Global representation of Segre numbers by Monge-Amp\`ere products
Mats Andersson, Dennis Eriksson, H{\aa}kan Samuelsson Kalm, Elizabeth, Wulcan, Alain Yger

TL;DR
This paper introduces a new framework using generalized cycles and a quotient group to extend intersection theory, linking Segre numbers with Monge-Ampère products on analytic spaces.
Contribution
It develops a novel group $ ext{B}(X)$ extending classical intersection theory, defining $ ext{B}$-Segre classes and Gysin morphisms, and relating Segre numbers to Monge-Ampère products.
Findings
Defines a $ ext{B}$-Segre class with support in $V$
Establishes a King formula for $ ext{B}$-Segre classes
Interprets classes as Monge-Ampère-type products
Abstract
On a reduced analytic space we introduce the concept of a generalized cycle, which extends the notion of a formal sum of analytic subspaces to include also a form part. We then consider a suitable equivalence relation and corresponding quotient that we think of as an analogue of the Chow group and a refinement of de Rham cohomology. This group allows us to study both global and local intersection theoretic properties. We provide many -analogues of classical intersection theoretic constructions: For an analytic subspace we define a -Segre class, which is an element of with support in . It satisfies a global King formula and, in particular, its multiplicities at each point coincide with the Segre numbers of . When is cut out by a section of a vector bundle we interpret this class as a…
Peer Reviews
No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.
Videos
No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.
Global representation of Segre numbers by Monge-Ampère products
Mats Andersson & Dennis Eriksson & Håkan Samuelsson Kalm &
Elizabeth Wulcan & Alain Yger
Department of Mathematics
Chalmers University of Technology and the University of Gothenburg
S-412 96 GÖTEBORG
SWEDEN
Institut de Mathématique
Universit Bordeaux 1
33405, Talence
France
[email protected], [email protected], [email protected], [email protected], [email protected]
(Date: March 11, 2024)
Abstract.
On a reduced analytic space we introduce the concept of a generalized cycle, which extends the notion of a formal sum of analytic subspaces to include also a form part. We then consider a suitable equivalence relation and corresponding quotient that we think of as an analogue of the Chow group and a refinement of de Rham cohomology. This group allows us to study both global and local intersection theoretic properties.
We provide many -analogues of classical intersection theoretic constructions: For an analytic subspace we define a -Segre class, which is an element of with support in . It satisfies a global King formula and, in particular, its multiplicities at each point coincide with the Segre numbers of . When is cut out by a section of a vector bundle we interpret this class as a Monge-Ampère-type product. For regular embeddings we construct a -analogue of the Gysin morphism.
The first, third and fourth author were partially supported by the Swedish Research Council
1. Introduction
Throughout this paper is a reduced analytic space of pure dimension and is a coherent ideal sheaf with zero set with codimension . Tworzewski, [21], and Gaffney and Gassler, [13], independently introduced, at each point , numbers that generalize the Hilbert-Samuel multiplicity at . These definitions, although slightly different, are both of a geometric nature. There is also a purely algebraic definition, see [1] and [2] by Achilles-Manaresi and Achilles-Rams, respectively. In [6] were introduced semi-global currents whose Lelong numbers at are precisely the , thus providing an analytic definition. Following [13] we call these numbers Segre numbers and, indeed, we will see in Theorem 1.1 below that they are closely related to Segre classes.
The main goal in this paper is to define concrete global analytic-geometric objects that represent the Segre numbers at each point. A secondary goal is to provide a framework, based on currents, to connect local intersection theory with global constructions.
Intersection theory deals with the -module of analytic cycles and its quotient module , the Chow group. In general there are no cycles or elements in that can represent the Segre numbers at each point. To find global representations we introduce an extension of that we call the -module of generalized cycles. Formally the elements in are a certain kind of closed currents but we prefer to think of them as geometric objects. In particular, ordinary cycles are certainly geometric objects but formally represented by their associated Lelong currents in . Many of the well-known geometric properties of extend to : We have the natural grading by dimension , where are the submodules of generalized cycles of pure dimension . At each point a generalized cycle has a well-defined multiplicity that is an integer. There is a notion of Zariski support of , and any has a unique decomposition in irreducible components. Moreover, is closed under multiplication by components of Chern and Segre forms of Hermitian vector bundles111All vector bundles in this paper are holomorphic.. To get independence of various choices we introduce a certain quotient module of ; preserves the above-mentioned geometric properties of . For instance, is a submodule of , we have a grading by dimension and well-defined multiplicities, etc. Moreover, admits a multiplication by components of Chern and Segre classes. A proper mapping222Mappings between spaces are always assumed to be holomorphic. induces a mapping , which in turn induces a mapping . Assume that is a subvariety. The image of the injective mapping is precisely the elements in that have Zariski support in . Conceptually we identify with its image. In the same way is identified with the elements in that have Zariski support on .
We define the -Segre class in in analogy with the Segre class in , cf. Remark 5.1 below: First assume that is irreducible. If vanishes identically on , then on . Otherwise, let be any modification of such that the ideal sheaf is principal333In this paper we let denote the ideal generated by the pullback of generators of ., let be the first Chern class of the line bundle defining the exceptional divisor in , and let be its Lelong current. For instance, can be the blow-up of along . Then
[TABLE]
Since is proper, (1.1) defines an element in . We will see that it is independent of the choice of modification. If consists of the irreducible components , then we let which is a locally finite sum on .
We are now ready to formulate our first main result, which is a generalized King formula, [16, 17], for these objects and that in particular provides the desired global representation of the Segre numbers of . Let be the component of in .
Theorem 1.1** (Global generalized King formula).**
Let be a coherent ideal sheaf over a reduced analytic space of pure dimension and let be the codimension of the zero set of . The class only depends on the integral closure class of . We have unique decompositions
[TABLE]
in , where are the (Fulton-MacPherson) distinguished varieties of of codimension , are positive integers, and has the following property: The multiplicities are nonnegative integers, and the set of where has codimension at least . Moreover, for , , and
[TABLE]
Our next objective is to present specific representatives for the -Segre class . Assume that we have a holomorphic section of a Hermitian vector bundle such that generates . If is projective such a always exists. One can give a meaning to the Monge-Ampère products for all , as follows. To begin with it is defined as when . The higher powers are defined recursively in [3] as
[TABLE]
For this definition coincides with Demailly’s extension of the classical Bedford-Taylor definition. Proposition 4.4 in [3] states that
[TABLE]
which gives further motivation for the notation. It was recently proved in [7] that one can also take the limit when of , where ; several other, but not all (sic!), sequences of plurisubharmonic functions decreasing to also work.
Theorem 1.2**.**
Let be a holomorphic section of a Hermitian vector bundle and let be the ideal sheaf generated by . The current
[TABLE]
is a generalized cycle that represents the -class .
Since is a subgroup of we conclude the following global version of [6, Theorem 1.1] from Theorems 1.1 and 1.2.
Corollary 1.3**.**
We have unique decompositions
[TABLE]
where are elements in . In particular, is equal to the Segre number at each point .
Given a generalized cycle with Zariski support we define in Section 5 for each a generalized cycle with Zariski support on and dimension . Its class in only depends on and the class of in . We let . We think of as (the push-forward to of) a representative of the Segre class of on , cf. Remark 5.4.
Notice that a coherent ideal sheaf can be identified with the, possibly non-reduced, embedded space with underlying reduced space and structure sheaf . If is a reduced analytic subspace, then we denote by the class in , called the Segre class, that is denoted by in [12], cf. Remark 5.1 below.
In intersection theory the notion of regular embedding plays a central role. With the identification above “regular” means that the associated sheaf is locally a complete intersection444We will assume that a regular embedding has codimension .. Since our second goal concerns intersection theory we will pay special attention to such sheaves and describe in more detail. In this case the normal cone is a vector bundle over and we let be its associated total Segre class. Here lower index denotes the component of bidegree . Let be (the Lelong current of) the fundamental cycle of , cf. [12, Ch. 1.5].
Proposition 1.4**.**
If defines a regular embedding , then
[TABLE]
in .
As in the case with general ideal sheaves we are interested in specific representatives, so let us assume that is defined by a section of a Hermitian vector bundle and let be the pull-back of to . There is a canonical holomorphic embedding of in , see Section 7. Let us equip with the induced Hermitian metric and let be the associated total Segre form which indeed is smooth on , see Section 2.
Proposition 1.5**.**
If is a section of the Hermitian vector bundle defining , then we have the equality of generalized cycles
[TABLE]
We have a mapping
[TABLE]
where lower index denotes dimension, and is the total Chern class of . If we choose a section of as above we get a representing mapping
[TABLE]
where is the associated total Chern form. The mapping (1.8) is a -analogue of the Gysin mapping, [12, Proposition 6.1], see Section 2 for the notation,
[TABLE]
In Section 10 we introduce a quotient space of closed -currents with support on , coinciding with the usual de Rham cohomology in case is smooth. There are natural mappings and .
Proposition 1.6**.**
For each , the images of and in coincide.
Proposition 1.7**.**
Assume that defines a regular embedding of codimension and let be the (reduced) zero set of . If is a cycle on , then the images in of the Gysin and the -Gysin mappings, (1.10) and (1.8), respectively, of coincide.
In Section 9 we consider a general ideal sheaf that is generated by a tuple of global sections of a line bundle . In this situation Stückrad-Vogel, [20], introduced an algorithm to produce concrete cycles, Stückrad-Vogel cycles, that determine a Chow class , which is related to via van Gastel’s formulas, [14]. Given a Hermitian metric on we define a global generalized cycle by taking a certain mean value of Stückrad-Vogel cycles. If we consider as a section of we have an analogue of van Gastel’s formulas relating and as elements in .
2. Preliminaries
Locally there is an embedding into an open subset . The sheaf of smooth -forms on is by definition the quotient sheaf , where is the sheaf of forms on such that vanish on . Since all embeddings are essentially equivalent, this definition is independent of the choice of embedding. The sheaf of currents of bidegree on is by definition the dual of . Given the embedding , currents in can be identified with currents on of bidegree that vanish on . We say that has order zero if has order zero; recall that this means that has measure coefficients. A current in is said to have (complex) dimension . If is proper, then is well-defined on smooth forms and is well-defined on currents and preserves dimension, see [5]. If is a current on and is a smooth form on , then
[TABLE]
Moreover, if has order zero then so has and
[TABLE]
where is the characteristic function of the analytic subset . If is a closed positive current then so is . The Lelong number of at is defined as the Lelong number of at where is a local embedding in a smooth manifold, see, e.g., [6, Section 2.2]. If is a subvariety of of pure dimension , then there is an associated closed positive current of dimension , the Lelong current,
[TABLE]
Recall that to any Hermitian line bundle there is an associated (total) Chern form . If is the same line bundle but with another Hermitian metric, then there is smooth function on such that
[TABLE]
Assume that is a Hermitian vector bundle of rank , and let be the projectivization of , by which we mean the projective bundle of lines through the origin in . Let be the tautological line bundle equipped with the induced Hermitian metric, and let be its Chern form. The (total) Segre form of is defined as
[TABLE]
Thus555It is not obvious that ; however it follows from the corresponding statement for the Chow class, see [12], or from (2.10) below. where
[TABLE]
is the component of bidegree . It is indeed is a smooth form on : if is smooth this follows since is a submersion and in general it follows by embedding locally in a smooth space and extending to a Hermitian bundle over this space.
Let be another analytic space and a proper mapping. Then the tautological line bundle associated with is the pullback of under the induced map and so . It follows that
[TABLE]
If is a line bundle, then , , and hence
[TABLE]
For a general Hermitian vector bundle we take (2.7) as the definition of its (total) Chern form. Thus where the component of bidegree is a polynomial in the . From (2.6) we get
[TABLE]
Let and be the same bundle but with two different Hermitian metrics and let and be the associated Hermitian line bundles over . In view of (2.3), (2.5) and (2.7) (and that is a submersion) we have, for , that
[TABLE]
for suitable smooth -forms on . We let and denote the cohomology classes, which we for simplicity refer to as the Segre and Chern classes, although we only consider representatives obtained from a Hermitian metric as above.
The Hermitian metric on determines a Chern connection and thus a curvature tensor . It is proved in [19, Proposition 6] that the definition used here and the differential-geometric definition of Chern form coincide, that is,
[TABLE]
An analytic -cycle on is a formal locally666Algebraic geometry only deals with finite linear combinations, but we use the more “analytic” definition. finite linear combination , where and are irreducible analytic sets of dimension . We let
[TABLE]
be its associated Lelong current. Note that if has dimension (the dimension of ), then . We will denote the -module of analytic -cycles on by . The support of the cycle is defined as the union of the for which and it coincides with the support of the current . Recall that
[TABLE]
where denotes the Lelong number of the closed positive current at , and is the multiplicity of at (defined as in [10, Ch. 2.11.1]), see, e.g., [10, 3.15, Proposition 2].
Let be a proper mapping. For each irreducible subvariety , let denote the degree of ; if it is defined as zero. The push-forward of is the cycle
[TABLE]
in , see, e.g., [12, Section 1.4]. Since it follows that
[TABLE]
In particular, if is an embedding in another reduced space , then can be regarded as a cycle on and . For the rest of this paper we often skip the notation and identify a cycle with its Lelong current.
Let so that777We write rather than for the point mass at [math]. in . The Poincaré-Lelong formula, usually stated on a smooth manifold, has an extension to our nonsmooth case (see also Section 8). We say that a meromorphic section of a line bundle is non-trivial if it is generically holomorphic and non-vanishing.
Proposition 2.1** (The Poincaré-Lelong formula).**
Let be a non-trivial meromorphic section of a Hermitian line bundle . Then has order zero on ,
[TABLE]
where is holomorphic, and there is a cycle such that
[TABLE]
In case is smooth, is the usual divisor defined by .
Proof.
Let be a smooth modification. Since is non-trivial on , is locally integrable and hence a current of order [math]. Since is a biholomorphism generically, . Thus has order zero. For the same reason the limit (2.14) holds where is holomorphic, and . By the Poincaré-Lelong formula on a smooth manifold, Applying we get (2.15) with . It follows from (2.13) that is a cycle, and it follows from (2.15) that it is independent of the choice of modification. ∎
Let be a subvariety. If is non-trivial, then we say that intersects properly, and we have the proper intersection , cf. [10, Ch 2, 12.3] and Section 8 below. Letting and noting that , we get from (2.15) the formula
[TABLE]
Recall that is rationally equivalent to [math], , if there are subvarieties of dimension and meromorphic non-trivial functions on , such that, writing rather than for simplicity,
[TABLE]
cf. (2.16), where the sums are locally finite. We denote the Chow group of cycles modulo rational equivalence by , cf. [12, Chapter 1.3]. Note that if is irreducible and compact and is a Cartier divisor, then precisely if for some meromorphic function on , i.e., the line bundle defined by is trivial. Thus for Cartier divisors (when is compact), rational equivalence precisely means linear equivalence. If is a proper mapping and in , then and thus (2.12) induces a mapping, cf. [12, Theorem 1.4],
[TABLE]
Each component of a Chern class on induces a mapping , , see, [12, Section 3.2]. If is a nontrivial meromorphic section on of a line bundle , then is the class in defined by .
3. Generalized cycles
The generalized cycles is the smallest class of currents that is closed under proper direct images and contains sums of wedge products of Lelong currents and components of Chern forms. More formally, we say that a current in is a generalized cycle if it is a locally finite linear combination over of currents of the form where is a proper map, is smooth, and is a product of components of Chern forms for various Hermitian vector bundles over , i.e.,
[TABLE]
We will keep this notation throughout this section. Since we can restrict to each connected component of we can assume that is connected.
Note that a generalized cycle is a real current of order zero that is closed (in particular it is normal) with components of bidegree . We let denote the -module of such currents of (complex) dimension , i.e., of bidegree , and let . If and is a component of a Chern form on , then . In fact, if , where , then , cf. (2.1).
Remark 3.1*.*
In view of (2.7) each form (3.1) is a finite sum of similar forms but with replaced by . Morover, we can assume that each factor in (3.1) is the first Chern form of a Hermitian line bundle. To see this it is enough to verify that any , where are Hermitian vector bundles of rank , is of this form. Let be the fiber product let be the pullback to of the tautological bundle , and let be the first Chern form on induced by the metric on . Then, cf. (2.5),
[TABLE]
∎
Lemma 3.2**.**
Let be a subvariety and .
(i) Then .
(ii) If
[TABLE]
where are proper, are smooth and connected, and are as in (3.1), then
[TABLE]
Proof.
Since the right hand side of (3.3) is in by definition, follows from . Assume now that (3.2) holds. By (2.2),
[TABLE]
Assume that . Then has positive codimension in since is connected. Since is smooth it follows that , and hence the corresponding term in (3.4), vanishes. Thus (3.3) holds. ∎
If is a subvariety of , then , where , which is the [math]th Chern form of any vector bundle over . Thus we have an embedding
[TABLE]
and we think of as a subset of . If is proper, then we have a natural mapping
[TABLE]
Indeed, if , then and is proper. In particular, if is a subvariety of , then we have an injective mapping
[TABLE]
Given there is a smallest variety , that we call the Zariski support of , such that vanishes outside . In fact, is the Zariski closure of the support of as a current.
Example 3.3*.*
Assume that is irreducible and let be the trivial line bundle. Then any smooth function on determines a metric on with the corresponding first Chern form . Since can vanish on an open subset of without vanishing identically, it is a non-zero generalized cycle with support strictly smaller than but with . ∎
Proposition 3.4** (Dimension principle).**
Assume that has Zariski support . If , then . If , then .
Proof.
Since is closed, of dimension and order zero it follows from [11, Corollary III.2.14] that it is a sum of various currents where is irreducible of dimension and is a number. By Proposition 6.1 below the Lelong number of a generalized cycle is an integer at each point, and it follows that the are integers. If it follows from [11, Thm III.2.10] that . ∎
Example 3.5*.*
If , then , where are the irreducible components of and are integers. ∎
Proposition 3.6**.**
The image of (3.6) is precisely those such that .
Thus we can, and will indeed do, identify generalized cycles on with generalized cycles in with Zariski support on .
Proof.
Assume that is on the form (3.2) and has support on . Since it follows from Lemma 3.2 that is equal to the right hand side of (3.3). For each of these we have a factorization where is proper. It follows that
[TABLE]
is in and . ∎
Definition 3.7**.**
We say that is irreducible in if is irreducible and for any proper subvariety .
Thus irreducibility is connected to an irreducible subvariety of . If is irreducible with Zariski support it has a unique decomposition
[TABLE]
where is the component of dimension and . It follows from Proposition 3.4 that is for some integer .
Lemma 3.8**.**
Assume that is of the form , where , is connected, and . Then is irreducible and or .
Proof.
Since is irreducible, so is . Clearly, . Assume that is a proper subvariety of . Then has positive codimension in since is connected. Thus
[TABLE]
since is smooth. If is a proper subvariety of , therefore . If not, it follows from (3.8) that is irreducible. ∎
Notice that if are irreducible with the Zariski support , then either vanishes or is again irreducible with Zariski support .
Proposition 3.9**.**
Each has a unique decomposition
[TABLE]
where are irreducible with different Zariski supports.
Proof.
We first prove the uniqueness. Let . Assume that (3.9) holds with . If there are non-vanishing then we can choose such that and has minimal dimension among the for which . For each then has positive codimension in and hence since is irreducible. Thus which is a contradiction. We conclude that for all .
To prove the existence, we may assume that is of the form (3.2), where and are connected. For each subvariety that appears as the Zariski support of one of the summands in (3.2), let , where the sum is over all such that . Then, by Lemma 3.8, is irreducible with Zariski support or . We now get the decomposition (3.9). ∎
Remark 3.10*.*
It follows from the proof that an irreducible with is a finite sum of terms like where is proper, and is irreducible. Since is proper it is a submersion outside an analytic set , where has positive codimension, so that is closed and smooth on . ∎
Given , for each each of the irreducible components in (3.9) consider the decomposition as in (3.7). We have the unique decomposition
[TABLE]
where
[TABLE]
[TABLE]
are called the fixed and moving part of , respectively. Notice that is a cycle in view of the dimension principle. We say that each term in (3.11) is a fixed component and each term in (3.12) a moving component of . The reason for this terminology will be clarified in Section 9 but already here we can present an illustrating example of a moving generalized cycle:
Example 3.11*.*
Assume that and let \theta=dd^{c}\log\big{(}|z_{1}|^{2}+\cdots+|z_{n}|^{2}\big{)}. Then , , is a generalized cycle in of dimension and with Zariski support . To see this, let be the blow-up at and notice that , where is minus the first Chern form of the line bundle, with respect to the “standard” metric, associated with the exceptional divisor . By repeated use of (2.1) we have that outside the origin. Since both sides are positive closed currents it follows by the dimension principle that the equality must hold across . Thus is in and by Lemma 3.8 it is irreducible with Zariski support . Thus it has one single moving irreducible component. One can verify that is indeed a mean value of all -planes through , cf. [6, Eq. (6.2)] with . More conceptually, one can thus think of as such a -plane moving around . ∎
4. Equivalence classes of generalized cycles
If is a short exact sequence of Hermitian vector bundles over we say that
[TABLE]
is a -form on . Let be the component of bidegree of a -form. If then so let us assume that . In view of (2.10) one can just as well use the differential-geometric definition of Chern form. From [9, Proposition 4.2] we get a smooth form on of bidegree such that . In fact in [9] only the case when is smooth is discussed. However, the construction of is completely explicit and local, and locally we can extend our short exact sequence to a neighborhood in a smooth ambient space and conclude that is smooth on .
Notice for future reference that if , then is a component of a -form if is. We say that is equivalent to [math] in , , if is a locally finite sum of currents of the form
[TABLE]
where is proper, is smooth and connected, is a component of a -form on , and is a product of components of Chern forms. If , where , we say that if for each . Let denote the -module of generalized cycles on modulo this equivalence. A class has pure dimension , , if has a representative in . Thus .
If is a Hermitian vector bundle, then for each we have the mapping
[TABLE]
Proposition 4.1**.**
The mapping (4.3) induces a mapping
[TABLE]
with the following properties: If is another vector bundle, then
[TABLE]
If is proper, then
[TABLE]
for . If is a short exact sequence on , then
[TABLE]
Proof.
First assume that and . With the notation above we may assume that , where and is a -form on . It follows that and hence by definition . Thus is well-defined on . We must verify that it does not depend on the particular choice of metric on . To this end, assume that is a short exact sequence of Hermitian vector bundles on and let be the component of bidegree of the associated -form. Assume that and is an element in . Then is a short exact sequence on and is the component of bidegree of the associated -form on . It follows that
[TABLE]
If so that and are isomorphic but with possibly different metrics, then so we can conclude that in . Thus (4.4) is well-defined. Now (4.5) and (4.6) are obvious and (4.7) follows from (4.8). ∎
Remark 4.2*.*
If is a component of (4.1), but where all are replaced by , then still . In fact, if lower index denotes component of bidegree , then
[TABLE]
so the claim follows from Remark 3.1. It is clear that Proposition 4.1 holds, with the same proof, if is replaced by . ∎
Notice that if is a proper mapping and , then so we have a natural mapping
Lemma 4.3**.**
If is a subvariety, then is injective.
Proof.
Assume that and in . Then , where , , are as in (4.2). In view of Lemma 3.2 we may assume that for each . For each there is a map such that . Let . Then
[TABLE]
so that Thus on . ∎
Proposition 4.4**.**
The mapping is injective.
Thus we can consider as a subgroup of .
Proof.
Assume that and in . If is the natural injection and
[TABLE]
then . By Lemma 4.3, in . Since has full dimension in , and thus bidegree , it must vanish in view of (4.2). ∎
Proposition 4.5**.**
For each open subset of there is a natural restriction mapping that induces a mapping .
Proof.
Assume that and . Then the restriction of the current to is equal to , where and are the restrictions to of and , respectively. Notice that is proper and that is a product of components of Chern forms since is. Since also the restriction to of a -form is a -form, it follows that is well-defined on . ∎
Lemma 4.6**.**
Assume that , , and that (3.9) is its decomposition in irreducible components. Then for each .
Proof.
Using the notation from above, we can assume that is of the form
[TABLE]
where are proper and are connected. It follows from the proof of Proposition 3.9 that
[TABLE]
and thus by definition. ∎
Let be a representative of and let be its decomposition in irreducible components. We claim that for each the corresponding class in is independent of the choice of . In fact, assume that is another representative with decomposition . The sums are (locally) finite and each term corresponds to a unique irreducible set, so by adding terms [math] if necessary we have that
[TABLE]
and hence by the lemma for each . Now the claim follows, and taking into account only the non-vanishing classes we get the unique decomposition
[TABLE]
where are well-defined elements in with well-defined Zariski supports .
In case this sum consists of just one non-zero term we thus have a well-defined irreducible subvariety, and so the following definition is meaningful:
Definition 4.7**.**
We say that is irreducible if it has a representative that is irreducible. The Zariski support of is then equal to .
We have the following simple consequences of the discussion above:
Proposition 4.8**.**
(i) If is irreducible and , then we have a unique decomposition , where .
(ii) Any has a unique decomposition , where are irreducible.
Definition 4.9**.**
In view of (ii) we define the Zariski support as the union of the .
From Proposition 3.6 and Lemma 4.3 we get
Proposition 4.10**.**
If , then the image of is precisely the in with Zariski support on .
That is, we can identify the elements in with elements in with Zariski support contained in .
Precisely as for generalized cycles we define and by (3.11) and (3.12), respectively, and get the unique decomposion, cf. (3.10),
[TABLE]
in in a fixed and a moving part, and in view of Proposition 4.4 the fixed part is indeed a cycle in .
Remark 4.11*.*
Let be compact, be a line bundle, and . The mass
[TABLE]
of is an integer that only depends on the class of in and of . In fact, we may assume that , where is a product of first Chern forms of line bundles over and is proper. Then and thus
[TABLE]
which is an integer since it is the integral of a product of first Chern forms of line bundles and thus an intersection number. By (4.2) and Stokes’ theorem it only depends on the class of and of . When and we think of as points moving around on , cf. Section 9. ∎
5. The -Segre class
Since any modification such that is principal factorizes over the blow-up of along , it follows by Proposition 4.1 and a standard argument that , as defined in the introduction, cf. (1.1), is a well-defined element in . Recall the restriction map of Proposition 4.5. We claim that
[TABLE]
In fact, by linearity it is enough to check the case when is irreducible. If is the [math]-ideal then (5.1) is trivial. If not, let be a modification such that is principal. Then the restriction of is a modification where the pullback of is principal. Let and be the restrictions of and , respectively, to . Then
[TABLE]
Remark 5.1*.*
In intersection theory, given a proper subscheme there is a well-defined Chow class in , , called the Segre class. As in the introduction let us think of as the nonreduced subspace of with structure sheaf , where is a coherent ideal sheaf over . Based on Chapter 4 in [12] (the summary on page 70 and Corollary 4.2.2) it follows that can be defined as in (1.1) if we interpret as the element in the Chow group and as the push-forward of Chow classes, so that is an element in for . Since is proper, has positive codimension and therefore vanishes. ∎
We shall now discuss concrete representatives of the -Segre class. In particular, these representations allow us to define the -Segre class not only on an analytic space but on a generalized cycle . To this end we first consider Monge-Ampère products on , cf. [6, Sections 5, 6]. Recall that is the equivalence relation defining .
Theorem 5.2**.**
Assume that is a holomorphic section of a Hermitian bundle and let be the associated coherent sheaf with zero set .
(i) For each the limits
[TABLE]
exist and are generalized cycles with Zariski support on , and the generalized cycles
[TABLE]
have Zariski support on .
(ii) If , then .
(iii) If is a holomorphic section of another vector bundle such that 888Between norms has the standard meaning that there are constants such that . , then .
(iv) If is proper and , then
[TABLE]
The hypothesis in , which clearly holds if both and define , precisely means that the sheaves defined by and have the same integral closure, see, e.g., [6]. We will refer to as the projection formula. We let
[TABLE]
Proof of Theorem 5.2.
We can assume that , where is proper and is smooth and connected. We first consider the case when vanishes identically on , or equivalently, . For the limit in (5.2) trivially exists and is [math], and so is (5.3). If , then (5.2) is and as well. Thus (i) holds, and (ii)-(iv) are easily verified.
We can thus assume that does not vanish identically on and hence it defines a subvariety of positive codimension. Then since is irreducible, cf. Lemma 3.8. Thus we may assume that and (possibly after a modification of ) that is principal on . This precisely means that , where is a section of the line bundle that defines the exceptional divisor and is a non-vanishing section of . Thus defines an isomorphism between and a line subbundle of , and so inherits a metric from such that . If we let
[TABLE]
we have by the Poincaré-Lelong formula that
[TABLE]
By (2.1),
[TABLE]
By [3, (4.6)],
[TABLE]
where the middle expression is recursively defined by (1.4). The equality is a simple consequence. We conclude that the limit (5.2) exists for each and that
[TABLE]
This is a generalized cycles with Zariski support contained in , cf. (3.5). Since we have by (2.2) that
[TABLE]
Clearly it is in and has Zariski support contained in . Thus (i) is proved.
If for some component of a -form, then
[TABLE]
and hence . Thus (ii) holds.
If is a section as in (iii), then we may assume that also . Since it follows that and define the same divisor and hence are sections of the same line bundle. Hence their associated first Chern forms differ by a -form on . In view of (5.9) and (5.4), and thus (iii) follows. Finally, we get (iv) from (5.6), with instead of , and (2.1). ∎
With the notation in the proof we have, cf. (5.9),
[TABLE]
Moreover, cf. (1.6), by definition
[TABLE]
Proof of Theorem 1.2.
We can assume that is irreducible. If vanishes identically, then and for , so coincides with in this case. Thus we may assume that has positive codimension, and that is a modification such that is principal. It then follows from (1.1), (5.4), and (5.9) with that is a representative for . Thus Theorem 1.2 follows. ∎
Example 5.3*.*
If the proper map is surjective and generically -to-, then and so ∎
Remark 5.4*.*
Assume that is a subvariety of pure codimension . By the projection formula, Theorem 5.2 ,
[TABLE]
Notice that the Segre class on for is represented by the generalized cycle , cf. Theorem 1.2. With the identification given by Proposition 4.10 of elements in with elements in with Zariski support on , thus the right hand side of (5.12) is a representative of . Warning: The left hand side of (5.12) is not a product but an operator acting on . In general one cannot recover from , or from even if . For instance, if defines a regular embedding and , then whereas , see Proposition 1.4. ∎
In view of (5.12) the following definition is natural.
Definition 5.5**.**
Assume that is defined by the section of the Hermitian vector bundle . Given and a representative , we define the -Segre class as the class in defined by . We let .
Proposition 5.6**.**
If is a component of a Chern or Segre form, then
[TABLE]
and
[TABLE]
Proof.
Assume that and is connected. Let . Now since both sides vanish if is a proper subvariety of and are equal to otherwise. Thus (5.13) follows from (2.1) and (2.2), and (5.14) follows from (5.2), (5.3) and (5.13). ∎
Sometimes it is convenient with a limit procedure that directly gives without first computing .
Proposition 5.7**.**
Let be a holomorphic section of a Hermitian bundle and let
[TABLE]
If , then for ,
[TABLE]
Using a principalization, the proposition is reduced to the following lemma that can be verified along the same lines as [3, Proposition 4.4], and we omit the details.
Lemma 5.8**.**
Let be a section of a Hermitian line bundle with and let . Then
[TABLE]
Remark 5.9*.*
One can define as the value at , via analytic continuation from , of the expression
[TABLE]
see [3, Proposition 4.1] and [6, Section 4]. ∎
Remark 5.10* (Comparison to Green forms).*
Recall that a -current is a Green current of a closed subvariety of codimension of a complex manifold if , where is a smooth form. If is smooth outside it is called a Green form. The calculus of Green forms, based on the -product, is an important tool in the study of height in arithmetic intersection theory, see, e.g., [8, 15]. In particular, Fulton’s intersection theory is recovered in the proper intersection case.
In the case , if is a section of a Hermitian line bundle that defines , then is a Green form in virtue of the Poincaré-Lelong formula (2.15). In fact, these are the only Green forms in the case . The existence of Green forms of so-called logarithmic type for is a more delicate matter, see [8]. That is of logarithmic type means that under a proper mapping such that locally in there are coordinates such that , where are smooth and closed. This can be compared to our definition of generalized cycles.
If is defined by the section of the Hermitian vector bundle , and , then, cf. (1.4) and Corollary 1.3,
[TABLE]
so that is kind of a Green form. Unless , however, is not smooth but only the push-forward under a modification of a smooth form, cf. (5.8). ∎
6. Multiplicities of a generalized cycle
In view of (2.11) it is natural to define the multiplicity of at as the Lelong number at . However, is not necessarily positive so it is not immediately clear that the Lelong number exists. Here is our formal definition: Let be a section of a Hermitian vector bundle in an open neighborhood of such that generates the maximal ideal at . Since has support at it follows from the dimension principle, Proposition 3.4, that . Moreover, in view of the proof of this proposition, for some real number . By Theorem 5.2 (iii), the number is independent of the choice of . Part (ii) of the same theorem implies that only depends on the class of in . By an argument as in the beginning of Section 5 we see that it is also independent of the choice of neighborhood of . Altogether the definition
[TABLE]
is meaningful. If is small enough we can assume that is trivial, with a trivial metric, and then coincides with the Lelong number if is positive, see, e.g., [6, Lemma 2.1] and Remark 5.9.
Proposition 6.1**.**
The multiplicity of at is an integer and it only depends on its class in .
Proof.
Let , where is proper and is connected. First assume that . Thus . Since is proper, is compact, so by (6.1),
[TABLE]
which is an intersection number, cf. Remark 4.11, and hence an integer. Next we assume that and that has positive dimension. As in the proof of Theorem 5.2, with and , cf. (5.9) and (6.1), we can assume that
[TABLE]
Only the term with can give a contribution and
[TABLE]
Writing , where are irreducible and compact, we therefore have that
[TABLE]
and hence an integer, since each integral is an intersection number. ∎
Assume that is irreducible. If it has dimension [math] and is moving, i.e., , then at each point. In fact, by the definition of irreducibility. However, as is illustrated by Example 3.11, if has positive dimension, can be nonzero at certain points even if is moving.
Proof of Theorem 1.1.
It is well-known that the blow-up of along only depends on the integral closure class of . Since is defined just in terms of the blow-up, cf. (1.1), it only depends on the integral closure class of .
By definition the distinguished varieties are precisely the sets where are the irreducible components of the exceptional divisor of the blow-up, see, e.g., [18] or [6].
The remaining statements of Theorem 1.1 are purely local and can be verified in the following way: Fix a point . In a suitable neighborhood of there is a section of a trivial vector bundle that generates there. By Proposition 4.5, . If we choose a trivial metric, then coincides with defined in [6], and from [6, Theorem 1.1] we have that . Because of the uniqueness of the decomposition (3.10) in fixed and moving components applied to all the statements now follows from [6, Theorem 1.1]. ∎
We have the following consequence of Proposition 5.6.
Lemma 6.2**.**
If and is a component of a Chern or Segre form of positive bidegree, then for each .
Proof.
Let generate the maximal ideal at , and write in a neighborhood of . By Proposition 5.6 and Stokes’ theorem, noting that has support at ,
[TABLE]
∎
Example 6.3* (Example 3.11 continued).*
It follows from Lemma 6.2 that for . From the geometric interpretation as a mean value of -planes through , or by a direct computation of , one can verify that . ∎
In view of Theorem 1.1, . For a general in or we can define the Segre numbers .
7. Regular embeddings
Assume that defines a regular embedding of codimension , cf. the introduction and Remark 5.1. As before denotes the associated reduced space, i.e., the zero set of . It is well-known that is locally free and thus is the sheaf of sections of a vector bundle known as the conormal bundle of in . We will denote its dual by , refer to it as the normal bundle of in , and view it as a holomorphic vector bundle over the reduced space . We will use the following alternative ad hoc definition of and its sections: A section of is a choice of holomorphic -tuple locally on for each local minimal set of generators for so that
[TABLE]
for any locally defined holomorphic matrix that is invertible in a neighborhood of . This defines a vector bundle over since for any two such choices there is an invertible matrix such that on the overlap in a neighborhood of . The connection between and is the non-degenerate pairing , where is a tuple, unique mod , such that .
Example 7.1*.*
If is smooth and reduced, then for any as above, the are linearly independent on and vanish on . Notice that on . Therefore, defines an injective mapping, hence an isomorphism, . In this case therefore is the usual normal bundle of complex differential geometry. ∎
Remark 7.2*.*
Several results of this section are well-known, at least in the algebraic context. For completeness and reference we give analytic proofs. ∎
Lemma 7.3**.**
Assume that is a vector bundle with a holomorphic section that defines . Then there is a canonical embedding
[TABLE]
Proof.
For each minimal set of generators of in some open connected there is a unique in such that . Set . Since generates it follows that is pointwise injective. Since it follows that If is a section of therefore
[TABLE]
Thus we can define as
[TABLE]
Since is pointwise injective it follows that is injective. ∎
In particular, if , then we have an isomorphism
[TABLE]
Proof of Proposition 1.5.
We let be the projectivization of and let be the tautological line bundle sitting in , equipped with the Hermitian metric inherited from . The line bundle is defined in the same way, with the Hermitian metric inherited from the normal bundle , which in turn has the metric induced by (7.2). Moreover, we let be the blow-up of along and let be the line bundle associated with the exceptional divisor. There are injective holomorphic mappings such that the diagram
[TABLE]
commutes and such that furthermore the Hermitian metric on coincides with the metric it inherits from via the first row.
Let us first explain the mapping . Given a minimal set of local generators of as above in say an open set we can represent as
[TABLE]
If we choose in , then we have a similar representation but with on the overlap . Recall that at the fibre of consists of all such that , cf. (7.1). We thus have the natural injection
[TABLE]
In we define by . If , then and , cf. the proof of Lemma 7.3, so we have that
[TABLE]
since . Since is injective, (7.8) provides an injective extension of across in . This extension is well-defined on overlaps because if , then and by (7.3) hence . For thus in is mapped to and by in turn to so the composed mapping is equal to the mapping induced by the canonical embedding , cf. (7.4). Thus the lower “half” of the diagram is defined and commutes.
We now define the mapping . Since is principal we recall from the proof of Theorem 5.2 (with and ) that can be identified with a line subbundle of via the mapping . Since by commutativity is the restriction of to we have an injective mapping . We must verify that it actually takes values in . By continuity it is enough to check that this holds over . However, there the section is non-vanishing and mapped onto . Thus is mapped onto which is in by definition.
It remains to explain . Notice that induces an embedding and hence also an embedding . Since is already defined, there is a unique mapping so that and the diagram commutes. If is a vector in , then by definition equals . However, the norm of induced by the top line is which in turn is as well. Thus the claims about (7.6) are proved.
As before, cf. (5.4), we let . By (7.6), is the first Chern form of and so, by definition, cf. (2.4),
[TABLE]
Each irreducible component of corresponds to an irreducible component of and for some integers . Since and are smooth it follows that
[TABLE]
Multiplying by and applying to the left hand side of (7.9) we get
[TABLE]
The same action on the right hand side of (7.9) gives, using that ,
[TABLE]
Summing up we get
[TABLE]
where the last equality follows from (5.9) (with and ); notice that here. It remains to see that is the fundamental cycle : Since we get from (7.10) that The same argument applied to the section of the trivial -bundle (with trivial metric) over gives that . It follows from [10, Ch. 3.16, Thm 3] that is the proper intersection , and it follows from [12, Ch. 7] that this product is the fundamental cycle in case of a regular embedding. ∎
Remark 7.4*.*
In the proof above we did not describe explicitly. With the notation above, in a set we can consider as the line subbundle of such that the fibre over a point is the line . Thus maps the point to in . ∎
It is well-known, and indeed follows from the proof above, that can be seen as the closure in of the graph ; then the mapping is of course just the natural inclusion.
Corollary 7.5**.**
Let be an irreducible subvariety and assume that defines a regular embedding of codimension in . Then
[TABLE]
Proof.
From Proposition 1.5 we have for degree reasons that . Since and intersect properly by assumption, makes sense and, moreover, cf. [6, Section 2.4] and (5.15). On the other hand, from Proposition 1.5 applied to , cf. (5.12), Thus
[TABLE]
If the tuple generates , then generates and the transition matrices of are the restriction to of the transition matrices of . Thus Moreover, the Hermitian metric on is inherited from so that
[TABLE]
By Proposition 1.5, (5.12), (7.11) and (7.12) we thus get
[TABLE]
∎
Proof of Proposition 1.4.
Notice that the right-hand side of the equation in the formulation of the proposition is well-defined in view of Proposition 4.1. In view of Theorem 1.2 and (4.4) the proposition follows immediately from Proposition 1.5 if there is a vector bundle with a section defining . If not we still have, cf. Remark 7.4, the commutative diagram
[TABLE]
By definition, cf. (1.1), recalling that , S({\mathcal{J}},X)=p_{*}\big{(}[D]\wedge 1/(1+c_{1}(L_{D}))\big{)} and, by (2.4), s(N_{{\mathcal{J}}}X)=\pi_{*}\big{(}1/(1+j^{*}c_{1}(L_{D}))\big{)}. Thus the result follows as in the proof of Proposition 1.5, replacing computations in by analogous ones in . ∎
Proposition 7.6**.**
Let be a holomorphic section of a Hermitian bundle defining the regular embedding and let be a holomorphic section of a Hermitian bundle defining a regular embedding of codimension . Suppose that the section of the Hermitian bundle defines a regular embedding of codimension . Then
[TABLE]
Proof.
Let us first assume that . Then the statement is symmetric in and ; and are sections of line subbundles and defining divisors and , respectively. By Proposition 1.5, , cf. (7.5), and so, by Corollary 7.5, since is generically non-vanishing,
[TABLE]
We have that is a section of the Hermitian bundle defining a regular embedding of codimension . Denote the corresponding ideal by , its zero set by , and notice that . By Proposition 1.5 we have
[TABLE]
where the last equality follows as in the end of the proof of Proposition 1.5. It follows from (2.7) and (2.10) that . This concludes the proof when .
Now assume that . Let be the blow-up of along . Then both and define principal ideals and it is readily verified that defines a regular embedding in of codimension . Since is a modification it is generically an isomorphism and hence from Example 5.3, Theorem 5.2 (iv), and the case proved above, we get
[TABLE]
∎
Remark 7.7*.*
It is not necessary to assume that defines a regular embedding; the proof only relies on the fact that defines a regular embedding. One can therefore formulate a variant of Proposition 7.6 that is a global version of Lemma 9.2 in [6]. ∎
Example 7.8*.*
Let be a section of a locally trivial fibration with one-dimensional fibers, let be a section of a Hermitian line bundle defining , and let be a section of a Hermitian bundle defining a regular embedding. If , then
[TABLE]
To see this, notice first that it follows from Proposition 1.5 and (2.7) that . Thus by Proposition 7.6, . ∎
Let be a regular embedding of codimension . We conclude with a short discussion of the -Gysin mapping (1.8). It is further studied in [4]. In analogy with Chow theory, cf. [12, Ch. 6], one can think of as an intersection of and in . We assume that is defined by the section of the Hermitian bundle so we can also consider the more explicit mapping (1.9).
First, let be a product of components of Chern or Segre forms. We claim that
[TABLE]
so that (1.9) can be seen as a generalization to of . In fact, by (5.14), , and so (7.14) follows from Proposition 1.5 and (2.7). In the same way (1.8) is a generalization to of .
Example 7.9*.*
If is a divisor, i.e., , then we can assume that is a section of a line bundle . Then , cf. (7.5). Assume that is irreducible. If vanishes identically on , then , and hence Otherwise and then
[TABLE]
∎
8. Variants of the Poincaré-Lelong formula
Let be a meromorphic section of a Hermitian line bundle . We say the intersects properly if for each irreducible component of , intersects properly, cf. Section 2, i.e., is non-trivial on each . We have the following Poincaré-Lelong formula “on ”:
Proposition 8.1**.**
Assume that is a meromorphic section of such that intersects properly. Then , a priori defined where is holomorphic and non-zero, extends to a current of order [math] on . Moreover, there is a generalized cycle in with Zariski support on such that
[TABLE]
If , then .
We say that is the proper intersection of and . Choosing a trivial metric on locally, we see that only depends on the divisor and not on (since if is pluriharmonic). In view of the last statement of the proposition, is well-defined in for .
Proof.
By assumption, is generically defined on . Each irreducible component of is a finite sum of non-zero generalized cycles with , see Remark 3.10 and Lemma 3.8. Let us consider such a and let be a subset of positive codimension such that is holomorphic and non-vanishing on . Then
[TABLE]
holds there, and since the right hand side has an extension to of order [math] so has the left hand side. Since has positive codimension in , . Summing up the first claim of the proposition follows.
Consider again a as above. From the usual Poincaré-Lelong formula, cf. Proposition 2.1, we have
[TABLE]
on . Summing up we get (8.1) with defined as the sum of all . The last statement of the proposition follows since if is of the form , where is a component of a -form. ∎
If is holomorphic, and thus, cf. (7.15),
[TABLE]
It follows as in the proof of Theorem 5.2 that .
Now assume that is a tuple of global sections of and consider the section of . In view of (5.2) we have
[TABLE]
where the right hand side is defined by the limit procedure in (5.2). If is a local frame for , then , where is a tuple of holomorphic functions. Clearly depends on the choice of frame but does not. Thus
[TABLE]
is a well-defined global current which in addition is independent of the Hermitian metric on .
Remark 8.2*.*
Let be an open set where we have a local frame for . If we choose the metric on in so that and equip with the induced metric, then . ∎
For instance, if is just one single section, i.e., , then (8.1) implies that dd^{c}\big{(}\log|h|_{\circ}^{2}\cdot\mu\big{)}=[{\rm div}h]{\wedge}\mu.
Example 8.3*.*
Let be the generalized cycle in of Example 3.11 and let be a section of defining a line through . Then has dimension , it is irreducible and . Thus intersects properly. We claim that . Let be the line . Notice that if we consider as sections of the line bundle , then , where . Now
[TABLE]
where the first equality follows from [11, Ch. III Corollary 4.11] and the second one from (8.5). In the affinization where we have the frame element , so in local coordinates we have ; notice that it is harmonic on and has a simple pole at so that Now the claim follows since . Notice that while . ∎
9. The -Stückrad-Vogel class
Throughout this section is a compact (reduced) analytic space and is generated by a finite number of global sections of the line bundle , to begin with without any specified Hermitian metric. For instance, if is projective, then given there is a very ample such that is globally finitely generated, see, e.g., [18, Theorem 1.2.6].
The classical Stückrad-Vogel (SV) algorithm, [20], is a way to produce intersections by reducing to proper intersections of cycles by divisors. The resulting SV-cycles define an element, the SV-class , in that only depends on and the line bundle . It is related to the Segre class via van Gastel’s formulas, [14], see below.
We shall define an analogous -SV class in for any , and this class will be related to our Segre class via analogues of van Gastel’s formulas. To motivate our definition we first consider the SV-algorithm on a generalized cycle : If then vanishes identically on and the algorithm stops directly. Otherwise, let be the irreducible components of . These are precisely the irreducible components of that are not contained in . For each the set of that vanish identically on is a proper subspace of the finite-dimensional vector space . Thus each in the complement of intersects properly, by definition; that is, a generic will do. Let us choose such a section and call it . Next, we consider . If is empty the algorithm stops. If not, a generic intersects properly. Let us choose such a section and call it . We proceed in this way until for some and the algorithm stops. If is nonempty, then since has dimension [math], any proper intersection with a divisor will give just [math], and the SV-algorithm stops.
If for some , then we can choose in an arbitrary way if we adopt the convention that any intersects the generalized cycle [math] properly and . We have the following definitions:
Definition 9.1**.**
An ordered sequence of sections of is a Stückrad-Vogel (SV) sequence on if intersects
[TABLE]
properly, . Given a SV-sequence on , we have the associated999It would me more correct but somewhat inconvenient to use the term SV-generalized cycle. SV-cycle
[TABLE]
where
[TABLE]
Here we use the convention that acts on the whole current on its right, i.e., , cf. [6, Sections 3 and 6].
Example 9.2*.*
If vanishes identically on , then . ∎
If does not intersect properly we can still define by (8.4). Since if vanishes identically on we have that where are the irreducible components of that intersects properly. By this convention therefore if the right hand side is a proper intersection. For any sequence of sections of we can thus define (9.2) with
[TABLE]
and as long as is a SV-sequence it is consistent with the previous definition. Let be a sequence of global sections of that generate . Given , , let which is well-defined up to a nonzero constant. If is a generic tuple, then is a SV-sequence on and, cf. (9.3),
[TABLE]
is the associated SV-cycle. As observed above, however, (9.4) makes sense for any .
Proposition 9.3**.**
Assume that . Then
[TABLE]
where is the natural normalized volume form on .
Proof.
We may assume that where and is connected. Then is irreducible. If vanishes identically on , then on and by definition both sides of (9.5) vanish. Thus we can assume that is nontrivial on , is principal and that the exceptional divisor is defined by the section of the line bundle . Then where is a non-vanishing tuple of sections of . Notice that
[TABLE]
Since is non-vanishing on , as in [6, Eq. (6.3)], for generic we have
[TABLE]
where all intersections are proper. By [6, Lemma 6.3] the left hand side of (9.5) is therefore equal to
[TABLE]
Now assume that we locally have a flat metric on . With the notation in the proof of Theorem 5.2 we then have since is a tuple of sections of and , cf. (9.12) below. From (5.8) we can therefore deduce that (9.6) is equal to the right hand side of (9.5). ∎
Remark 9.4*.*
Proposition 9.3 is similar to [6, Theorem 6.2]. The analogues of the identities (6.8) and (6.9) in that theorem hold in the present situation as well; after adaption to the present situation the proof in [6] goes through. ∎
Definition 9.5**.**
Given a line bundle and a tuple of sections of that generate and we define the generalized cycle
[TABLE]
It follows from (9.4) and (9.5) that is a mean value of SV-cycles on .
Notice that in general, the subspace of generated by is proper. Nevertheless, the class of in is independent of the choice of tuple :
Proposition 9.6**.**
If is another tuple of sections of that generate , and , then
Proof.
We first consider and keep the notation from the proof of Proposition 9.3. If vanishes on , then . Thus we assume that on as usual. Since is a non-vanishing tuple of sections of , is a metric on and hence is a representative of the first Chern class . From (9.6) and (2.2) we have
[TABLE]
Now , where also is a tuple of sections of , and hence and differ by a -form; in fact the difference is of the global function . Thus the class in is independent of the choice of tuple. Finally, if is a component of a -form and , then (9.7) is in . ∎
In view of Remark 8.2 we have that in for a suitable metric on on . Therefore local statements that hold for must hold for as well: For instance, if is a component of a Chern or Segre form, then by (5.14),
[TABLE]
If is proper and is a tuple of sections of that generate , then is a tuple of sections of that generate . If , then by Theorem 5.2 (iv),
[TABLE]
In view of Proposition 9.6 the following definition makes sense.
Definition 9.7**.**
Assume that has sections that generate globally. For we let , the -SV class, be the class in defined by for a tuple of generators and a representative of .
We now relate the -SV class to the -Segre class in analogy with van Gastel’s formulas [14], see (9.22) below. To this end we first give a -variant and therefore choose a Hermitian metric.
Theorem 9.8**.**
Let be a tuple of sections of that generate . Assume that we have a Hermitian metric on with first Chern form and consider as a section of the Hermitian vector bundle . For we have
[TABLE]
and
[TABLE]
Proof.
Let us assume that where and is connected. If vanishes identically on then and and thus (9.10) and (9.11) are both trivially true.
We can thus assume that , where is a non-vanishing tuple of sections of , or equivalently, a non-vanishing section of . As in the proof of Theorem 5.2 we let . Let be the induced metric on . Then, cf. the proof of Theorem 5.2, so that and hence
[TABLE]
It follows from (9.7) and (9.12) that101010Notice that is independent of the metric on .
[TABLE]
We have, cf. (5.9),
[TABLE]
Thus (9.10) follows, and (9.11) is proved in a similar way. ∎
Corollary 9.9**.**
If and we have
[TABLE]
Remark 9.10*.*
Suppose that . Fix and consider the decomposition, cf. (3.10), of the component of codimension . Since is obtained as a mean value of , which are cycles of pure codimension , it is clear that any irreducible -cycle of that occurs in all generic SV-cycles must appear in . In the literature, such a cycle is called a fixed component; any other component in a generic SV-cycle is called a moving component. Since the Zariski support of the irreducible components of have codimension strictly smaller than , they must be mean values of moving components of . It follows from (9.14) that the fixed components of and are the same, cf. (4.10). ∎
Example 9.11*.*
Assume that , let , and let be the linear subspace . If , then is a smooth (hence regular) embedding defined by the section of . Thus , cf. (7.5). We want to compute the -Gysin mapping (1.8), or more precisely (1.9), in this case. If we equip with the Fubini-Study metric , then , and therefore
[TABLE]
Let . By (9.11)
[TABLE]
By (9.16) one can thus reduce the computation of (1.9) to find , which in turn can be obtained as mean values of generic SV-cycles. ∎
From Theorem 9.8 and Lemma 6.2 we have
Proposition 9.12**.**
For each ,
For we let
[TABLE]
where is any representative of ; by Stokes’ theorem it is well-defined. Moreover, in view of (4.2) it only depends on the image of in and so is well-defined on . If is a cycle, then is the usual degree of with respect to . The degree is indeed the mass with respect to of , and we have the following mass formula:
Proposition 9.13**.**
If is generated by the tuple of sections of and , then
[TABLE]
If , then the last term on the right hand side vanishes.
Proof.
We can assume that where and is connected. If vanishes identically on , then both sides of (9.17) are equal to . Otherwise we may assume that where is a section of the line bundle defining the divisor on and is a non-vanishing section of , where . Notice that in view of (2.1),
[TABLE]
Let . By (9.12), . From (5.5) thus
[TABLE]
where , which is a a global integrable form on . By repeated use of Stokes’ theorem we get
[TABLE]
Now (9.17) follows from the proof of Proposition 9.3, cf. (9.6) and (9.7), since
[TABLE]
The last statement follows since . ∎
If is -plurisubharmonic with analytic singularities, then one can define for any and an analogous mass formula was proved in [7], see [7, Theorem 1.2].
Remark 9.14*.*
Assume that and are as in the previous proof. If is a section of , then where is a section of . Let be a SV-sequence on and be the associated SV-cycle. If is sufficiently generic, then with essentially the same proof we get
[TABLE]
∎
Finally let us consider the special case when is an ordinary cycle. With no loss of generality we can assume that . Let be a sequence of sections of . One can check that is an SV-sequence on if and only if
[TABLE]
this is the condition in [20]. The SV-algorithm in [20] is precisely the same as used above and the resulting SV-cycle therefore is, in our notation, cf. (9.3),
[TABLE]
Let us now assume that is irreducible. If vanishes identically, then for any SV-sequence, and we define . Otherwise, let us assume that is a modification such that is principal, and let and be as before. In particular, let be a section of that defines the divisor . Then where are sections of . As in the proof of Proposition 9.3, cf. [6, Eq. (6.3)], we then have
[TABLE]
where the case shall be interpreted as . Choosing the sequence even more generic if necessary, we can in addition assume that all the intersections
[TABLE]
are proper. As before, let and . Then the first Chern class of is . By definition, cf. Section 2, therefore (9.20) is a representative of the Chow class . We conclude that a generic SV-sequence defines the Chow class
[TABLE]
It follows that this class only depends on and but not on the choice of modification of . If is not irreducible and consists of the irreducible components , then we define . The formulas
[TABLE]
are due to van Gastel, [14, Corollary 3.7], and can be obtained by mimicking the proof of Theorem 9.8 above.
10. Comparison of and
In this section we assume that is compact and projective. In particular, each line bundle over has a nontrivial meromorphic section. Let be the equivalence classes of -closed -currents on of order zero such that if there is a current of order zero such that . Notice that if is an embedding into a smooth manifold of dimension , then there is a natural mapping induced by the push-forward of currents. If is smooth and , then this map gives an isomorphism ; the surjectivity is clear and the injectivity follows since a closed current of order zero locally has a potential of order zero.
Example 10.1*.*
Assume that is a meromorphic section of a Hermitian line bundle such that intersects properly. It follows from Proposition 8.1 that and coincide in . ∎
Let be a Hermitian vector bundle. Since is smooth and closed on , is a well-defined mapping on . Another choice of metric gives rise to a smooth form that is for a suitable smooth form (if ). Thus we get a mapping on . Let be a short exact sequence of Hermitian vector bundles on . Then, cf. Section 4, there is a smooth on such that . Thus
[TABLE]
In view of (4.2) there is a natural mapping
[TABLE]
If is a proper map, then
[TABLE]
If is a vector bundle, then
[TABLE]
In view of (2.17) there is a mapping
[TABLE]
taking a representative of to the cohomology class determined by its Lelong current. Clearly
[TABLE]
as a consequence, the image of is contained in the image of . If is proper as above we have from (2.13) that
[TABLE]
We will use the equalities, see [12, Theorem 3.2],
[TABLE]
in if is a vector bundle, and
[TABLE]
in if is exact. In analogy with (10.3) we have:
[TABLE]
Proof of Eq. (10.8).
First assume that has rank ; it is then sufficient to show (10.8) for . By -linearity it is enough to look at each irreducible component of separately and so we may assume that is represented in by an irreducible subvariety . Let be a meromorphic section of that is nontrivial on . Then is represented in by the cycle and so
[TABLE]
in , where the second equality follows from Example 10.1 applied to .
Next, assume that (10.8) holds for vector bundles of rank and consider of rank . Let , where , and let be the tautological line subbundle so that we have a short exact sequence over . Take in such that . By (10.6) and (10.7),
[TABLE]
By (2.1), (2.8), (10.1), (10.5), (10.9), and the induction hypothesis
[TABLE]
∎
Proof of Proposition 1.6.
We have already noticed, (10.4), that the image of is contained in the image of . For the converse inclusion consider in , . By (10.5), (10.8), (10.4), (10.3), and (10.2) we have
[TABLE]
and thus is in the image of . ∎
Proof of Proposition 1.7.
Let . We may assume that is an irreducible subvariety . If vanishes identically on , then is mapped to under both the Gysin and the -Gysin mapping. Thus we can assume that we have a modification such that is principal on . Let be the exceptional divisor and the associated line bundle. Using (10.4), (10.5), and (10.8), recalling that , see the introduction and Remark 5.1, we have
[TABLE]
By an analogous computation backwards with rather than , using (10.3) and (10.2), we find that the right hand side of (10.10) is equal to . ∎
Notice in particular that Summing up we have seen that the - and -objects coincide on cohomology level. However, there are no nontrivial mappings such that
[TABLE]
commutes for each proper mapping mapping . In fact, let be a one-point set , and let be a manifold with two distinct points that are rationally equivalent. Take so that . If is nonzero, then has support at and is nonzero. If (10.11) commutes, then must be a nonzero point mass at . Changing the roles of and we get a contradiction since in .
Neither there are non-trivial mappings such that
[TABLE]
commutes and for each line bundle . Just take that has a nontrivial line bundle with flat metric and a meromorphic non-trivial section, as in the following example.
Example 10.2*.*
Let be a complex -dimensional torus. It is well-known that two different points and are not rationally equivalent, i.e., there is no meromorphic function whose divisor is . But the cohomology class determined by is zero. Let be the line bundle equipped with some Hermitian metric. By the Poincaré-Lelong formula, is a representative of the cohomology class of and is thus -exact. Hence, since is smooth, the -lemma shows that there is a smooth global function such that . If we modify the metric on by we have . ∎
The reference list from the paper itself. Each links out to its DOI / PubMed record.
- 1[1] Achilles, R. & Manaresi, M. Multiplicities of a bigraded ring and intersection theory , Math. Ann. 309 (1997) 573–591
- 2[2] Achilles, R. & Rams, S. Intersection numbers, Segre numbers and generalized Samuel multiplicities , Arch. Math. (Basel) 77 (2001) 391–398
- 3[3] Andersson, M. Residue currents of holomorphic sections and Lelong currents , Arkiv för matematik 43 (2005) 201–219
- 4[4] M. Andersson & D. Eriksson & H. Samuelsson Kalm & E. Wulcan & A. Yger Nonproper intersection products and generalized cycles , ar Xiv:1908.11759 [math.AG math.CV]
- 5[5] M. Andersson & H. Samuelsson Kalm A note on smooth forms on analytic spaces , ar Xiv:2003.01959 [math.CV]
- 6[6] M. Andersson & H. Samuelsson Kalm & E. Wulcan & A. Yger Segre numbers, a generalized King formula, and local intersections , J. Reine Angew. Math. 728 (2017) 105–136
- 7[7] M. Andersson & Z. Błocki & E. Wulcan On a Monge-Ampère operator for plurisubharmonic functions with analytic singularities , Indiana Univ. Math. J. 68 (2019), no. 4, 1217–1231
- 8[8] Bost, J.-B. & Gillet, H. & Soulé, C. Heights of projective varieties and positive Green forms , J. Amer. Math. Soc. 7 (1994) 903–1027
