is b-Cartier.
Indeed, if
$(W',B_{W'},\mathbf {N})$
is not exceptional, by pulling back a non-klt complement of it, we obtain a complement for
$(X',B',\mathbf {M})$
of coregularity strictly less than c. This leads to a contradiction. By [Reference Filipazzi and Moraga14, Theorem 1.2], any generalized pair
$(W',B_{W'},\mathbf {N})$
as above admits an
$N(\Omega ,d_{W'},d_{W'},q)$
-complement. By pulling back, we obtain an N-complement for
$(X',B',\mathbf {M})$
for some
$$\begin{align*}N\leq \mathrm{lcm}(q,N(\Omega,d_{W'},d_{W'},q)). \end{align*}$$
Putting Case
$1$
through Case
$3$
together, we conclude that
$$\begin{align*}N(X,B,\mathbf{M}) \leq \max\{ N(\mathcal{R},d-1,c,p), \mathrm{lcm}(q,N(\Omega,1,1,q)), \ldots, \mathrm{lcm}(q,N(\Omega,c,c,q)) \}. \end{align*}$$
for every d-dimensional generalized pair
$(X,B,\mathbf {M})$
as in the statement. Proceeding inductively, we conclude that every generalized pair
$(X,B,\mathbf {M})$
as in the statement of the theorem satisfies that
$$\begin{align*}N(X,B,\mathbf{M}) \leq \max\{ N(\mathcal{R},c,c,p), \mathrm{lcm}(q,N(\Omega,1,1,q)), \ldots, \mathrm{lcm}(q,N(\Omega,c,c,q)) \}. \end{align*}$$
Observe that the number on the r.h.s. only depends on
$\Lambda ,c$
and p. This finishes the proof of the implication.
Lemma 7.5. Let
$(\mathbb {P}^1,B_{\mathbb {P}^1},{\mathbf {M}_{\mathbb {P}^1}})$
be a generalized log Calabi–Yau pair for which
$\mathrm {coeff}(B_{\mathbb {P}^1})\in D_t(\mathbb {Z}_{>0})$
and
$2{\mathbf {M}_{\mathbb {P}^1}}$
is Cartier. If
$t>\frac {5}{6}$
, then
$t=1$
.
Proof. Each coefficient of
$B_{\mathbb {P}^1}$
is either standard or of the form
$$ \begin{align} 1-\frac{1}{m}+\frac{t}{m}> 1-\frac{1}{6m}>5/6. \end{align} $$
The only sets of standard coefficients whose sum is less than
$\frac {7}{6}$
are
$\{1\}$
and
$\{\frac {1}{2},\frac {1}{2}\}$
. Thus,
$B_{\mathbb {P}^1}$
is supported in at most
$3$
points and
$t=1$
.
Proof of Theorem 5.
Let
$(X,B,\mathbf {M})$
be a d-dimensional generalized pair as in the statement. Following Step 1 of the proof of Theorem 3.5, let t be a log canonical threshold of coregularity
$1$
(or a pseudo-effective threshold) of a prime divisor with respect to
$(X,B,\mathbf {M})$
. By [Reference Figueroa, Moraga and Peng10, Lemma 3.2] (or proof of Lemma 3.2 in the case where t is a pseudo-effective threshold), we can construct a generalized log Calabi–Yau pair
$$\begin{align*}(\mathbb{P}^1,B_{\mathbb{P}^1},{\mathbf{M}_{\mathbb{P}^1}}) \end{align*}$$
for which
$\mathrm {coeff}(B_{\mathbb {P}^1})\in D_{t}(\{1\})$
and
$2{\mathbf {M}_{\mathbb {P}^1}}$
is Cartier. By Lemma 7.5, we conclude that
$t=1$
provided that
$t>5/6$
. Hence, by the proof of Theorem 3.5, we may assume that the coefficients of B belong to
Proceeding as in the proof of Proposition 7.4, we conclude that
$$\begin{align*}N(X,B,\mathbf{M}) \leq N(\mathcal{R}_1,d,1,2) \leq \mathrm{lcm}(2, N(\mathcal{R}_1,1,1,2) ). \end{align*}$$
Note that we can take
$q=2$
due to Theorem 1. We conclude that
$N\in \{2,4,6\}$
.
We prove the three main theorems of the article. The theorems are proved together inductively.
Proof of Theorems 6, 7 and 8.
Note that Theorem 8
$(0)$
is trivial. By [Reference Filipazzi, Mauri and Moraga13, Theorem 1], we conclude that Theorem 6
$(0)$
holds. By Theorem 7.1, we know that Theorem 7
$(0)$
holds. Assume that Theorem 6
$(c-1)$
, Theorem 7
$(c-1)$
and Theorem 8
$(c-1)$
hold. By Proposition 6.3, we conclude that Theorem 8
$(c)$
holds. By Proposition 7.2, we conclude that Theorem 6
$(c)$
holds. By Proposition 7.4, we conclude that Theorem 7
$(c)$
holds. This finishes the proof of the theorems.
Finally, we prove the application to klt singularities.
Proof of Theorem 9.
Let
$(X;x)$
be a klt singularity of absolute coregularity
$0$
. Let
$(X,\Gamma _0;x)$
be a strictly log canonical pair of coregularity
$0$
at x. By [Reference Xu43, Lemma 1], there exists a plt blow-up
$\pi \colon Y\rightarrow X$
that extracts a unique exceptional divisor E that is a log canonical place of
$(X,\Gamma _0;x)$
.Footnote
3
In particular, the pair
$(E,\mathrm {Diff}_E(0))$
is a Fano pair of absolute coregularity 0 and with standard coefficients (see, e.g., [Reference Shokurov39, Proposition 3.9]). By Theorem 4,
$(E,\mathrm {Diff}_E(0))$
admits a 1- or 2-complement. By Steps 4–9 of the proof of Proposition 5.2, we can lift this complement to a 1- or 2-complement of
$(X;x)$
at x.
Acknowledgements
This project was initiated in the Minimal Model Program Learning Seminar. The authors would like to thank Mirko Mauri for many discussions that led to some of the ideas of this article. Lastly, the authors would like to thank the anonymous referee for useful comments and suggestions that helped the authors improve the clarity of this work.
Funding statement
SF was partially supported by ERC starting grant #804334. FF received partial financial support by the NSF under János Kollár’s grant number DMS-1901855.
Competing interest
The authors have no competing interest to declare.
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