Subcanonicity of Codimension Two
Subvarieties

Enrique ARRONDO

Departamento de Álgebra

Facultad de Ciencias Matemáticas

Universidad Complutense de Madrid

28040 Madrid, Spain

Enrique Arrondo@mat.ucm.es

Recibido: 5 de Febrero de 2004
Aceptado: 3 de Junio de 2004

ABSTRACT

We prove that smooth subvarieties of codimension two in Grassmannians of lines
of dimension at least six are rationally numerically subcanonical. We prove the
same result for smooth quadrics of dimension at least six under some extra con-
dition. The method is quite easy, and only uses Serre’s construction, Porteous
formula and Hodge index theorem.

Key words: subcanonicity, codimension two, Grassmannians, quadrics.

2000 Mathematics Subject Classification: 14M07.

Introduction

The main open problem about (complex) subvarieties of small codimension is Hart-
shorne’s conjecture. In the particular case of codimension two, it states that any
(smooth) subvariety of codimension two X ⊂ Pn must be a complete intersection if
n ≥ 6 (although the original conjecture stated n > 6). In [6], Larsen has shown (in a
more general framework) that, in these hypotheses, the restriction map H2(Pn, Z) →
H2(X, Z) is an isomorphism, which implies that X must be subcanonical (previously,
Barth had proved in [1] the same result with rational coefficients).

Partial support for this paper came from the Research Project BFM2000-0621 from the Spanish
Ministry of Science and Technology, as well as from the “Acción Integrada” HI00-128 supported by
Spain and Italy.

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Enrique Arrondo Subcanonicity of codimension two subvarieties

We are interested in the same problem when changing Pn with a Grassmannian or
a quadric. The interesting case is when the ambient space has dimension six, so that
we will focus our attention on G(1, 4), the Grassmann variety of lines in P4, and Q6,
the smooth six-dimensional quadric.

Since on G(1, 4) the universal quotient bundle has rank two, we cannot expect
that smooth subvarieties of codimension two are complete intersections, although I
conjecture that the only other possibility for such a subvariety is to be the zero-locus
of a section of a twist of the universal bundle. The only result in this direction is a
generalization of Larsen’s result for Grassmannians of higher dimension: for a smooth
subvariety X ⊂ G(1, n) of codimension two the restriction map H2(G(1, n), Z) →
H2(X, Z) is an isomorphism for n ≥ 6 (see [2, Theorem 2] for the case n ≥ 7 and [8]
in general). In particular, such X is subcanonical.

On the other hand, Q6 contains the Segre embedding of P1 × P3, which is neither
a complete intersection nor even subcanonical; I conjecture however that this is the
only codimension two subvariety that is not a complete intersection. For higher
dimensional quadrics Qn (n ≥ 7), [3, Theorem 2.3.11] (or Larsen result for arbitrary
codimension) implies that any X ⊂ Qn of codimension two is subcanonical.

In this paper we will improve partially the result of Barth and van de Ven by prov-
ing that a smooth subvariety X ⊂ G(1, 4) of codimension two is rationally numerically
subcanonical, i.e. the canonical divisor of X is numerically a rational multiple of the
hyperplane section. We will prove the same result for subvarieties of Q6 but adding an
extra numerical condition (obviously some condition was required in order to exclude
the counterexample).

The method we will use is very simple and it is implicitly in the literature (see
for instance [4]). The idea is to use Serre’s construction to regard our variety X as
the dependency locus of r − 1 sections of a vector bundle of rank r on the ambient
space. The fact that X is smooth implies that the locus in which these sections have
rank r − 3 is empty, and this will imply numerically that the surface section of X is
rationally numerically equivalent to zero. Our results will thus come from Lefschetz
hyperplane theorem. These results provide an evidence for the above conjectures, and
I hope that this paper will encourage people to work in this direction.

In a first section we will illustrate how the method works in the known case of
subvarieties of Pn. In the second section we will prove the result for G(1, 4) and
G(1, 5), while the third section will be devoted for the proof in Qn. We end with a
last section of remarks and conjectures.

1. Subvarieties of projective space

In this section we will see how to prove in a simple way the following corollary of a
theorem of Barth and Larsen. This will be the method that we will follow in the rest
of the paper when substituting Pn with a Grassmannian of lines or a smooth quadric.

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Enrique Arrondo Subcanonicity of codimension two subvarieties

Proposition 1.1. Let X ⊂ Pn be a smooth subvariety of codimension two. If n ≥ 6,
then X is rationally numerically subcanonical.

Proof. We consider S ⊂ P4 to be the surface obtained as the intersection of X with
a general P4 ⊂ Pn. Since S is smooth, we have the relation coming from the double
point formula:

K2
S =

d2

2
− 5

2
d− 5g + 5 + 6χ(OS). (1)

Here KS is the canonical divisor, d is the degree of S (and hence the degree of X)
and g is the sectional genus of both S and X.

On the other hand, from Serre’s construction, we can obtain X as the dependency
locus of r − 1 sections of a rank r vector bundle F over Pn (Hartshorne’s conjecture
is equivalent to say that it is possible to take r = 2 and that F splits). As usual, we
identify the i-th Chern class of F with an integer ci, in the sense that ci(F ) = ciH

i,
where H is the hyperplane class of Pn. We have in particular a Koszul exact sequence

0 → O⊕r−1
Pn → F → OPn(c1) → OX(c1) → 0. (2)

Restricting the above exact sequence to a general P4 and using Riemann-Roch
Theorem we can compute the Hilbert polynomial χ(OS(l)) in terms of c1, c2, c3, c4.
Identifying the coefficients of this polynomial with the standard Hilbert polynomial
of a surface, we get the relations:

c2 = d,

c3 = −c1d + 4d + 2g − 2,

c4 =
1
2
d2 +

25
2

d + 15g − 15 + dc2
1 − 8c1d− 4c1g + 4c1 + 6χ(OS).

And now the tricky —but simple— part comes. Since the locus X in which the
map O⊕r−1

Pn → F of (2) has rank at most r−2 is smooth, this map cannot have points
in which the rank is less than or equal to r − 3. This means that the corresponding
Porteous cycle must be zero in the degree six part of the Chow ring of Pn. By Porteous
formula, this means that c2

3 − c2c4 = 0. After making the above substitutions for
c2, c3, c4, we first see that this equality does not depend on c1. But on the other
hand, it surprisingly becomes the identity (KSHS)2 − K2

SH2
S = 0 when using (1).

Therefore, the Hodge index theorem implies that KS − qHS is numerically equivalent
to zero for some rational number q. On the other hand, the Lefschetz hyperplane
theorem implies that the restriction map H2(X, Q) → H2(S, Q) is injective. We have
just seen that the image of the class of KX + (−q + n − 4)HX is zero (recall that
KS = (KX +(n−4)HX)|S by the adjunction formula). Therefore, KX is numerically
equivalent to (q − n + 4)HX , as wanted.

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Enrique Arrondo Subcanonicity of codimension two subvarieties

2. Subvarieties of Grassmannians of lines

We prove here the analogue of Proposition 1.1 for Grassmannians of lines. We study
first the case in which the Grassmannian has dimension six, i.e. G(1, 4), the Grass-
mannian of lines in P4.

Theorem 2.1. Any smooth subvariety X ⊂ G(1, 4) of codimension two is rationally
numerically subcanonical.

Proof. We imitate the proof of Proposition 1.1 for the projective case, but we need to
have in mind that there are several natural choices of surfaces inside X, not only linear
sections. First of all, recall that the Chow group of degree two of G(1, 4) is generated
by two elements: the Schubert cycle Ω(1, 4) of all the lines meeting a fixed line of P4,
and the Schubert cycle Ω(2, 3) of all the lines contained in a fixed hyperplane of P4.
Therefore X has a bidegree (a, b), where a is the number of lines of X contained in a
hyperplane H ⊂ P4 and passing through a point p ∈ H, and b is the number of lines
of X contained in a plane of P4. We can therefore consider the following surfaces
of X:

• A general linear section S, which will have, as a surface in the Plücker ambient
space, degree 3a + 2b. We will denote by g its sectional genus. By adjunction
formula, we have KS = (KX + 2HX)|S .

• A surface S1 ⊂ G(1, 3), consisting of the set of lines of X contained in a general
hyperplane H ⊂ P4 (we will identify this hyperplane with P3). As a surface in
G(1, 3), it has bidegree (a, b) (a being the number of lines of S1 passing through
a given point of P3, and b being the number of lines of S1 contained in a given
plane of P3). Its degree as a projective surface is a + b, and we will denote with
g1 its sectional genus. This surface is obtained from X as the zero locus of the
restriction to X of the section of Q (universal quotient bundle of G(1, 4) of rank
two) defining H. Therefore, KS1 = (KX + HX)|S1 .

• A surface S2 consisting of the set of lines of X meeting a general given line
of P4.

The adjunction properties of the two first surfaces makes reasonable to write all
the invariants in terms of the invariants of S and S1. It will be useful for this purpose
to observe that a special linear section S —namely the set of lines meeting two planes
Π1, Π2 meeting along a line L— splits as S1 ∪S2, the intersection of S1 and S2 being
the curve C1 of lines meeting the line L and contained in the hyperplane spanned by
Π1 and Π2. The curve C1 is hence a hyperplane section of S1.

To obtain the double point formulas for S and S1, it is enough to multiply the
self-intersection formula c2(N) = aΩ(1, 4)|X + bΩ(2, 3)|X (N being the normal bundle

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Enrique Arrondo Subcanonicity of codimension two subvarieties

of X in G(1, 4)) with H2
X and Ω(1, 4)|X respectively. We obtain thus

K2
S = a2 + ab +

1
2
b2 − 2a− 3

2
b− 3g + 3 + 6χ(OS), (3)

K2
S1

=
1
2
a2 +

1
2
b2 − 3

2
a− 3

2
b− 4g1 + 4 + 6χ(OS1). (4)

On the other hand we write X as the dependency locus of r−1 sections of a vector
bundle F of rank r over G(1, 4). We represent the first four Chern classes of F by
integers as follows:

• c1(F ) = c1Ω(2, 4), where Ω(2, 4) is the Schubert cycle of all the lines meeting a
given plane, i.e. the hyperplane class H of G(2, 4).

• c2(F ) = c21Ω(1, 4) + c22Ω(2, 3).

• c3(F ) = c31Ω(0, 4) + c32Ω(1, 3), where Ω(0, 4) is the Schubert cycle of lines
passing through a point, and Ω(1, 3) is the Schubert cycle of lines meeting a line
L and contained in a hyperplane H ⊃ L.

• c4(F ) = c41Ω(0, 3) + c42Ω(1, 2), where Ω(0, 3) is the Schubert cycle of lines
contained in a hyperplane and passing through a point of it, and Ω(1, 2) is the
Schubert cycle of lines contained in a plane.

Restricting the exact sequence 0 → O⊕r−1
G(1,4) → F → OG(1,4)(c1) → OX(c1) → 0

to the intersection of two hyperplanes of G(1, 4) and to a Schubert cycle Ω(2, 3) and
computing in this way the Hilbert polynomials of S and S1 we get relations:

c21 = a,

c22 = b,

c31 = −2b− c1a + 2g − 4g1 + 2,

c32 = 3a + 3b− c1b− c1a + 2g1 − 2,

c41 =
a2

2
+ ab +

a

2
− 2b− 6c1a− 2c1b + 2c2

1a + c2
1b + 9g − 12g1,

c42 =
a2

2
+

b2

2
+

13
2

a +
13
2

b− 6c1a− 6c1b + c2
1a + c2

1b + 12g1.

Using these expressions, the equality c3(F )2 − c2(F )c4(F ) = 0 becomes

− a3

2
− 3

2
a2b− b3

2
+

17
2

a2 +
27
2

ab +
13
2

b2 − 15a− 8b

− 9ag − 8bg + 24ag1 + 16bg1 + 4g2 − 16g1g + 20g2
1 + 8g − 24g1 + 8

+ 6aχ(OS1)− 6bχ(OS1)− 6aχ(OS) = 0. (5)

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Enrique Arrondo Subcanonicity of codimension two subvarieties

We are not as lucky as in the proof of Proposition 1.1, since this time equality (5)
is not the Hodge inequality for S. Our strategy now is to use Hodge index theorem
for S1 and S2 but, instead of using their respective canonical divisors, using the
restriction to them of the canonical divisor of X (this does not make any difference
for S1, because it is subcanonical, but for S2 there is a crucial difference). We thus
have that ((KX)|S1HS1)

2 − ((KX)|S1)
2(HS1)

2 ≥ 0 becomes

− a3

2
− 1

2
a2b− 1

2
b2a− b3

2
+

5
2
a2 + 5ab +

5
2
b2 + 4g2

1 − 8g1 + 4

− 6aχ(OS1)− 6bχ(OS1) ≥ 0, (6)

while ((KX)|S2HS2)
2 − ((KX)|S2)

2(HS2)
2 ≥ 0 becomes

− a3 − 5
2
a2b− ab2 + 8a2 +

19
2

ab + 3b2 − 6a− 3b

− 6ag − 5bg + 12ag1 + 8bg1 + 4g2 − 8g1g + 4g2
1

− 12aχ(OS)− 6bχ(OS) + 12aχ(OS1) + 6bχ(OS1) ≥ 0 (7)

(to obtain these relations we have to use (3) and (4), or even better the self-intersection
formula itself).

We now want to compare inequalities (6) and (7) with equality (5). To this purpose
we try to eliminate χ(OS) and χ(OS1). We thus multiply (6) by b(2a + b) and (7) by
a(a+ b) and subtract (5) multiplied by (a+ b)(2a+ b). We find the beautiful surprise
that the result of this operation, which must be a non negative number, becomes

−(−3a2 − 5ab− 2b2 + 4a + 2b + 2ag + 2bg − 6ag1 − 4bg1)2. (8)

Therefore, this last expression is zero (it is not difficult to see that for subcanonical
varieties this vanishing holds, since this is equivalent to say that the canonical divisors
of the hyperplane sections of S and S1 are multiples of their respective hyperplane
section and these multiples are related with each other). Also the inequalities (6)
and (7) become equalities. (It is easy to see that b > 0, and a = 0 only if X is a
G(1, 3), which is obviously subcanonical.) If we compute now (KSHS)2 −K2

SH2
S it

becomes

− 3a3 − 5a2b− 7ab2

2
− b3 + 15a2 +

41ab

2
+ 7b2 + 3a + 2b− 3ag − 2bg

+ 4g2 − 8g + 4− 18aχ(OS)− 12bχ(OS)

which is seen to be (6) multiplied by 3a+2b
a+b plus (7) multiplied by 3a+2b

2a+b minus (8)
divided by (a + b)(2a + b), and hence it is zero. The result follows now from Hodge
index theorem and Lefschetz hyperplane theorem, as in the projective case.

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Enrique Arrondo Subcanonicity of codimension two subvarieties

Unfortunately we cannot deduce from the above result the subcanonicity in codi-
mension two for any G(1, n). Indeed, the canonical way would be to use induction
on n, regard G(1, n−1) inside G(1, n) as the set of lines lying in a hyperplane of Pn and
restrict any X ⊂ G(1, n) to G(1, n− 1). However, G(1, n− 1) is obtained as the zero
locus of a section of the rank two quotient bundle Q on G(1, n). But neither Q nor its
restriction to X are ample, and therefore there is no known analogue of the Lefschetz
hyperplane theorem to guarantee that the map H2(X, Q) → H2(X ∩G(1, n− 1), Q)
is injective (see [7]).

Nevertheless, as mentioned in the introduction, it is known that, if n ≥ 6, the
Picard group of any smooth subvariety X ⊂ G(1, n) is generated by its hyperplane
section, and hence X is subcanonical (even in the strict sense that the canonical
divisor is linearly equivalent to an integral multiple of the hyperplane section). We
are therefore left with the case n = 5. I include here the numerical details of the proof
(whose scheme is the same as in the above proofs), which is due to my student Jorge
Caravantes.

Theorem 2.2. Any smooth subvariety X ⊂ G(1, 5) of codimension two is rationally
numerically subcanonical.

Proof. Let the subvariety X have bidegree (a, b), where a is the number of lines of X
contained in a fixed general three-dimensional subspace of P5 and passing through a
fixed general point of it, and b is the number of lines of X contained in a general plane
of P5. We can consider the following surfaces inside X (the last three corresponding
to the intersection with the three Schubert cycles of G(1, 5) of dimension four):

• The surface S obtained as the intersection of X with four general hyperplanes
of P14 (the Plücker space of G(1, 5)). We will denote with g its sectional genus.

• The surface S1 consisting of the lines of X passing through a fixed general point
of P5. We will denote with g1 its sectional genus.

• The surface S2 consisting of the set of lines of X contained in a hyperplane of
P5 and meeting a line of it.

• The surface S3 consisting of the lines of X contained in a fixed general three-
dimensional subspace of P5. It is not difficult to see that its sectional genus can
be derived from g, g1, a, and b.

We write again X as the dependency locus of r−1 sections of a vector bundle F of
rank r over G(1, 5). The equation c3(F )2−c2(F )c4(F ) = 0 produces now two identities
when intersecting with the two Schubert cycles of codimension two of G(1, 5):

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Enrique Arrondo Subcanonicity of codimension two subvarieties

− 1
2
a3 − 3

2
a2b− 1

2
b3 +

493
50

a2 +
141
10

ab +
13
2

b2 − 439
25

a− 24
5

b− 38
25

ag

− 8
5
bg +

477
25

ag1 +
32
5

bg1 +
4
25

g2 − 32
25

gg1 +
164
25

g2
1 +

24
25

g − 296
25

g1

+
136
25

− 2aχ(OS) + 2aχ(OS1) + 4aχ(OS3)− 6bχ(OS3) = 0, (9)

− 3
2
a3 − 3

2
a2b− 3

2
ab2 +

303
50

a2 − 2
5
ab− 2b2

+
136
25

a +
1
5
b− 18

25
ag +

2
5
bg − 118

25
ag1 −

3
5
bg1 +

4
25

g2

+
8
25

gg1 +
4
25

g2
1 +

16
25

g − 16
25

g1 +
16
25
− 2aχ(OS)− 2bχ(OS)

− 4aχ(OS1) + 2bχ(OS1)− 2aχ(OS3) + 4bχ(OS3) = 0. (10)

On the other hand, the Hodge inequality for the restriction of KX and HX to
S1, S2 and S3 yield (after using the appropriate double-point formulas) the following
three inequalities:

−1
2
a3 +

7
2
a2 − a + ag1 + 4g2

1 − 8g1 + 4− 6aχ(OS1) ≥ 0, (11)

− a3 − 5
2
a2b− ab2 − 236

25
a2 − 89

10
ab− 2b2 − 14

25
a +

1
5
b

+
32
25

ag +
2
5
bg − 18

25
ag1 −

3
5
bg1 +

4
25

g2 +
8
25

gg1

+
4
25

g2
1 −

16
25

g − 16
25

g1 +
16
25
− 4aχ(OS)− 2bχ(OS)

+ 4aχ(OS1) + 2bχ(OS1) + 8aχ(OS3) + 4bχ(OS3) ≥ 0, (12)

− 1
2
a3 − 1

2
a2b− 1

2
ab2 − 1

2
b3 +

1093
50

a2 +
113
5

ab +
13
2

b2 − 264
25

a− 24
5

b

− 88
25

ag − 8
5
bg +

352
25

ag1 +
32
5

bg1 +
4
25

g2 − 32
25

gg1 +
64
25

g2
1 +

24
25

g − 96
25

g1

+
36
25
− 6aχ(OS3)− 6bχ(OS3) ≥ 0. (13)

In this case we can see immediately that the sum of the left-hand sides of (9)
and (10) coincides with the sum of the left-hand sides of (11), (12), and (13). There-
fore, inequalities (11), (12), and (13) must be in fact equalities.

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Enrique Arrondo Subcanonicity of codimension two subvarieties

To see that (KSHS)2−K2
SH2

S is zero, we multiply its expression (using the double-
point-formulas) by 4a3 +6a2b+2ab2 and subtract the zero expressions 36a3 +74a2b+
48ab2 + 10b3 times (11), 54a3 + 84a2b + 30ab2 times (12) and 72a3 + 76a2b + 2ab2

times (13). In this way we get

− 2
25

(13a + 5b)(−27a2 − 15ab + 16a + 10b + 2ag − 18ag1 − 10bg1)2.

Since it has to be non-negative, this immediately implies that (KSHS)2 − K2
SH2

S

is zero, and the result follows once more by Hodge index theorem and Lefschetz
hyperplane theorem.

Putting together the results of this section we get the following

Corollary 2.3. Let X ⊂ G(1, n) be a smooth codimension two subvariety. If n ≥ 4,
then X is rationally numerically subcanonical.

3. Subvarieties of smooth quadrics

To understand the situation we start with the following example.

Example 3.1. Let X be the image of the Segre embedding of P1 × P3 in P7. In
coordinates, it can be viewed as the set of points (x0 : · · · : x7) for which the matrix(

x0 x1 x2 x3

x4 x5 x6 x7

)
has rank one. Then X is contained in a smooth quadric Q6, for instance the one of
equation X0X5 − X1X4 + X2X7 − X3X6 = 0. Therefore one cannot hope that all
the smooth subvarieties of Q6 of codimension two are subcanonical, even numerically
and/or rationally. Notice that if in this example we intersect X with the linear space
X0 = X2 = X4 = X6 = 0 (which is contained in Q6) we get a smooth conic, hence
of genus zero, while if we intersect with X0 = X1 = X6 = X7 = 0 (also contained in
Q6) we get the disjoint union of two lines, hence of genus −1.

Notation. Let X ⊂ Q6 be a smooth codimension two subvariety of Q6, the smooth
six-dimensional quadric. We will denote by g1, g2 the genera of the curves obtained
by intersecting X with a three-dimensional linear space of each of the two families of
such linear spaces contained in Q6.

The following result shows how the subcanonicity depends on these two genera.

Theorem 3.2. Let X ⊂ Q6 be a smooth codimension two subvariety of Q6. Then X
is rationally numerically subcanonical if and only if g1 = g2.

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Enrique Arrondo Subcanonicity of codimension two subvarieties

Proof. The “only if” part is trivial. Indeed if KX is numerically equivalent to qHX ,
the determinant KX + 6HX of the normal bundle of X in Q6 will be numerically
equivalent to (q + 6)HX . Hence, if C is the intersection of X with a linear space A
of dimension three, the determinant of the normal bundle of C in A will have degree
(q+6) deg(HC) = (q+6)d, where d is one half of the degree of X. Since KA = −4HA,
it follows that the degree of the canonical divisor of C is (q + 2)d, hence independent
on which of the two families of linear spaces A belongs to.

For the “if” part we use the same strategy as in the previous sections. Intersecting
X with two general hyperplanes of P7 we obtain a smooth surface S contained in a
smooth four-dimensional quadric. The double point formula for S inside this quadric
reads

K2
S = d2 − 7d− 4g1 − 4g2 + 8 + 6χ(OS)

(recalling that a smooth four-dimensional quadric can be identified with G(1, 3), this
formula is nothing but (4) with a = b = d and having in mind that the sectional genus
of X can be written as g1 + g2 +d−1 by choosing a linear space of codimension three
intersecting Q6 in the union of two linear spaces of dimension three meeting along a
plane).

We write now X as the dependency locus of r − 1 sections of a vector bundle F
of rank r over Q6. As before, if c1(F ) = c1HQ6 , the first Chern classes of F become:

c2(F ) = dH2
Q6

,

c3(F ) = (4d− c1d + 2g1 − 2)A1 + (4d− c1d + 2g2 − 2)A2,

where, for i = 1, 2, Ai is the class of a linear space of dimension three meeting X in
a curve of genus gi, and

c4(F ) =
(
d2+25d+2c2

1d−16c1d+12g1+12g2−24−4c1g1−4c1g2+8c1+6χ(OS)
)
A1H.

With these expressions, the relation c3(F )2 − c2(F )c4(F ) = 0 becomes

−d3 + 7d2 − 8d + 4dg1 + 4dg2 + 8g1g2 − 8g1 − 8g2 + 8− 6dχ(OS) = 0, (14)

while the inequality (KSHS)2 −K2
SH2

S ≥ 0 becomes

−d3 + 7d2 − 8d + 4dg1 + 4dg2 + 2g2
1 + 4g1g2 + 2g2

2 − 8g1 − 8g2 + 8− 6dχ(OS) ≥ 0,

which, using the equality (14), can be written as 2(g1 − g2)2 ≥ 0. We therefore have
equality in the Hodge inequality if g1 = g2, which proves the result.

4. Final remarks

In the results of this paper, one should expect to be able to replace “rationally nu-
merically equivalent” with “linearly equivalent”, as it happens for sufficiently big
dimension. In particular I conjecture the following:

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Enrique Arrondo Subcanonicity of codimension two subvarieties

Conjecture 4.1. Let X ⊂ G(1, n) be a smooth subvariety of codimension two. If
n ≥ 4, then Pic(X) is generated by the hyperplane section class.

Conjecture 4.2. Let X ⊂ Qn be a smooth subvariety of codimension two. If n ≥ 6,
then Pic(X) is generated by the hyperplane section class except if n = 6 and g1 6= g2.

Such results would be a first step towards an analogue of Hartshorne’s conjecture,
which I state in the following way:

Conjecture 4.3. Let X ⊂ G(1, n) be a smooth subvariety of codimension two. If
n ≥ 4, then X is either the complete intersection of G(1, n) with two hypersurfaces
or the zero locus of a section of a twist of the universal rank-two quotient bundle of
G(1, n).

Conjecture 4.4. Let X ⊂ Qn be a smooth subvariety of codimension two. If n ≥ 6,
then X is the complete intersection of Qn with two hypersurfaces except if n = 6 and
g1 6= g2.

Observe that these are not just an analogue of Hartshorne’s conjecture, but in fact
they would imply it. To see this, it is enough to consider finite maps from G(1, 4) and
Q6 to P6, and then consider the pull-back by these maps of any smooth codimension
two subvariety.

In the case of quadrics, Conjectures 4.2 and 4.4 can be strengthen with the fol-
lowing (probably very optimistic):

Conjecture 4.5. Let X ⊂ Q6 be a smooth subvariety of codimension two. If g1 6= g2,
then X is as in Example 3.1.

A natural question is whether similar results are true for other ambient varieties
of dimension at least six. The first natural choice would be arbitrary Grassmannians
(as in [2] and [8]). For example, Theorem 2.1 can be interpreted as saying that any
smooth codimension two subvariety of G(2, 4) is rationally numerically subcanonical
(and one can conjecture for instance that moreover its Picard group is generated by
its hyperplane section). The problem to extend this to arbitrary Grassmannians of
planes is the same we found in section 2 for Grassmannians of lines. The general
question is:

Problem 4.6. Let X ⊂ G(k, n) be a smooth subvariety. Find conditions under
which the restriction maps Hi(X, Q) → Hi(X ∩ G(k, n − 1), Q) and Hi(X, Z) →
Hi(X ∩G(k, n− 1), Z) are injective.

Observe that X ∩G(k, n− 1) is given as the zero locus of the restriction to X of a
section of the rank-(k+1) universal quotient bundle of G(k, n). However, in the cases
we are interested in, this bundle is not ample, so that we cannot apply [7, Prop. 1.1.6],
which would imply a positive answer to the problem.

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Enrique Arrondo Subcanonicity of codimension two subvarieties

If Problem 4.6 had a positive answer if i = 2 and dim G(k, n− 1) ≥ 6, this would
imply for example the subcanonicity for any subvariety of codimension two in G(k, n)
with dim G(k, n) ≥ 6. It would be enough to intersect the subvariety with a general
G(k, k+2) and apply Corollary 2.3 (or restrict to G(k, k+1) and apply Barth-Larsen
result).

Acknowledgements. The motivation for this paper came from several discussions
with Lucia Fania. Giorgio Ottaviani (and many others that I would have not enough
space to quote) also helped me to cover my ignorance about several technical details.
I deeply thank my student Jorge Caravantes, who allowed me to include here his proof
of Theorem 2.2; he should be considered the only author of that part. I want also to
acknowledge the extremely useful help that has been for this paper the extensive use
we did of the Maple package Schubert ([5]).

References

[1] W. Barth, Transplanting cohomology classes in complex-projective space, Amer. J. Math. 92
(1970), 951–967.

[2] W. Barth and A. Van de Ven, On the geometry in codimension 2 of Grassmann manifolds,
Classification of algebraic varieties and compact complex manifolds, 1974, pp. 1–35. Lecture
Notes in Math., Vol. 412.

[3] M. C. Beltrametti and A. J. Sommese, The adjunction theory of complex projective varieties, de
Gruyter Expositions in Mathematics, vol. 16, Walter de Gruyter & Co., Berlin, 1995.

[4] L. Ein, An analogue of Max Noether’s theorem, Duke Math. J. 52 (1985), no. 3, 689–706.

[5] S. Katz and S. A. Strømme, schubert, a Maple package for intersection theory, available at
http://www.mi.uib.no/schubert/.

[6] M. E. Larsen, On the topology of complex projective manifolds, Invent. Math. 19 (1973), 251–260.

[7] A. J. Sommese, Submanifolds of Abelian varieties, Math. Ann. 233 (1978), no. 3, 229–256.

[8] , Complex subspaces of homogeneous complex manifolds. II. Homotopy results, Nagoya
Math. J. 86 (1982), 101–129.

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