Effective Adjunction Theory
Marco Andreatta, Claudio Fontanari

TL;DR
This paper explores the effectivity of adjoint divisors on algebraic varieties, establishing criteria for uniruledness and non-vanishing of sections in polarized manifolds, advancing understanding of their geometric properties.
Contribution
It proves new characterizations of uniruled varieties and non-vanishing results for adjoint line bundles on polarized manifolds.
Findings
Uniruledness characterized by vanishing of certain sections.
Non-vanishing of sections for $K_X+tL$ when pseudo-effective.
Provides criteria linking effectivity and geometric properties.
Abstract
Here we investigate the property of effectivity for adjoint divisors. Among others, we prove the following results: (i) A normal projective variety with at most canonical singularities is uniruled if and only if for each very ample Cartier divisor on we have for some . (ii) Let be a polarized manifold of dimension and let be an integer with . If is pseudo-effective, then .
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Effective Adjunction Theory
Marco Andreatta and Claudio Fontanari
[email protected], [email protected] Dipartimento di Matematica
Università degli Studi di Trento
Via Sommarive 14
38123 Trento
Italy.
Abstract.
Here we investigate the property of effectivity for adjoint divisors. Among others, we prove the following results:
A projective variety with at most canonical singularities is uniruled if and only if for each very ample Cartier divisor on we have for some .
Let be a projective -fold, an ample divisor and an integer with . If is pseudo-effective, then .
We would like to thank Paolo Cascini, Roberto Pignatelli and Luis Sola-Conde for fruitful conversations. We are grateful to János Kollár for pointing out his examples and for suggesting projective varieties with canonical singularities as a good category to settle our results. We also thank the referees for useful comments. The research project was partially supported by GNSAGA of INdAM, by PRIN 2015 ”Geometria delle varietà algebriche”, and by FIRB 2012 ”Moduli spaces and Applications”.
2010 Mathematics Subject Classification: 14E30, 14J40, 14J35, 14N30.
1. Introduction
Let be a normal projective variety over the complex field ; let be its canonical divisor. We assume that has at most canonical singularities.
In the paper we fix a suitable Cartier divisor on and we discuss when the effectivity or non-effectivity of some adjoint divisors determines the geometry of .
In the first part we consider the notion of Termination of Adjunction. This turns out to be rather delicate, since in the literature there are different meanings for such a property. The following are four possibilities, where and are natural numbers.
- (A)
For every (for some) big Cartier divisor there exists such that (i.e. it is not pseudo-effective) for .
- (B)
For every big Cartier divisor we have for some .
- (C)
For every very ample Cartier divisor we have for some .
- (D)
For some (for every) big Cartier divisor we have for every and some .
It is clear that (A) (B) (C) (D).
We prove that these four definitions are equivalent and moreover that Adjunction Terminates in the above sense if and only if is uniruled (see Theorem 3, Corollary 1 and Corollary 2).
The results follow by some characterizations of pseudo-effective Cartier divisor (see Theorem 2), which are direct consequences of a fundamental result of Siu ([22]). The connection with uniruledness follows in turn from the fact that a projective variety with canonical singularities is uniruled if and only if is not pseudo-effective (see [3], Corollary 0.3, or [5], Corollary 1.3.3).
A characterization of rationally connected manifolds along the same lines has been given in [6].
The examples described in [15], Theorem 39, show that, for varieties with singularities worst then canonical, uniruledness is not connected to Termination of Adjunction.
We consider also the following more general definition.
- (C’)
Let be an effective Cartier divisor on . We say that Adjunction Terminates in the classical sense for if there exists an integer such that
[TABLE]
for every integer .
We conjecture that such a definition is actually equivalent to the previous ones; a partial result in this direction is provided by Proposition 2. In dimension two, Castelnuovo and Enriques indeed proved that Condition (C’) implies that is uniruled (see [7] and also [20]).
In the second part of the paper we assume that is a projective variety of dimension with at most terminal -factorial singularities. We take a nef and and big Cartier divisor on and we call a quasi polarized pair.
The following is a straightforward consequence of Theorem D in [5], see Remark 5 at the beginning of Section 5.
Proposition 1**.**
Let be a quasi polarized pair and . If , then there exists such that .
Note that for the statement of the Proposition would amount to Abundance Conjecture, together with MMP.
The next Conjecture is an effective version of the above Proposition.
Conjecture 1**.**
Let be a quasi polarized pair and . If , then .
The case is a version of the so-called Ambro-Ionescu-Kawamata conjecture, which is true for (see Theorem 1.5 in [14]), while for we recover a conjecture by Beltrametti and Sommese (see [4], Conjecture 7.2.7). Note that if Conjecture 1 holds for then it holds also for every .
In the paper we consider the following conjecture.
Conjecture 2**.**
Let be a quasi polarized pair and . Then for every integer with if and only if is not pseudo-effective.
Since is big, in particular pseudo-effective, then the if part is obvious. Note that Conjecture 2 for implies Conjecture 1.
We prove that Conjecture 2 is true for (see Proposition 4); we actually show that this case happens if and only if the pair is birationally equivalent (via a [math]-reduction, see the definition in the next section) to the pair .
For the conjecture was essentially proved by Höring, see [14], Theorem 1.2. We prove a slightly more explicit version of his result (see Proposition 7), namely, we show that this case happens if and only if the pair is birationally equivalent to a finite list of pairs.
Finally, we focus on the case (see Theorem 8 and Proposition 6) and we generalize previous work by Fukuma ([12], Theorem 3.1).
2. Notation and preliminaries
Let be a normal complex projective variety of dimension . We adopt [16] and [17] as the standard references for our set-up. In particular, we denote by the group of all Cartier divisors on and by the subgroup of numerically trivial divisors. The quotient group is the Neron-Severi group of .
In the vector space , whose dimension is , we consider some convex cones.
- (a)
the convex cone of all ample -divisor classes; it is an open convex cone.
- (b)
the convex cone of all big -divisor classes; it is an open convex cone.
- (e)
the convex cone spanned by the classes of all effective -divisors.
- (n)
the closed convex cone of all nef -divisor classes.
- (p)
the closed convex cone of all pseudo-effective -divisor classes.
The above definitions actually lean on some fundamental results like the openess of the ample and big cones, the facts that and ; for more details see [17].
Note that and that there are no inclusions between and .
Note also that if is a birational morphism and is a Cartier divisor on then is big (resp. pseudo-effective) if and only if is big (resp. pseudo-effective).
We consider projective varieties with singularities of special type, as in the Minimal Model Program. For reader convenience we recall their definition (see [16], Definition 2.11 and Definition 2.12).
Definition 1**.**
Let be a normal projective variety. We say that has canonical (respectively terminal) singularities if
- i)
is -Cartier, and
- ii)
for one (or for any) resolution of the singularities
(respectively
- ii)
for one (or for any) resolution of the singularities , where is the reduced exceptional divisor).
In the category of projective varieties with canonical singularities the pseudo-effectivity of the canonical bundle is a birational invariant, as noticed by Mori in [19], (11.4.1). He actually conjectured the following beautiful result ([19], (11.4.2) and (11.5)), which was proved in [3], Corollary 0.3 and in [5], Corollary 1.3.3.
Theorem 1**.**
Let be a projective variety with at most canonical singularities. Then is uniruled if and only if is not pseudoeffective.
As for the invariance of the global sections of adjoint bundles (or of pluri-canonical bundles if is trivial) we have the following.
Lemma 1**.**
Let be a birational morphism between projective varieties with at most canonical singularities, let be a Cartier divisor on and let . Then
[TABLE]
Proof.
Since and have canonical singularities we have . This is straightforward from the definition of canonical singularities and by taking a resolution of , , and as a resolution of .
Since is Cartier, by projection formula it follows
[TABLE]
by taking global sections we obtain our statement. ∎
3. Termination of Adjunction
Much of this section is based on the following Lemma, which was proved in the analytic setting by Siu (see [22], Proposition 1). For reader convenience we provide an algebraic proof relying on [18] (see also [21], Chapter V, Corollary 1.4).
Lemma 2**.**
Let be a smooth projective variety of dimension and let be a very ample divisor on . If , then for every pseudo-effective divisor on we have .
Proof.
Since is pseudo-effective we have that is big, hence there exists a positive integer such that with ample and effective (see for instance [17], Corollary 2.2.7). Let and , so that is big and nef; apply [18], Proposition 9.4.23, to get . Since the multiplier ideal is an ideal of , it follows that for every , i.e. as soon as . ∎
The following characterization of pseudo-effective divisors is probably well-known to the specialists; however, we did not find it explicitly in the literature.
Theorem 2**.**
Let be a smooth projective variety and let be a divisor on . The following statements, where and denote natural numbers, are equivalent:
- i)
* (i.e it is pseudo-effective).*
- ii)
There is a big divisor such that for every and for some .
- iii)
There is a big divisor such that for all .
- iv)
There is a very ample divisor such that for all .
- v)
For every big divisor we have for all and all .
Proof.
First of all note that the implications v) iv), iv) iii) and iii) ii) are obvious. Moreover ii) i) follows from .
The difficult part is to prove i) v); for this we use Lemma 2 together with Kodaira’s Lemma (see for instance [17], Proposition 2.2.6). Namely, let be the divisor of Lemma 2; then (just take ). If is a big divisor on , then by Kodaira’s Lemma for every . Hence
[TABLE]
where the last inequality follows from Lemma 2 by taking as a pseudo-effective divisor . ∎
Remark 1**.**
Note that i) iii) is just Lemma 2, while i) ii) follows easily from ; this last fact was first noticed by Mori in [19], (11.3) on p. 318. Indeed, let and ; then the set is contained in .
The next Theorem proves the equivalence of the different definitions of Termination of Adjunction stated in the Introduction.
Theorem 3**.**
Let be a projective variety with at most canonical singularities.
The following statements, where and denote natural numbers, are equivalent:
(i) is uniruled (i.e. is not pseudo-effective).
(ii) For every big Cartier divisor there exists such that for .
(iii) For every big Cartier divisor we have for some .
(iv) For every very ample Cartier divisor we have for some .
(v) For some big Cartier divisor we have for every and some .
Proof.
(i) (ii) is implied by the properties of the cone described in Section 2; indeed, it follows by contradiction from .
(ii) (iii), (iii) (iv) and (iv) (v) are straightforward.
(v) (i) requires a resolution of the singularities . Assume by contradiction that is not uniruled. Therefore also is not uniruled and is pseudo-effective. If is any big Cartier divisor on , then is big and by [17], Corollary 2.2.7, we have with ample and effective for some . It follows that with very ample for some . Hence, by Lemma 1, for every we have . Lemma 2 says that this last term is positive, thus contradicting our assumption. ∎
Remark 2**.**
Note that Mori in [19], (11.4) on p. 318, suggests that in principle (i) could have been stronger then (iv): We say that is -uniruled if is not pseudo-effective. We note that -uniruledness is slightly stronger than saying that adjunction terminates, i.e. for each very ample divisor and some .
The following two corollaries show that the two formulations, respectively for some and for every, of (A) and (D) in the Introduction are equivalent.
Corollary 1**.**
Let be a projective variety with at most canonical singularities.
The following statements, where and denote natural numbers, are equivalent:
(i) For every big Cartier divisor there exists such that for .
(ii) For some big Cartier divisor there exists such that for .
Proof.
It is obvious that (i) implies (ii). Conversely, if (ii) holds then is not pseudoeffective, hence is uniruled. It follows from Theorem 3 that (i) holds. ∎
Corollary 2**.**
Let be a projective variety with at most canonical singularities.
The following statements, where and denote natural numbers, are equivalent:
(i) For some big Cartier divisor we have for every and some .
(ii) For every big Cartier divisor we have for every and some .
Proof.
It is obvious that (ii) implies (i). Conversely, if (i) holds then by Theorem 3 is uniruled, i.e. is not pseudoeffective. Assume by contradiction that there exist a big divisor and some such that for every . Then is pseudo-effective, a contradiction. ∎
As pointed out by the referee, since every divisor is a difference of very ample ones, (C) is actually equivalent to the following stronger condition.
- (C*)
For every Cartier divisor we have for some .
The following is a more general definition of Termination of Adjunction.
Definition 2**.**
(Condition (C’)) Let be a normal projective variety; let be an effective Cartier divisor on . We say that Adjunction Terminates in the classical sense for if there exists an integer such that
[TABLE]
for every integer .
We conjecture that such a definition is actually equivalent to the previous ones. The following partial result in this direction is straightforward.
Proposition 2**.**
Let be a projective variety with canonical singularities. Let be any effective divisor and assume that Adjunction Terminates in the classical sense for . Then has negative Kodaira dimension.
Proof.
Recall that the Kodaira dimension of a singular variety is defined to be the Kodaira dimension of any smooth model (see for instance [17], Example 2.1.5). Assume by contradiction that has non-negative Kodaira dimension, i.e. for some integer , where is any resolution of the singularities. Since has canonical singularities, from Lemma 1 it follows that . Hence for every integer , contradicting the assumption that for . ∎
Together with the standard conjecture that negative Kodaira dimension implies uniruledness (see for instance [19], (11.5) on p. 319, and [3], Conjecture 0.1), from Proposition 2 it would follow that Termination of Adjunction in the classical sense implies uniruledness. In dimension two such an implication holds unconditionally, as it was proved by Castelnuovo and Enriques in [7] (for a modern proof we refer to [20]).
We conclude this section with a characterization of uniruled varieties which may suggest a different way to consider (effective) termination of adjunction. It follows as a straightforward consequence of Lemma 2 and the main result in [3].
Proposition 3**.**
Let be a smooth projective variety of dimension and let be a very ample divisor on . If for some natural number , then is uniruled.
Proof.
Assume by contradiction that is not uniruled, so that is pseudo-effective by [3]. Lemma 2 with gives the sought-for contradiction. ∎
Theorem 3.1 in [9] gives a statement similar to the last proposition; there the variety is singular and is just nef and big. However and has to be multiplied by a higher number, for instance .
4. Quasi polarized pairs
A quasi polarized pair is a pair where is a projective variety with at most -factorial terminal singularities and is a nef and big Cartier divisor on . If is ample we call the pair a polarized pair.
In [1], Section 4, following T. Fujita’s ideas as revisited by A. Höring in [14] and using the MMP developed in [5], we described a MMP with scaling related to divisors of type , for a positive rational number.
In particular we introduced the [math]-reduction of a quasi polarized pair (see [1], Definition 4.4) as quasi polarized pair birational to obtained from via a Minimal Model Program with scaling:
which contracts or flips all extremal rays on such that .
At every step of the MMP given above, we have a quasi polarized variety with at most terminal -factorial singularities.
If is birational then , while if is a flip then and are isomorphic in codimension one.
Remark 3**.**
By using Lemma 1 and Hartogs theorem we deduce
[TABLE]
for
The following has been proved in [1], Theorem 5.1 and in [13], Proposition 1.3.
Theorem 4**.**
Let be a quasi polarized pair. Then is pseudo-effective for all unless the [math]-reduction is . Actually, is pseudo-effective unless is one of the following pairs:
- •
,
- •
, where is a quadric,
- •
, a generalized cone over ,
- •
* has the structure of a -bundle over a smooth curve and restricted to any fiber is .*
Moreover, except in the above cases, is nef.
The first-reduction of a quasi polarized pair (see [1], Definition 5.5) is a quasi polarized pair birational to obtained from a [math]-reduction via a morphism consisting of a series of divisorial contractions to smooth points, which are weighted blow-ups of weights with (see [2], Theorem 1.1).
Remark 4**.**
According to [1], Proposition 5.4, we have
[TABLE]
for any .
The following has been proved in [1], Theorem 5.7.
Theorem 5**.**
Let be a quasi polarized pair.
* is not pseudo-effective if and only if any first-reduction is either one of the pairs listed in the statement of Theorem 4 or one of the following pairs:*
- •
a del Pezzo variety, that is with ample,
- •
,
- •
,
- •
, where is a quadric,
- •
* has the structure of a quadric fibration over a smooth curve and restricted to any fiber is ,*
- •
* has the structure of a -bundle over a normal surface and restricted to any fiber is ,*
- •
, is fibered over a smooth curve with general fiber and restricted to it is .
If is pseudo-effective then on any first-reduction the divisor is nef.
The following definition was given by Höring (see ([14], Definition 1.2).
Definition 3**.**
A quasi polarized pair is a (generalized) scroll if is smooth and there is a fibration onto a projective manifold such that the general fiber admits a birational morphism and that . A quasi polarized pair is birationally a scroll if there is a birational morphism such that is a (generalized) scroll.
The next is Theorem 1.4 in [14].
Theorem 6**.**
Let be a quasi polarized pair. If is not birationally a scroll then is generically nef.
A key step in the proofs of Theorem 7 and of Theorem 8 is the following lemma due to Höring (see [14], p. 741, Step 2 in the proof of Theorem 1.2).
Lemma 3**.**
Let be a quasi polarized pair. Assume that is pseudo-effective and that is nef and big. Then
[TABLE]
We consider now a quasi polarized pair and we assume moreover that is smooth. We borrow from Y. Fukuma the following set-up for the computation of the Hilbert polynomial of .
Let
[TABLE]
The following statement can be easily checked by reverse induction on .
Lemma 4**.**
Fix an integer . If for every integer with , then for all integers with .
If one defines
[TABLE]
then it follows easily that
[TABLE]
Moreover, by taking and in Lemma 4, we obtain the following implication.
Corollary 3**.**
If for every integer with , then .
On the other hand, by Kawamata-Viehweg vanishing theorem and Serre duality, we have ; therefore from the Riemann-Roch theorem we obtain the following explicit computations (for further details, see [10], (2.2), and [11], Proposition 3.2).
Lemma 5**.**
Let be a polarized manifold of dimension and let denote the sectional genus of . Then we have
[TABLE]
5. Polarized Abundance
The aim of this section is to argue around the Conjectures stated in the introduction.
We start showing that Proposition 1 is a direct consequence of (the more general) Theorem D in [5].
Remark 5**.**
Let be a quasi-polarized variety and let be a positive rational number. Then there exists an effective -divisor on such that and is Kawamata log terminal. This is well-known to the specialists, a proof can be found in [1]. If , then and by [5], Theorem D, there exists an -divisor such that . That is, there exists such that .
We consider Conjecture 2; for we recover the following easy fact.
Proposition 4**.**
Let be a quasi polarized pair of dimension . We have for every integer with if and only if is not pseudo-effective. Moreover this is the case if and only if the [math]-reduction of the pair is .
Proof.
By Remark 3 we have for any . Hence if for every integer with then from Corollary 3 it follows that . Since we have and if and only if , the claim follows from [1], Theorem 5.1 (2). ∎
Next, for , the following is a slightly more explicit version of [14], Theorem 1.2; the proof is essentially the one of [14].
Theorem 7**.**
Let be a quasi polarized pair of dimension . We have for every integer with if and only if is not pseudo-effective.
That is, by Theorem 4, if and only if the [math]-reduction of the pair is one of the following:
(i) ,
(ii) , where is a quadric,
(iii) , a generalized cone over ,
(iv) has the structure of a -bundle over a smooth curve and restricted to any fiber is .
Proof.
Let be the [math]-reduction of the pair and let be its desingularization (namely, and .
By Remark 3 and Lemma 1 we have
[TABLE]
for any .
The if part is obvious. In order to prove the only if part, assume that for every integer with . Corollary 3 implies that
[TABLE]
Assume by contradiction that is not one of the pairs in (i), (ii), (iii), (iv); then, by Theorem 4, is nef. The required contradiction is provided by [14], Theorem 1.2. ∎
The next step should work as follows.
Conjecture 3**.**
Let be a quasi polarized manifold of dimension . We have for every integer with if and only if is not pseudo-effective, that is if and only if the first-reduction is one of the pairs listed in Theorems 4 and 5.
Once again, the if part is obvious. Conversely, from Corollary 3 it follows that , but the proof of the only if part seems to be elusive.
From now on, we focus on the case ; here formula (1) reads simply as:
[TABLE]
where
[TABLE]
We prove the following generalization of [12], Theorem 3.1.
Theorem 8**.**
Let be a polarized manifold of dimension and let be an integer with . If is pseudo-effective, then . In particular,
- •
* for *
- •
* if and only if is *
- •
* if and only if is either , where is a quadric, or has the structure of a -bundle over a smooth curve and restricted to any fiber is .*
Proof.
Since is ample is a 0-reduction, in particular by Theorem 4 we can assume that is nef for . We can also assume that is nef. Indeed, if not then is one of the exceptions listed in the statement of Theorem 4. If is or , where is a quadric hypersurface, then Theorem 8 is obvious. The case of a generalized cone over does not occur since is smooth, while the case of a -bundle over a smooth curve will be considered in Proposition 5.
Now, assume that is generically nef. By using the formulas in Lemma 5 and Miyaoka inequality as stated in [14], Corollary 2.11, with , we compute:
[TABLE]
Hence from (3) and the nefness of it follows that
[TABLE]
for every .
Finally, assume that is not generically nef. By Theorem 6 and Lemma 1 we may assume that is a (generalized) scroll and the claim is a consequence of the following proposition. ∎
Proposition 5**.**
Let be a generalized scroll of dimension and let be an integer such that . If is nef, then .
Proof.
Let be the scroll fibration and let be the generic fiber with a birational morphism as in Definition 3.
If the claim is obvious; therefore we can assume that and that (since we have and if and only if ). We also have that and .
If , then , hence for . Thus we have and from (3) it follows that for we have
[TABLE]
If , then , hence for . In particular, we have and .
For , i.e. if we assume is nef, by Theorem 1.2 in [14] we must have since for .
For we deduce from (3) that
[TABLE]
If , then , hence . In particular, we have .
If , then and we conclude exactly as in the previous case .
If , then is pseudo-effective and is pseudo-effective and big.
Passing to the [math]-reduction we may assume that is nef and big. Therefore Lemma 3 applies and by Lemma 5 we get .
Hence from (3) it follows that for we have
[TABLE]
∎
The statement of Theorem 8 should hold also for , but we have only the following partial result.
Proposition 6**.**
Let be a polarized manifold of dimension . If is pseudo-effective, then unless is not generically nef.
Proof.
By Theorem 5 and Remark 4 we may assume that is nef.
Assume that is generically nef. By using the formula for in Lemma 5 and Miyaoka inequality, as stated in [14], Corollary 2.11, with , we compute:
[TABLE]
Hence from (3) it follows that
[TABLE]
∎
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