Cohomology rings and algebraic torus actions on hypersurfaces in the product of projective spaces and bounded flag varieties
Grigory Solomadin

TL;DR
This paper investigates the maximal algebraic torus actions on Milnor hypersurfaces, computes their automorphism groups, classifies certain toric hypersurfaces, and describes their cohomology rings.
Contribution
It provides the first comprehensive analysis of torus actions and cohomology structures for Milnor hypersurfaces in complex algebraic geometry.
Findings
Maximum dimension of torus actions on Milnor hypersurfaces determined
Automorphism groups of Milnor hypersurfaces computed
Cohomology rings of classified hypersurfaces explicitly described
Abstract
In this paper, for any Milnor hypersurface we find the largest dimension of effective algebraic torus actions on it. The proof of the corresponding theorem is based on the computation of the automorphism group for any Milnor hypersurface. We find all generalised Buchstaber-Ray and Ray hypersurfaces that are toric varieties. We compute the Betti numbers of these hypersurfaces and describe their integral singular cohomology rings in terms of the cohomology of the corresponding ambient varieties.
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Taxonomy
TopicsAlgebraic Geometry and Number Theory · Commutative Algebra and Its Applications · Advanced Combinatorial Mathematics
Cohomology rings and algebraic torus actions on hypersurfaces in the product of projective spaces and bounded flag varieties
Grigory Solomadin
Laboratory of algebraic topology and its applications, Faculty of computer science, National Research University Higher School of Economics, Russian Federation
Abstract.
In this paper, for any Milnor hypersurface we find the largest dimension of effective algebraic torus actions on it. The proof of the corresponding theorem is based on the computation of the automorphism group for any Milnor hypersurface. We find all generalised Buchstaber-Ray and Ray hypersurfaces that are toric varieties. We compute the Betti numbers of these hypersurfaces and describe their integral singular cohomology rings in terms of the cohomology of the corresponding ambient varieties.
Key words and phrases:
Toric varieties: automorphisms of algebraic varieties, torus actions, blow-ups, fiber bundles, hypergraphs
2020 Mathematics Subject Classification:
Primary: 14L30, 53D20; secondary: 14M25, 14J50, 94C15
The publication has been prepared with the support of “RUDN University Program 5–100” program. The reported study was funded by RFBR, project number . The reported study was funded by the grant of “Young mathematics of Russia” foundation.
1. Introduction
In the present paper, we study effective algebraic torus actions on the particular collections of nonsingular complex algebraic hypersurfaces, namely, , and in , and , respectively, for any nonnegative integers . Here the -dimensional varieties and are a complex projective space and a bounded flag variety [bu-ra-98'], respectively.
For any integers the transverse intersection of the Segre embedding image of to
with a generic hyperplane is called a Milnor hypersurface. In particular, is a hypersurface in of bidegree . The hypersurface was defined as a toric variety in [bu-ra-98] for any integers . Following the definition of the hypersurface given in [ra-86] for any integers by Ray, we call it a Ray hypersurface.
Recall that a normal algebraic variety over containing an algebraic torus as a dense open orbit is called a toric variety if the action of on itself extends to a regular action on . The motivation for our study stems from the question raised in [so-17]: is a toric variety? A positive answer to this question leads to the short proof of one theorem from algebraic topology, as described in [so-17].
For any integers it was shown in [bu-ra-98] that the variety is a toric variety iff . Demazure’s result [dem-70] allows to describe the automorphism group of any Milnor hypersurface that is a toric variety. We remark that the automorphism group of was described explicitly in [ch-pr-sh-19, Lemma 4.5]. We compute the automorphism group of for arbitrary integers . The computation is based on the well-known sheaf-theoretic argument for projective Fano varieties. We deduce the first main result of this paper from this computation.
Theorem 1.1**.**
The largest dimension for algebraic torus actions on the Milnor hypersurface is equal to for any integers .
We provide a natural definition of the variety as a hypersurface in for all integers . Taking into account that is isomorphic to the variety from [bu-ra-98] for any integers such that , we call the hypersurface a generalised Buchstaber-Ray hypersurface. The following two theorems represent main results of this paper, in addition to Theorem 1.1.
Theorem 1.2**.**
The hypersurface is a toric variety iff or .
Theorem 1.3**.**
The hypersurface is a toric variety iff or .
Theorem 1.3 provides a complete answer to the problem discussed in [so-17]. In order to prove Theorem 1.2, for any integers such that or , we define the algebraic torus action on endowing it with the structure of a toric variety. For any integers we define the effective action of the algebraic torus on . This action corresponds to the -dimensional algebraic subtorus in the connected component of the automorphism group of . Let be any integers that do not satisfy the condition of Theorem 1.2. Let be any maximal algebraic torus in such that . All maximal algebraic tori of the algebraic group are conjugate to each other. We prove that with -action is not a toric variety by using a combination of methods from [gu-za-01g], [ba-14] and [ta-04]. These two facts together imply that is not a toric variety (for these particular values of ). We prove Theorem 1.3 by following a similar approach.
In addition, for all integers we compute the Betti numbers of the hypersurfaces and , and relate their integral singular cohomology rings to the cohomology rings of and , respectively. Namely, we prove that the morphism of the respective integral cohomology rings, induced by the embedding of any hypersurface considered above to the ambient space, is onto, and describe its kernel.
The paper is organised as follows. In Section 2, the automorphism group of any Milnor hypersurface is computed and the proof of Theorem 1.1 is provided. In Section 3, we define generalised Buchstaber-Ray and Ray hypersurfaces. In Section 4, we define a certain class of algebraic torus actions on any nonsingular complex manifold. We assign the hypergraph equipped with additional structures to any action from this class. These structures generalise the notion of an axial function and a connection from GKM-theory (see [gu-za-01]) to the case of a hypergraph. In Section 5, the proofs of Theorems 1.2 and 1.3 are given. In Appendix A, we describe the generalised Buchstaber-Ray and Ray hypersurfaces in terms of consecutive blow-ups along smooth subvarieties as well as in terms of algebraic fiber bundles. In Appendix B, we study the integral singular cohomology rings of generalised Buchstaber-Ray and Ray hypersurfaces, and compute the respective Betti numbers by utilizing the results from Appendix A.
2. The automorphism group of a Milnor hypersurface
Unless explicitly stated otherwise, in the sequel an algebraic variety (or, in short, a variety) is defined as a separated reduced irreducible scheme of finite type over . A hypersurface in a variety is a subvariety of codimension . An algebraic fiber bundle is a locally trivial algebraic fiber bundle in the Zariski topology. A holomorphic fiber bundle is a locally trivial complex-analytical fiber bundle over a complex manifold. We call any toric variety that is an algebraic fiber bundle a toric fiber bundle, if the base and the fiber are toric varieties and the projection is equivariant with respect to the given algebraic torus actions on and . A fiber bundle is a locally trivial topological fiber bundle. Occasionally, we call a fiber bundle with a particular structure (topological, holomorphic, algebraic, toric) with fiber an -bundle. We indicate the complex dimension of an algebraic variety (or complex manifold) by writing . We put .
In this paper, we repeatedly use the well-known bijective correspondence between (Cartier) divisors on a nonsingular algebraic variety and algebraic line bundles over ([ha-77, p.144]). This correspondence respects the equivalence relations of linear equivalence on divisors and of algebraic isomorphism on line bundles. Another variant of this correspondence takes place for complex manifolds and holomorphic line bundles, with appropriately defined equivalence relations in the holomorphic setting. For more details, see [gr-ha-78, Chapter 1, §1].
We denote by the dual vector bundle to any vector bundle (with a particular structure). We slightly abuse the notation and denote the pull-backs of all vector bundles , under the natural projections and of varieties by and , respectively.
We consider the set of all automorphisms of any algebraic variety as an abstract group with the natural group operation.
Definition 2.1**.**
The group is called the automorphism group of an algebraic variety . The connected component of the group is the subgroup of automorphisms that occur as a member of a family such that is an irreducible rational curve, the natural map defined by is a morphism, and is the identity for some .
It follows from the Definition 2.1 that for any algebraic torus acting on its image under the natural embedding to is contained in [ar-ba-13, Lemma 1.4, p. 1715].
Proposition 2.2**.**
[ra-64, Corollary 1, p.31]* Let be a nonsingular complete variety. Then is an algebraic group.*
Proposition 2.3**.**
[dem-70]* Let be a nonsingular projective toric variety. Then is an algebraic group of rank .*
Corollary 2.4**.**
Let be a nonsingular projective variety. Let be the rank of . For any integer and any effective action of by automorphisms on the following holds.
* One has , and there exists an extension of -action on to an effective action of on ;*
* Any two effective -actions by automorphisms on are equivariantly isomorphic;*
* If is a toric variety, then the action of any maximal torus in on endows with the structure of a toric variety.*
Proof.
Claims , follow from the theorem about conjugacy of all maximal algebraic tori in any algebraic group ([vi-on-90, p.119]) and Proposition 2.2. Claim follows from Proposition 2.3 and . ∎
Definition 2.5**.**
For for any integers the nonsingular hypersurface in given by the equation
[TABLE]
in the homogeneous coordinates of is called a Milnor hypersurface. Denote by the hypersurface in given by the equation
[TABLE]
The Milnor hypersurface is the divisor corresponding to the algebraic line bundle over . Here denotes the tautological line bundle over a complex projective space.
Remark 2.6*.*
The suitable automorphism of induces the isomorphism of subvarieties in . The map , , maps to . Hence, .
It is well known that ([ha-77, Example 7.1.1, p.152]). It is easy to prove the following lemma.
Lemma 2.7**.**
*Let be any integers. If , then . One has
\operatorname{Aut}(\mathbb{P}^{i}\times\mathbb{P}^{i})\simeq\bigl{(}\mathbb{P}GL_{i+1}(\mathbb{C})\times\mathbb{P}GL_{i+1}(\mathbb{C})\bigr{)}\rtimes\mathbb{Z}_{2}.*
We extend any automorphism of to the automorphism of as follows.
Lemma 2.8**.**
There is the monomorphism of algebraic groups . Its image consists of automorphisms of leaving invariant.
Proof.
Recall that there is the standard exact sequence relating the ideal sheaf of the subvariety to the structure sheaf of the ambient variety. For the natural inclusion , the corresponding exact sequence of sheaves on is
[TABLE]
Twisting (3) by one obtains the following exact sequence
[TABLE]
of sheaves. By [ha-77, Lemma 2.10, p.209], one has
[TABLE]
It follows from the cohomological long exact sequence of (4), the identity (which in turn follows from Künneth’s formula and the description of sheaf cohomology of ) and (5) that
[TABLE]
is an epimorphism. It is not hard to show that the abelian group is generated by the first Chern classes of the restrictions of the sheaves , to . Then one obtains from the following part of the long exact sequence
[TABLE]
of the exponential sequence of sheaves, where is the sheaf of germs of local holomorphic functions on (see [hi-66, p.127, §15.9]). The classes of , span the semigroup of effective divisors in . Any automorphism maps effective divisors to effective. Hence, the abelian group isomorphism defines the bijective map on the basis of the semigroup of effective divisors to itself. We conclude that the homomorphism restricts to the well-defined map on the set of generators of this semigroup, represented by and . This map is either identity or involution. Hence, , and acts on the sections of . We lift the automorphism to an automorphism of by choosing any section of the epimorphism (6) of -modules. The projective embedding corresponding to the sheaf is the Segre embedding
[TABLE]
We conclude that the automorphism of is the restriction of an automorphism of to . It also remains to notice that is an algebraic condition on . ∎
By Remark 2.6, one has . Without loss of generality, we compute the group for any integers such that . Let be the bilinear form on given by the formula
[TABLE]
for any . Let be the projection given by the formula . Define the bilinear form by the formula
[TABLE]
Let , . Define as
[TABLE]
where is the identity -matrix and the block structure is with respect to the decomposition
[TABLE]
in the basis of . The proof of the following lemma is straight-forward.
Lemma 2.9**.**
Let , . Suppose that for any such that , one has . Then the identity
[TABLE]
holds for some and some . The class is uniquely defined by the class .
For all , let
[TABLE]
be the subgroup of . (This is a subgroup because the identity holds for any . The inclusion easily follows from (1).) The following proposition is straight-forward to prove.
Proposition 2.10**.**
The group is a central extension of the following groups
[TABLE]
where the right homomorphism is given by in terms of (8).
Theorem 2.11**.**
Let be any integers such that . One has . If , then . For one has . In particular, holds for any .
Proof.
Since , one has . Now let . We apply Lemma 2.8. In the case of , the involution descends from to . Hence, by Lemma 2.7, in order to prove the claim of the theorem it remains to compute the subgroup of elements in with well-defined restrictions to . This follows easily from Lemma 2.9. The proof is complete. ∎
Proof of Theorem 1.1.
Follows from Theorem 2.11 and Corollary 2.4. ∎
Remark 2.12*.*
The quotient by the subgroup of the diagonal matrices is a principal -bundle. Let be the algebraic line bundle associated with it. Denote by the associated -bundle over corresponding to . In particular, the total space of the algebraic fiber bundle over is . The fiberwise transposed algebraic line bundle is defined in the obvious way. There is the natural isomorphism of the algebraic line bundles . The group is isomorphic to (see [ba-br-65]). The first Chern class is the generator of this cyclic group. In terms of Proposition 2.10, the group as a variety is isomorphic to the total space of the -bundle .
Let us compute by applying Theorem 2.11.
Example 2.13*.*
The algebraic line bundles over are isomorphic, because . By Remark 2.12, the total space of the algebraic -bundle is . We conclude that the total space of the algebraic fiber bundle over is isomorphic to . By Remark 2.12 and Theorem 2.11 we obtain the isomorphism of algebraic groups
[TABLE]
The Milnor hypersurface is a toric variety [bu-pa-15, pp.348–350]. Its automorphism group can be computed by Demazure’s theorem (see [dem-70], [oda-88, §3.4], [ar-15, Excercise 4.9, p. 329]), and the group obtained in this way agrees with (9). We finish this Section by defining a maximal algebraic torus in . For any integer the formula
[TABLE]
determines the -action on . Let be any integers such that . Then we define the effective -action on the hypersurface in the homogeneous coordinates of by the formula
[TABLE]
3. Definitions of and
3.1. Generalised Buchstaber-Ray hypersurface
Let us recall some definitions.
Definition 3.1**.**
[[bu-ra-98]] Let be the point, and let be the trivial line bundle. For any integer , let be the total space of the algebraic -bundle associated with the algebraic vector bundle over . Let be the tautological line bundle over . The variety is called a bounded flag variety. We abuse the notation slightly by defining to be the pull-back of under the composition of projections of -bundles, where .
An equivalent definition of a bounded flag variety was given in [bu-ra-98'] as follows. Choose a basis in . Then is the set of sequences of lines in such that
[TABLE]
hold, where denotes the line spanned by in . Put . The projection of the -bundle from Definition 3.1 is given by . Using (12), we obtain
[TABLE]
where denotes the linear span of vectors in . Let be the homogeneous coordinates of the line in (13), where the coordinates are dual to , for any . In particular, , for any . The embedding given by
[TABLE]
endows with the tuple of homogeneous coordinates. The image of in is given by the conditions
[TABLE]
These are quadratic equations (on the tuple of homogeneous coordinates ) given by vanishing of all -minors of the matrices (14).
It is well known that is obtained from by the sequence of blow-ups at strict transforms of the subvarieties of in any order, where runs over . The variety is a nonsingular projective toric variety of dimension (see [bu-ra-98'], [so-17]). The action of on , given by the formula
[TABLE]
has a dense open orbit.
The varieties were introduced by V.M. Buchstaber and N. Ray in [bu-ra-98] for any integers such that . They showed in [bu-ra-98] that is a nonsingular projective toric variety for any integers such that . We generalise their definition to the case of arbitrary integers , as follows.
Definition 3.2**.**
For any integers we call the hypersurface in given by the equation
[TABLE]
where are the homogeneous coordinates on the second factor in , a generalised Buchstaber-Ray hypersurface.
Remark 3.3*.*
Consider the hypersurface in given by the equation
[TABLE]
For any integers such that the hypersurface given by (17) is clearly isomorphic to . However, unlike , the hypersurface given by (17) is singular for , see [so-17]. Notice that , because substituting [math] for in (16), we obtain the equation which has no solutions.
Here is the definition of in terms of configurations of lines in a complex vector space. Endow with the natural Hermitian metric such that the standard basis of is orthonormal. Any point of is the sequence \bigl{(}l_{0},\dots,l_{i},l^{\prime}\bigr{)} of lines in satisfying the conditions
[TABLE]
for any integer . Put . Then is given in by the (algebraic) condition , i.e. the lines are orthogonal in .
3.2. Ray hypersurface
We introduce the next definition by following [ra-86], [so-17].
Definition 3.4**.**
For any integers , we call the hypersurface of given by the equation
[TABLE]
where , are the tuples of homogeneous coordinates on , , respectively, a Ray hypersurface.
Remark 3.5*.*
The natural involution maps to . Hence, for any integers . By definition, and for any integer . Notice that , because substituting [math] for in (19), we get the equation which has no solutions.
Here is the definition of in terms of configurations of lines in a complex vector space. Any point in is the sequence \bigl{(}l_{0},\dots,l_{i},l^{\prime}_{0},\dots,l^{\prime}_{j}\bigr{)} of lines in satisfying the conditions
[TABLE]
for any integers and . Put . Then is given by the (algebraic) condition .
4. Monodromy in the weight graph of an algebraic torus action
4.1. Definitions
Let us start this section by introducing the necessary notions.
Definition 4.1**.**
[Compare with [ba-14]] Let be any finite set. Let be any finite collection of elements (a multiset, i.e. repetitions are allowed in ) of the set . Let . The pair is called an (abstract) hypergraph. For any hypergraph , any elements of , of and of are called a vertex, a hyperedge and a pointed hyperedge, respectively. Any element such that is called a loop of . Any collection is called a collection of multiple hyperedges of if . For any , a vertex is called an initial vertex of a pointed hyperedge . Put
[TABLE]
For any the elements and are called an oriented edge and edge of , respectively, if . If is an oriented edge, then the complementary vertex of to is called a terminal vertex of . In the following, we consider only those hypergraphs that have neither loops nor multiple hyperedges. Denote the oriented edge coming from to in by (if such an edge exists). In this case, put . If any hyperedge of is an edge, then is called a graph.
Definition 4.2**.**
Let be any hypergraph. Denote by the maximal subgraph of the hypergraph . Denote by the subgraph of consisting of all edges in that have empty intersection with any hyperedge that is not an edge of . We call an -regular hypergraph, if for any vertex of one has .
Clearly, is a subgraph of . In general, this inclusion is strict.
Example 4.3*.*
Consider the edge graph of the tetrahedron with the set of vertices . Remove the edges corresponding to and add the hyperedge to this graph. Denote the obtained hypergraph by . Clearly, is , and the edges of are , , . However, , and is empty.
We introduce the notion of a weight hypergraph, motivated by notion of GKM-hypergraph ([ba-14]) and GKM-graph ([gu-za-01]), as follows. Let be any -regular hypergraph. Let be any map.
Definition 4.4** (cf. [gu-za-01, ba-14]).**
We call an axial function on , if the following conditions hold.
-
for any edge ;
-
for any .
We call a pair an -type weight hypergraph (or a weight hypergraph for short, if the values of are clear from the context). We call the pair a weight graph if is a graph.
Consider any collection of bijective maps .
Definition 4.5** (cf. [gu-za-01]).**
We call a connection on the weight hypergraph , if the following conditions hold for any .
-
;
-
;
-
For any there exists an integer such that
[TABLE]
Remark 4.6*.*
A connection on a weight hypergraph consists of the maps , where exhausts the oriented edges of the graph . These maps act on the subsets of oriented edges of the graph .
In order to study different connections on a given weight hypergraph, we give the following definition.
Definition 4.7**.**
Let be a weight hypergraph with a connection . For any edge of we say that is definite at an edge , if the affine lines in the affine space are mutually different where runs over . Otherwise, we call nondefinite at . When is clear from context, we call (non-)definite, if is (non-)definite at , respectively. If is definite at any edge of , then we call a definite weight hypergraph.
The notion of definiteness of an edge is independent of an orientation of due to the following simple proposition.
Proposition 4.8**.**
Let be a weight hypergraph with a connection . Let be an edge of . If is definite at , then is definite at , and the values of are uniquely determined by .
Proof.
Due to bijectivity of and (21), one establishes the equality
[TABLE]
of the sets of lines in the affine space by letting , . Hence, is definite at . The set (22) contains exactly elements because is definite at . One has iff the affine lines in corresponding to and by (22) coincide. Hence, is uniquely determined by . ∎
Definition 4.9**.**
(cf. [gu-za-01], [ta-04]) A sequence of edges in is called an edge path, if for any . For any edge path in the initial and terminal vertices of are and , respectively. Let be any edge path in the subgraph of the hypergraph . Then the parallel transport map of the connection is defined by the formula , where is any oriented edge from . If , then is called the monodromy map of along .
We generalise the notion of a face of a GKM-graph to the case of a nonregular subgraph in a weight hypergraph in the following two definitions.
Definition 4.10**.**
Let be a connected subgraph of . Let be any oriented edge satisfying . We call an internal (external, respectively) edge for in , if (, respectively).
In general, an internal edge for may not belong to .
Example 4.11*.*
Consider the graph with the set of vertices , whose edges are . There exists a unique axial function on such that , , . Clearly, there exists a unique connection on . Let be the subgraph of with , whose edges are . Then the edge is internal for . However, .
Definition 4.12**.**
Let be a connected -regular hypergraph endowed with a connection . Let be any connected subgraph of the graph . We call an invariant subgraph of with respect to , if the edge is internal for , where is any edge of and is any internal edge for .
Let us relate the above definitions with the notion from GKM-theory when is a graph.
Definition 4.13** ([gu-za-01], [bu-pa-15]).**
The axial function on is called -independent, if the vectors are linearly independent for any and any different . A weight graph endowed with an axial function and a connection is called a GKM-graph, if is -independent. A connected -regular subgraph of the GKM-graph is called an -face of (or a face), if one has for any and any .
It is well known that for any GKM-graph with a -independent axial function there exists no more than one connection on it (e.g. see [gu-za-01]).
Remark 4.14*.*
Any face of a GKM-graph with a connection is invariant under in sense of Definition 4.12. (We distinguish between the notion of a face of a GKM-graph [gu-za-01] and its generalisation from Definition 4.12, namely, the notion of an invariant subgraph in a weight hypergraph.) Let be any weight hypergraph. Let be any connected subgraph of . It is easy to prove that is invariant under iff for any edge of and any external edge for the edge is external for . For any edge path in any invariant subgraph of if an edge is internal (external, respectively) for , then is internal (external, respectively) for . Let us finally remark that, in general, an invariant subgraph is not regular. Following the notation of Example 4.11, the nonregular subgraph of is invariant for , because the set of external edges to in is empty, see Fig. 1.
4.2. Weight hypergraph of a complex -manifold
Let be the algebraic (i.e. noncompact) torus acting effectively by biholomorphic maps on a compact connected complex manifold , where . Denote by the set of fixed points of this action.
Assumption 4.15**.**
The manifold has an open cover by its open complex -invariant submanifolds , where . One has for any . For any there exists a -equivariant biholomorphism . The action of on here is induced by a monomorphism such that is a direct product of and some algebraic torus. The -action on here is given by the formula
[TABLE]
Remark 4.16*.*
Assumption 4.15 implies that the set of fixed points is finite and nonempty, and that the -stabiliser of any point is a direct factor of , that is an algebraic subtorus.
The induced representation of on the tangent space at any fixed point decomposes into the sum
[TABLE]
of characters corresponding to the primitive nonzero elements . These vectors are called the weights of the -action on at the fixed point .
For any and any let be the connected component of such that (notice that there exists a unique for any ). The -action on induces the effective action of the algebraic torus on .
Remark 4.17*.*
For any such that is not represented by a weight of the -action at , the set is finite and zero-dimensional.
For any let be all weights of the -action at that are -multiples of for some , that is, for all . For any nonzero element of denote the corresponding class in by .
Proposition 4.18**.**
Suppose that Assumption 4.15 holds for the -action on . Then for any and any nonzero the set has a structure of a complex -invariant closed submanifold of . One has and
[TABLE]
Proof.
For any the linear subspace of coincides with the linear subspace (see Assumption 4.15). This implies all statements of the proposition. ∎
The following fact is well known.
Proposition 4.19**.**
Any -dimensional -invariant complex submanifold of is equivariantly biholomorphic to the standard -action on having weights for some nonzero .
We assign a weight hypergraph to any effective -action on any compact connected complex manifold satisfying Assumption 4.15, as follows. (Compare with [gu-za-01g], [ba-14].)
Construction 4.20** (Weight hypergraph of an algebraic torus action, compare with [ba-14]).**
Let be the (finite by compactness of ) set of all elements represented by a weight at some -fixed point of the -action on . Put
[TABLE]
Here we regard as a finite multiset (due to compactness of ). Notice that is a connected hypergraph. Denote the submanifold of corresponding to a hyperedge by for any . For any let be any weight of the corresponding -action on at the fixed point (in general, is defined up to sign). Notice that is an axial function on . We call the (-type) weight hypergraph associated with the action of on .
In the following, we consider only the class of -actions such that the associated hypergraphs have neither loops, nor multiple hyperedges. This implies that for any associated hypergraph the multiset is a set.
Remark 4.21*.*
Let be a hyperedge of the associated weight hypergraph of the -action on . If is an edge (that is, ) of , then is uniquely defined by the -action on . In general, is defined for the -action on only up to a sign.
We define the connection on the weight hypergraph associated with the -action on by following the construction from [gu-za-01], as follows.
Construction 4.22** (Connection on a weight hypergraph of an algebraic torus action).**
Let be any edge. Consider any -invariant rational curve of with different fixed points . Let and . Let , be the weights of the -action on at fixed points , respectively, where . Any complex vector bundle over splits equivariantly into the direct sum
[TABLE]
of -equivariant complex line bundles over . Hence, there exist permutations of such that , . We put for any . One can check that the collection , is a connection on the weight hypergraph .
Remark 4.23*.*
In general, a connection on a weight graph, associated with a torus action on a complex manifold, is not unique, because there is freedom in choosing the permutations from Construction 4.22, see Example 5.10 below. However, if an associated weight graph is definite, then it uniquely determines a connection on it.
4.3. GKM-graph of a nonsingular projective toric variety
Let be a nonsingular projective toric variety of dimension . The weight graph and the connection associated with the natural -action on coincide with the associated GKM-graph (with the natural connection) which is given as follows [gu-za-01]. The graph is the edge graph of the simple moment polytope of , where (see [bu-pa-15]). For any edge of the vector is emanating from to being parallel to the corresponding edge of the polytope . The axial function is -independent, because is a simple polytope. Hence the weight graph admits a unique connection.
The faces of the graph with the connection are described by the following lemma.
Lemma 4.24**.**
[bu-pa-15, Lemma 7.9.7, p.306]* For any , any integer and any distinct elements there exists a unique -face of containing . In particular, is the edge graph of a polytopal face of the moment polytope of .*
It is straight-forward to deduce the following lemma from convexity of faces for the moment polytope .
Lemma 4.25**.**
Let be a face of the moment polytope of . If are connected by an edge of the polytope , then . In particular, for any two faces of the edge graph of if then .
Proposition 4.26**.**
Let be any face of the GKM-graph of . Let be any edge path in . Then one has
[TABLE]
If , then the well-defined (by (26)) restriction of the monodromy map to is the identity map.
Proof.
By Lemma 4.24, for any there exists a unique -face of such that and . Let . Then there exists a unique edge such that . We conclude that , because is invariant. In particular, if , then . This completes the proof of the proposition. ∎
Let be any monomorphism of tori. Suppose that Assumption 4.15 holds for the induced -action on the toric variety . Then the weight hypergraph associated with this -action on is well-defined.
Remark 4.27*.*
Any -invariant submanifold of is -invariant. The opposite is false. For example, the Milnor hypersurface is invariant under the restriction of the action of the respective algebraic subtorus in . However, for any integers the hypersurface is not invariant under the natural -action on , see (11).
Proposition 4.28**.**
Let . Then one has , and any -invariant rational irreducible curve of is -invariant. In particular, one has for any vertex of .
Proof.
The inclusion holds, because any -invariant submanifold of is -invariant. To prove the first claim, it remains to note that the integers are equal to the Euler characteristic of (see [gu-10]). Let be the homomorphism of character lattices corresponding to the monomorphism of tori. Let . Any -invariant irreducible rational curve of has the form for some weight at . Let be such a curve. Clearly, is -invariant. Hence, , where is the -invariant submanifold of . The submanifold is a rational irreducible curve, because . Hence, . This proves the second claim of the proposition. ∎
5. Algebraic torus actions on , , and proofs of Theorems 1.2, 1.3
Throughout this section we refer to some auxiliary results from Appendix A.
5.1. Generalised Buchstaber-Ray hypersurface
Let us start by recalling the description of -fixed points in the bounded flag manifold . For any and any put
[TABLE]
For any let be a unique integer such that holds. Let
[TABLE]
where is the line spanned by -th vector of the standard basis in , (see §3.1). The following two lemmas are straight-forward to prove.
Lemma 5.1**.**
For any and any integer one has the identity
[TABLE]
Lemma 5.2** ([bu-ra-98],[bu-pa-15]).**
One has .
For any let . Clearly, is an affine subvariety of , where is the tuple of homogeneous coordinates on (see §3.1). Hence, is -invariant with respect to the action (15) for any . It is easy to deduce the following lemma by the induction on from the equations (14).
Lemma 5.3**.**
For any the invariant affine subvariety of the toric variety is equivariantly isomorphic to with the -action (23) under the following isomorphism
[TABLE]
Recall that the projective space is covered by its open subvarieties , , where . These subvarieties are invariant under the standard -action (10) on . Any -invariant irreducible rational curve of has the form , where are any integers such that . For any vectors and any let
[TABLE]
Under the action (15) any -invariant irreducible rational curve of has the form
[TABLE]
where and are arbitrary. Here has all zero coordinates besides -th coordinate that is equal to . The following proposition is easily deduced from Lemma 5.3.
Proposition 5.4**.**
For any the weights of the -action (15) on at the fixed point are , where runs over .
For any integers such that , the formula
[TABLE]
determines a unique effective action of the algebraic torus on hypersurface in the coordinates of . This follows easily from (16) together with the relations (14) on the tuple of homogeneous coordinates on . The hypersurface is an invariant subvariety of with respect to the action (27) of the algebraic subtorus in . Hence, the fixed point set of the -action (27) on is the subset of fixed points of the toric variety . It can easily be checked that consists of the points for any and any such that holds. It follows that the open covering of by the open -invariant subvarieties , where , are any elements such that , satisfies the Assumption 4.15.
Denote the combinatorial equivalence class of the standard simplex in by . Let be the Cartesian product of copies of .
Proposition 5.5**.**
* For any integers such that the variety is a projective toric variety which is an algebraic -bundle over . Its moment polytope is combinatorially equivalent to ;*
* For any integer , the variety is a projective toric variety whose moment polytope is combinatorially equivalent to . In particular, is a Bott tower;*
* For any integer , the variety is a projective toric variety whose moment polytope is combinatorially equivalent to the truncation of at its face (see [bu-pa-15]).*
Proof.
For the proof of see [bu-ra-98] or [bu-pa-15, p.350]. The claim follows from the Definition 3.2. By Theorem A.4, the variety is the blow-up of along the zero locus , which is invariant under the action (27) and is isomorphic to . Hence, the blow-up is -equivariant. In particular, is a projective toric variety and the respective moment polytope is obtained by the truncation indicated above. ∎
Notice that the fan of any projective nonsingular toric variety is the normal fan of the respective moment polytope.
Remark 5.6*.*
By Proposition A.1 , the blow-up is -equivariant, where is a toric surface. By Theorem A.4, the blow-up is also -equivariant. The two -actions on obtained in this way coincide. Let be the fan in corresponding to the toric variety . It is easy to show that the generators of the one-dimensional cones from are the columns of the following matrix
[TABLE]
For any integer and any denote by the vector . For any integers and any denote by the vector . It is easy to prove the following two propositions.
Proposition 5.7**.**
Let be any integers such that . Then for any and any such that the weights of the -action (27) on at the fixed point are the elements of the multiset
[TABLE]
Remark 5.8*.*
If , then . If , then , where . This justifies the exclusion in (28).
Proposition 5.9**.**
Let , be any elements such that . Then the multiset of collections of pairwise proportional weights of the -action (27) on at consists of the multiset of the (unordered) pairs of weights, where and are any integers satisfying the following conditions
[TABLE]
The -invariant subvariety of corresponding to the weight (see Section 4) is . One has .
The following example shows that the -dimensional variety has a fixed point of the -action (27) whose weights are linearly dependent.
Example 5.10*.*
The weights of the -action (27) on at the fixed points , , , are the respective collections of vectors in given as follows.
- •
, , , ;
- •
, , , ;
- •
, , , ;
- •
, , , .
For any integers such that , let be the weight hypergraph associated with the -action (27) on (notice that the Assumption 4.15 is satisfied for such an action).
Proposition 5.11**.**
Let be any integers such that . Let and be arbitrary. Then:
* For any integer satisfying , the hypergraph has a pointed hyperedge such that and ;*
* For any integer satisfying , the hypergraph has a pointed hyperedge such that and ;*
* If there exist integers and satisfying and , then the hypergraph has a pointed hyperedge such that and .*
Proof.
It is not hard to prove that any of the following irreducible rational curves
[TABLE]
[TABLE]
[TABLE]
of is invariant under the induced effective action of the one-dimensional algebraic torus from the -action (27) on . For any of these curves the corresponding weight given above is determined up to multiplication by . This completes the proof. ∎
One can obtain the hypergraph from Propositions 5.9 and 5.11. The axial function can be computed from Propositions 5.7 and 5.11. Let be a connection on associated with the action (27). We compute the values of that are necessary for the proof of Theorem 1.2 in the following proposition.
Proposition 5.12**.**
Let be any integers such that . Let be any vector such that holds. Then for any integers satisfying , the hypergraph has the definite oriented edge . The connection is well defined at , and one has the following identities
[TABLE]
where and are any integers such that and .
Proof.
By Proposition 5.9, the collection of weights at , as well as at , is -independent, because . Hence, by Proposition 5.11 there exists the edge in the hypergraph . By Proposition 5.7 this edge is definite and belongs to the graph . In order to prove the identities from the claim of the proposition we compute the congruences modulo between the weights (in particular, vectors in ) in Fig. 2. During the computation we use the identity for any integer which holds, because . ∎
Proof of Theorem 1.2.
For any integers which do not satisfy , the claim of the theorem follows from Proposition 5.5. Let be any integers such that . Suppose that is a toric variety. The idea of the following argument is to find an invariant -face in with a nontrivial action of the monodromy map along it on the external edges. By Proposition 5.12, for any integer the vertex of belongs to . Hence, the edge path belongs to for any integer . This implies that the monodromy map is well defined for any . By Proposition 5.12, the subgraph is a -face of for any integer . By Proposition 5.12, we compute with respect to the connection as follows.
[TABLE]
Hence,
[TABLE]
It follows from the assumption and Corollary 2.4 that there exists the extension of the -action (27) on to the toric action with the GKM-graph with the connection . By Proposition 4.28, is the subgraph of for any . Since the edges of are definite in , one has . In particular, (29) holds with respect to . However, this contradicts Proposition 4.26. The proof is complete. ∎
5.2. Ray hypersurface
In this paragraph we use the notation introduced in §5.1. For any integers such that , the formula
[TABLE]
determines a unique effective action of the algebraic torus on the hypersurface . This follows from the relations (14) on the homogeneous coordinates on . The hypersurface is an invariant subvariety of with respect to the action (30) of the algebraic subtorus in . Hence, the fixed point set of the -action (30) on is the subset of . It can easily be checked that consists of the points for any and any such that . It follows that the open covering of by the open -invariant subvarieties , where , are any elements such that , satisfies the Assumption 4.15.
Corollary 5.13**.**
Let be any integer.
* The variety is a projective toric variety whose moment polytope is combinatorially equivalent to . In particular, is a Bott tower;*
* The variety is a projective toric variety whose moment polytope is combinatorially equivalent to the truncation of at its face ;*
* The variety is a projective toric variety whose moment polytope is combinatorially equivalent to the truncation of at its edge.*
Proof.
Parts and follow from Proposition 5.5, because , . Now we prove part . By Theorem A.10 , there is the algebraic -bundle . This algebraic fiber bundle is represented as the fibered product for some principal algebraic -bundle over . The equivariant blow-up from Remark 5.6, where we identify , induces the -equivariant morphism
[TABLE]
by acting on the fibers. The fan of the toric -bundle is the normal fan of the polytope in combinatorially equivalent to the cube . The columns of the following matrix
[TABLE]
are the generators of the one-dimensional cones for its fan, see [so-17]. Hence, the fan of is the normal fan of the polytope in combinatorially equivalent to edge truncation of the cube . The columns of the following matrix
[TABLE]
are the generators of the one-dimensional cones for its fan. We remark that the last column in the above matrix corresponds to the truncation facet. This completes the proof. ∎
Remark 5.14*.*
The fan of the toric -bundle is obtained from the fan of the toric -bundle in a similar way as in the proof of Corollary 5.13. The corresponding map of fibers is the composition of the -equivariant blow-up from Remark 5.6 and the -equivariant blow-up at any fixed point. Hence, the columns of the following matrix
[TABLE]
are the generators of the one-dimensional cones for the fan of . We remark that the last column in the above matrix corresponds to the truncation facet of .
For any integer and any denote by the vector . For any integer and any denote by the vector . It is easy to prove the following two propositions.
Proposition 5.15**.**
Let be any integers such that . Then for any and any such that , the weights of the -action (30) on at the fixed point are the elements of the following multiset
[TABLE]
Remark 5.16*.*
If , then , where . If , then , where . This justifies the exclusion in (31).
Proposition 5.17**.**
Let be any integers such that . Let , be any vectors satisfying . Then the multiset of collections of pairwise proportional weights of the -action 30 on at consists of the (unordered) pairs of weights, where and are any integers satisfying the following conditions
[TABLE]
The -invariant subvariety of corresponding to the weight (see Section 4) is . One has .
For any integers such that , let be the weight hypergraph associated with the -action (30) on (notice that the Assumption 4.15 is satisfied for such an action).
Corollary 5.18**.**
Let be any integers such that . Then , , .
Proof.
Let . To prove the first claim of the corollary it is enough to check that the condition (32) fails for . Following the notation introduced in Proposition 5.17, if , then , so (32) does not hold. If , then , so the condition (32) is not satisfied. If , then
[TABLE]
Hence, the condition (32) is not satisfied in this case, as well. The proof of the second claim from the corollary is obtained by substituting for in the above proof, respectively. Now let . If , then , and (32) fails. If , then , and (32) fails. Let , so that . Then for any one has , and (32) fails. The proof is complete. ∎
Proposition 5.19**.**
Let be any integers such that . Let , be any elements. Then:
* For any integer satisfying , the hypergraph has a pointed hyperedge such that , and ;*
* For any integer satisfying , the hypergraph has a pointed hyperedge such that , and ;*
* If there exist integers and satisfying and , then the hypergraph has a pointed hyperedge such that , and .*
Proof.
It is easy to prove that any of the following irreducible rational curves
[TABLE]
[TABLE]
[TABLE]
of is invariant under the induced effective action of the one-dimensional algebraic torus from the -action (30) on . For any of these curves the corresponding weight given above is determined up to multiplication by . This completes the proof. ∎
Remark 5.20*.*
The condition from the third case of Proposition 5.19 holds iff the numbers , belong to the images of the functions , , where runs over and runs over , respectively. If this condition holds, then the number of the weights from first two cases in Proposition 5.19 is equal to , otherwise this number is equal to .
One can obtain the hypergraph from Propositions 5.17 and 5.19. The axial function can be computed from Propositions 5.15 and 5.19. Let be a connection on associated the action (30). In the following proposition we compute the values of that are necessary for the proof of Theorem 1.3.
Proposition 5.21**.**
Let be any integers such that holds. Then the graph has the definite oriented edges , and the following identities hold.
[TABLE]
where and are any integers such that ; , and ;
[TABLE]
where and are any integers such that ; , and ;
[TABLE]
[TABLE]
where and are any integers such that ; , and ;
[TABLE]
[TABLE]
where and are any integers such that ; , and .
Proof.
Notice that the edge from any of the four cases from the proposition has vertex for some such that . By Proposition 5.15, -linear independence of weights now follows from definiteness of . To prove the identities from the claim of the proposition we deduce the congruences between the weights of given in Fig. 4. (Here we follow the notation introduced in the proof of Proposition 5.12). ∎
Proof of Theorem 1.3.
For any integers such that or , the claim of the theorem holds by Corollary 5.13. Let be any integers that satisfy neither of these conditions. Without loss of generality, we prove the claim for the case only, because . Suppose that is a toric variety. The idea of the following argument is to find a -face in with nontrivial action of the monodromy map on the external edges to along some loops in . By Proposition 5.17, for any the vertex belongs to , because holds for any . Hence, one has . By Corollary 5.18, one has . We conclude that the connection on is well defined along the edges of the edge path as well as along the oriented edge of .
It follows from the assumption and Corollary 2.4 that there exists an extension of the -action (30) on to a toric action with the GKM-graph and the connection . Let be any vertex of or of the oriented edge . By Proposition 4.28, one has . In particular, is a subgraph of . By Proposition 5.21, the subgraph is invariant in . The connections , coincide along the edges of as well as along the edge of due to definiteness of at these edges. By Lemma 4.24, there exists a unique -face of with respect to such that contains the edges . In particular, and . By Lemma 4.25, this implies that the vertex of does not belong to . On the other hand, by Proposition 5.21, the edges
[TABLE]
[TABLE]
belong to . Hence, belongs to . This contradiction proves the theorem. ∎
6. Acknowledgements
The author expresses his gratitude to V.M. Buchstaber and T.E. Panov for the proposal of problems studied here, many fruitful discussions and constant support while writing this paper. Special thanks are to I. Arzhantsev, who spotted an error in the early version of the text. It is pleasure to acknowledge several important discussions with A. Ayzenberg and C. Shramov.
Appendix A Descriptions of and in terms of blow-ups and fiber bundles
Here is the list of main results of this section. In Proposition A.1, for any integers we prove that the variety is obtained from by the sequence of blow-ups along strict transforms of the subvarieties of which are isomorphic to , where runs over . In Theorem A.4, for any integers we prove that is the blow-up of along the subvariety isomorphic to . We also find two similar descriptions for Ray hypersurfaces in terms of blow-ups in Proposition A.6 and Theorem A.9. We find the structures of algebraic fiber bundles on generalised Buchstaber-Ray and Ray hypersurfaces in Theorems A.5 and A.10, respectively. Throughout of this section we use the notions introduced in Section 3.
A.1. Generalised Buchstaber-Ray hypersurface
Let be any integers. Let be the homogeneous coordinates of . Denote the subvariety in by for any .
Proposition A.1**.**
* The divisor in corresponds to the algebraic line bundle over ;*
* For any , two subvarieties and (see Definition 2.5) intersect transversally in . The subvariety of is isomorphic to .*
* The variety is a strict transform of under the sequence of consecutive blow-ups of along strict transforms of the subvarieties in , where runs over . In particular, is the nonsingular variety that is obtained from by blow-ups with nonsingular centres.*
Proof.
Under the natural embedding the restriction of the homogeneous coordinate to is the global section of the sheaf over . Hence, the left-hand side of the equation (16) is a global section of the sheaf over . This proves .
Consider the isomorphism
[TABLE]
Under this isomorphism, maps isomorphically to the hypersurface . We compute the dimensions as follows.
[TABLE]
We obtain
[TABLE]
which proves . The projection
[TABLE]
decomposes into a sequence of blow-ups along strict transforms of , where runs over . The subvarieties and intersect transversally in by for any . Hence, the argument from [gr-ha-78, pp. 604–605] applies. Therefore, the restriction of the projection (33) to decomposes into a sequence of blow-ups of . This proves . ∎
Remark A.2*.*
The arrangement in is a simple instance of a building set in terminology of [li-09], because the elements of this arrangement form a chain of embeddings of submanifolds in . The wonderful compactification of this arrangement is isomorphic to the iterated blow-up of , where runs over . This can be seen either directly from the embedding of a blow-up to the Cartesian product, or from [li-09, Theorem 1.3, p.537]. Comparing this with Proposition A.1 , one obtains that is a wonderful compactification. The embedding of obtained from wonderful compactification is to , where the blow-up centres are described by Proposition A.1 . In this paper we utilize the different embedding .
Remark A.3*.*
The projective toric variety is a Bott tower (see [bu-ra-98] or [so-17, p.769, Proposition 9]). One can easily compute the fan in of the toric variety by following the general description of the fan for any Bott tower (see [bu-pa-15, p.290, Corollary 7.8.7]). The columns of the following matrix
[TABLE]
are the generators of the respective one-dimensional cones of . The three-dimensional cones of are
[TABLE]
Let be any integers. Denote by the subvariety in consisting of all points such that and hold. Each of the conditions and is equivalent to the condition . Therefore, holds for any point from . In particular, . Denote the natural embedding from Definition 3.2 by . Consider the projection
[TABLE]
Consider the embedding induced by the identity map on and by the embedding given by .
Theorem A.4**.**
* The normal bundle of the embedding is ;*
* The morphism is the blow-up of along with the exceptional divisor ;*
* The exceptional divisor is the total space of the algebraic fiber bundle .*
Proof.
The normal bundle of the embedding is isomorphic to . The normal bundle of the embedding is by Proposition A.1 . This proves . The subvariety of is given by the equations , where
[TABLE]
are global sections of the algebraic line bundles and over , respectively. The regular morphism is an isomorphism outside the zero locus . The restriction of the morphism to the preimage of is . Since this projective bundle is isomorphic to the projectivisation of the normal bundle of in by basic property of a blow-up, we conclude that is the required blow-up. Hence, is the exceptional divisor of the blow-up . This proves and . ∎
Theorem A.5**.**
* Let be any integers such that . Then the morphism*
[TABLE]
is an algebraic -bundle;
* Let be any integer. Then the morphism*
[TABLE]
is an algebraic -bundle.
Proof.
We prove the claims of this theorem by constructing the trivialisations for the corresponding algebraic fiber bundles. Let . Recall that any is determined by the tuple of the homogeneous coordinates. Let be the open subvariety of , where . For any there exists a unique morphism such that
- •
is a -linear map for any ;
- •
takes to , and takes to , respectively, for any ;
- •
the following (well-defined) conditions (where is a tuple of homogeneous coordinates) hold:
[TABLE]
The desired trivialisation for the fiber bundle is
[TABLE]
Let be the tuple of homogeneous coordinates of any . Let be the open subvariety of , where . For any let be a morphism such that for any the -linear map takes to and takes to , respectively. Furthermore, for any there exists a unique satisfying the well-defined conditions
[TABLE]
The desired trivialisation for the fiber bundle is
[TABLE]
∎
A.2. Ray variety
Let be any integers. Denote the subvariety in by for any . The proof of the following proposition is similar to the proof of Proposition A.1.
Proposition A.6**.**
* The divisor corresponds to the algebraic line bundle over ;*
* For any , two subvarieties and intersect transversally in . The subvariety of is isomorphic to .*
* The variety is a strict transform of under the sequence of consecutive blow-ups of along strict transforms of the subvarieties in , where runs over . In particular, is the nonsingular projective variety that is obtained from by blow-ups with nonsingular centres.*
Remark A.7*.*
The arrangement in is also a building set in terminology of [li-09], because the elements of this arrangement form a chain of embeddings of submanifolds in . The wonderful compactification of this arrangement is isomorphic to the iterated blow-up of , where runs over . This can be seen either directly from the embedding of a blow-up to the Cartesian product, or from [li-09, Theorem 1.3, p.537]. Comparing this with Proposition A.6 , one obtains that is a wonderful compactification. The embedding of obtained from wonderful compactification is to , where the blow-up centres are described by Proposition A.6 . In this paper we utilize the different embedding .
Let be any integers. Denote by , , the subvarieties in consisting of all points such that and hold; and hold; and hold, respectively. It is straight-forward to prove the following lemma.
Lemma A.8**.**
One has , where are nonsingular irreducible hypersurfaces of . The intersection is isomorphic to .
Denote by the natural embedding from Definition 3.4. Consider the following morphisms
[TABLE]
[TABLE]
[TABLE]
[TABLE]
The proof of the following theorem is similar to the proof of Theorem A.4
Theorem A.9**.**
* The normal bundles of the embeddings*
[TABLE]
are and , respectively;
* The morphisms and are the blow-ups along the centres and with exceptional divisors and , respectively;*
* The exceptional divisors and are the total spaces of the algebraic fiber bundles and , respectively.*
The proof of the following theorem is similar to the proof of Theorem A.5.
Theorem A.10**.**
* Let be any integers such that . Then the following morphism*
[TABLE]
is an algebraic -bundle.
* Let be any integer. Then the following morphisms*
[TABLE]
are algebraic fiber bundles with fibers and , respectively.
Appendix B Cohomology rings of and
In this section, we prove that the cohomology rings of the hypersurfaces and are isomorphic to the quotients of the known cohomology rings of the ambient varieties and by the annihilator ideals of the first Chern classes of the respective normal line bundles for any integers . We deduce the formulas for the Hodge-Deligne polynomials of the hypersurfaces and from the Hodge-Deligne polynomial of by using the blow-up descriptions of and from Section A. In particular, we compute all Betti numbers of and for any integers . In the following, by omitting the coefficient group in singular cohomology we assume -coefficients.
B.1. Cohomology ring of the blow-up of a complex manifold along a submanifold
Let be any holomorphic embedding of complex compact connected manifolds. Consider the blow-up of along . The exceptional divisor of is the holomorphic fiber bundle , where the projection map is given by the restriction of to , and is the normal bundle of . The restriction of the projection map to induces the structure of a -module on .
Theorem B.1** (Leray, Hirsch, see [bo-hi-58, §15]).**
Let be a complex vector bundle of rank over . Consider the fiberwise projectivisation of . Let be the first Chern class of the dual to the tautological line bundle over . Then the following rings
[TABLE]
are isomorphic. In particular, is a free -module with generators .
Example B.2*.*
By applying Theorem B.1 recurrently to the -bundle , one obtains an isomorphism
[TABLE]
of graded rings, where , see [bu-pa-15].
Let be any compact complex submanifold of which intersects transversally in .
Proposition B.3** ([gr-ha-78], [ha-ba-09]).**
The normal bundle of the hypersurface in is isomorphic to the tautological line bundle . The strict transform of under is isomorphic to . The following abelian groups
[TABLE]
are naturally isomorphic, where is the codimension of in . The ring is isomorphic to the quotient of the ring on the right hand side of (36) by the relations
[TABLE]
[TABLE]
where is Poincaré dual to the homology class , and restricts to .
B.2. Cohomology ring of a hypersurface
Let be any compact complex manifold with no torsion in . By the Poincaré duality, the -bilinear form ,
[TABLE]
given by the natural pairing with the fundamental class , is nondegenerate.
In addition, let be connected and simply connected. Then the group is isomorphic to the Picard group of equivalence classes of the holomorphic line bundles over modulo holomorphic isomorphisms. Let be any holomorphic line bundle. In the following, we assume that the divisor corresponding to is represented by an irreducible nonsingular hypersurface in . In this case, the homology class of in is Poincaré dual to . Consider the homomorphism induced by the natural embedding .
Proposition B.4**.**
Suppose that all odd cohomology groups vanish and that is an epimorphism. Then is the annihilator ideal of in the ring . In particular, the quotient homomorphism induced by is an isomorphism of rings.
Proof.
Since is an epimorphism, we conclude from that holds for any integer . The universal coefficients formula then implies that the groups , have no torsion. The class is Poincaré dual to . This means that the identity
[TABLE]
holds for any . For any elements of degree and , respectively, we deduce the following identities
[TABLE]
from (38). Let be any element of . Then the left hand side of (39) is zero. Hence, belongs to the kernel of the bilinear form . Then , because the bilinear form is nondegenerate. We conclude that .
Let be any element. Then the right-hand side of (39) is zero for any . We conclude from (39) that for any , because is epimorphic. Hence, belongs to the kernel of the bilinear form . We conclude that , because is nondegenerate. This implies that holds. The proof is complete. ∎
In general, the embedding of a hypersurface to the ambient manifold does not induce epimorphism of the respective cohomology groups.
Example B.5*.*
For any integers , let be the embedding of a generic hypersurface of degree to . One can check that for any even and any integer the group is nonzero and the homomorphism is not epimorhic. For and the Veronese embedding of the nonsingular quadric induces the homomorphism
[TABLE]
of the respective cohomology rings, which is clearly not onto. (The last example was pointed out to the author by A. Ayzenberg.)
Lemma B.6**.**
Let be complex vector bundles over a compact topological space . Suppose that is a subbundle of . Let be the corresponding embedding. Then the induced homomorphism is onto.
Proof.
Consider the tautological line bundles , of the respective projective fiber bundles. Let , . By Theorem B.1, the following free -modules
[TABLE]
are isomorphic, where , . By the definition, . Hence, . Now the statement follows from (40), because . ∎
Recall that is a submanifold and is a hypersurface in . Assume that and intersect transversally in . Then by Proposition B.3, the strict transform of with respect to the blow-up is isomorphic to . Let be the corresponding embedding.
Lemma B.7**.**
Suppose that the embeddings and induce epimorphisms of the respective cohomology rings. Then the embedding induces an epimorphism of the respective cohomology rings.
Proof.
Let be the exceptional divisor of the blow-up , where and are the normal bundles of the inclusions and , respectively. The normal vector bundle is a subbundle of due to the sequence of embeddings. Consider the following commutative diagram
[TABLE]
where the vertical arrows are the isomorphisms from Proposition B.3, and the lower arrow is induced by the embeddings and (by naturality). By the condition of the lemma, is epimorphic. By Lemma B.6 and the assumption, the composition , induced by the natural embeddings, is epimorphic. Then the lower arrow in (41) is epimorphic. By the commutativity of (41) we conclude that is epimorphic. This completes the proof. ∎
Let be any closed connected submanifolds of the complex manifold . Denote by the strict transform of the subvariety under the blow-up of along , where . We generalise Lemma B.7 as follows.
Lemma B.8**.**
* Assume that and intersect transversally in for any . Then and intersect transversally in , where ;*
* In addition to the condition , suppose that the embeddings and induce epimorphisms of the respective cohomology rings for any . Then the embeddings and induce epimorphisms of the respective cohomology rings for any .*
Proof.
The claim follows from Proposition B.3 immediately. Now we prove . The claim about follows by substituting for in Lemma B.7. The claim about follows by substituting for in Lemma B.7. ∎
See §3 for the definitions of , .
Theorem B.9**.**
* The embedding induces epimorphism in cohomology. One has the ring isomorphism*
[TABLE]
where .
* The embedding induces epimorphism in cohomology. One has the ring isomorphism*
[TABLE]
where .
Proof.
Propositions A.1, A.6 and Lemma B.8 imply that , are epimorphic. The respective kernels are given in Proposition B.4. It remains to compute the cohomology of the respective Cartesian products. This follows by Künneth formula from the computation of the cohomology rings of , (see (35)). ∎
Example B.10*.*
By Theorem A.9, is the blow-up of along . The normal bundle of the composition of embeddings is the restriction of to . The irreducible rational curve is obtained by taking subsequently the divisors corresponding to the algebraic line bundles , over . Hence, . Clearly, , where is the tautological line bundle and . It is not hard to compute the Chern class to be of . Hence, by Proposition B.3, one has
[TABLE]
Here we can vanish by expressing the additive generators and as and , respectively.
Example B.11*.*
It is not hard to compute the ideal of the ring to be
[TABLE]
Hence, by Theorem B.9, one has
[TABLE]
The isomorphism
[TABLE]
of polynomial rings induces the isomorphism between the quotient rings, which are given on the right hand sides of (43) and (42). A similar computation shows that
[TABLE]
B.3. Betti numbers
Consider the Hodge-Deligne polynomial of a quasiprojective complex algebraic variety (see [da-kh-87], [gu-10]).
Proposition B.12** ([da-kh-87, p.929]).**
* For any quasiprojective complex algebraic varieties one has*
[TABLE]
* For any integer one has ;*
* For any algebraic -bundle , where are nonsingular projective varieties, one has*
[TABLE]
* For any closed immersion of nonsingular projective algebraic varieties, the identity*
[TABLE]
holds, where is the complex codimension of .
For any complex projective manifold , the -th Betti number of is equal to by the Hodge decomposition, where is any integer. If has only diagonal Hodge numbers, i.e. for any , then we put , where .
Proposition B.13**.**
Let be any integers. Then the following relations hold.
[TABLE]
[TABLE]
[TABLE]
where and ;
[TABLE]
Proof.
By Proposition 5.5 the variety is the algebraic -bundle over for any integers such that and . The variety is the tower of algebraic -bundles over the point. Hence, by Proposition B.12 one obtains the formula (44) from the Hodge-Deligne polynomial of the projective space.
We prove (45) by the induction on . By Theorem A.4 , the variety is the blow-up of along its subvariety . Hence, by Proposition B.12,
[TABLE]
which proves the induction basis . Assume that (45) holds for . By Theorem A.4 , the variety is the blow-up of along its subvariety . We conduct the computation for by using the induction hypothesis and Proposition B.12 as follows.
[TABLE]
This proves the identity (45).
It is enough to prove (46) only for any integers such that , because . We prove (46) by the induction on . For , (46) follows from (45), since . Assume that (46) holds for . Let . By Theorem A.9 , the variety is the blow-up of along its subvariety . We conduct the computation for by using the induction hypothesis and Proposition B.12 as follows.
[TABLE]
This proves the identity (46).
Finally, prove (47) by the induction on . Note that is the blow-up of along its subvariety . By Proposition B.12, then one has the identity
[TABLE]
which proves the induction basis . Assume that (47) holds for . By Theorem A.9 , the variety is the blow-up of along its subvariety .We conduct the computation for by using the induction hypothesis and Proposition B.12 as follows.
[TABLE]
The proof is complete. ∎
Corollary B.14**.**
Let be any integers. Then one has the following formulas.
[TABLE]
[TABLE]
[TABLE]
Remark B.15*.*
The identities from Proposition B.13 agree with the various algebraic fiber bundle structures on and from Section A and the property of Hodge-Deligne polynomial from Proposition B.12 .
The reference list from the paper itself. Each links out to its DOI / PubMed record.
- 1[ \resetbiblist 99] \bibselect biblio_Ar MJ
