Nef line bundle

In algebraic geometry, a line bundle on a projective variety is nef if it has nonnegative degree on every curve in the variety. The classes of nef line bundles are described by a convex cone, and the possible contractions of the variety correspond to certain faces of the nef cone. In view of the correspondence between line bundles and divisors (built from codimension-1 subvarieties), there is an equivalent notion of a nef divisor.

Definition

More generally, a line bundle L on a proper scheme X over a field k is said to be nef if it has nonnegative degree on every (closed irreducible) curve in X.^[1] (The degree of a line bundle L on a proper curve C over k is the degree of the divisor (s) of any nonzero rational section s of L.) A line bundle may also be called an invertible sheaf.

The term "nef" was introduced by Miles Reid as a replacement for the older terms "arithmetically effective" (Zariski 1962) and "numerically effective", as well as for the phrase "numerically eventually free".^[2] The older terms were misleading, in view of the examples below.

Every line bundle L on a proper curve C over k which has a global section that is not identically zero has nonnegative degree. As a result, a basepoint-free line bundle on a proper scheme X over k has nonnegative degree on every curve in X; that is, it is nef.^[3] More generally, a line bundle L is called semi-ample if some positive tensor power [math]\displaystyle{ L^{\otimes a} }[/math] is basepoint-free. It follows that a semi-ample line bundle is nef. Semi-ample line bundles can be considered the main geometric source of nef line bundles, although the two concepts are not equivalent; see the examples below.

A Cartier divisor D on a proper scheme X over a field is said to be nef if the associated line bundle O(D) is nef on X. Equivalently, D is nef if the intersection number [math]\displaystyle{ D\cdot C }[/math] is nonnegative for every curve C in X.

To go back from line bundles to divisors, the first Chern class is the isomorphism from the Picard group of line bundles on a variety X to the group of Cartier divisors modulo linear equivalence. Explicitly, the first Chern class [math]\displaystyle{ c_1(L) }[/math] is the divisor (s) of any nonzero rational section s of L.^[4]

The nef cone

To work with inequalities, it is convenient to consider R-divisors, meaning finite linear combinations of Cartier divisors with real coefficients. The R-divisors modulo numerical equivalence form a real vector space [math]\displaystyle{ N^1(X) }[/math] of finite dimension, the Néron–Severi group tensored with the real numbers.^[5] (Explicitly: two R-divisors are said to be numerically equivalent if they have the same intersection number with all curves in X.) An R-divisor is called nef if it has nonnegative degree on every curve. The nef R-divisors form a closed convex cone in [math]\displaystyle{ N^1(X) }[/math], the nef cone Nef(X).

The cone of curves is defined to be the convex cone of linear combinations of curves with nonnegative real coefficients in the real vector space [math]\displaystyle{ N_1(X) }[/math] of 1-cycles modulo numerical equivalence. The vector spaces [math]\displaystyle{ N^1(X) }[/math] and [math]\displaystyle{ N_1(X) }[/math] are dual to each other by the intersection pairing, and the nef cone is (by definition) the dual cone of the cone of curves.^[6]

A significant problem in algebraic geometry is to analyze which line bundles are ample, since that amounts to describing the different ways a variety can be embedded into projective space. One answer is Kleiman's criterion (1966): for a projective scheme X over a field, a line bundle (or R-divisor) is ample if and only if its class in [math]\displaystyle{ N^1(X) }[/math] lies in the interior of the nef cone.^[7] (An R-divisor is called ample if it can be written as a positive linear combination of ample Cartier divisors.) It follows from Kleiman's criterion that, for X projective, every nef R-divisor on X is a limit of ample R-divisors in [math]\displaystyle{ N^1(X) }[/math]. Indeed, for D nef and A ample, D + cA is ample for all real numbers c > 0.

Metric definition of nef line bundles

Let X be a compact complex manifold with a fixed Hermitian metric, viewed as a positive (1,1)-form [math]\displaystyle{ \omega }[/math]. Following Jean-Pierre Demailly, Thomas Peternell and Michael Schneider, a holomorphic line bundle L on X is said to be nef if for every [math]\displaystyle{ \epsilon \gt 0 }[/math] there is a smooth Hermitian metric [math]\displaystyle{ h_\epsilon }[/math] on L whose curvature satisfies [math]\displaystyle{ \Theta_{h_\epsilon}(L)\geq -\epsilon\omega }[/math]. When X is projective over C, this is equivalent to the previous definition (that L has nonnegative degree on all curves in X).^[8]

Even for X projective over C, a nef line bundle L need not have a Hermitian metric h with curvature [math]\displaystyle{ \Theta_h(L)\geq 0 }[/math], which explains the more complicated definition just given.^[9]

Examples

• If X is a smooth projective surface and C is an (irreducible) curve in X with self-intersection number [math]\displaystyle{ C^2\geq 0 }[/math], then C is nef on X, because any two distinct curves on a surface have nonnegative intersection number. If [math]\displaystyle{ C^2\lt 0 }[/math], then C is effective but not nef on X. For example, if X is the blow-up of a smooth projective surface Y at a point, then the exceptional curve E of the blow-up [math]\displaystyle{ \pi\colon X\to Y }[/math] has [math]\displaystyle{ E^2=-1 }[/math].
• Every effective divisor on a flag manifold or abelian variety is nef, using that these varieties have a transitive action of a connected algebraic group.^[10]
• Every line bundle L of degree 0 on a smooth complex projective curve X is nef, but L is semi-ample if and only if L is torsion in the Picard group of X. For X of genus g at least 1, most line bundles of degree 0 are not torsion, using that the Jacobian of X is an abelian variety of dimension g.
• Every semi-ample line bundle is nef, but not every nef line bundle is even numerically equivalent to a semi-ample line bundle. For example, David Mumford constructed a line bundle L on a suitable ruled surface X such that L has positive degree on all curves, but the intersection number [math]\displaystyle{ c_1(L)^2 }[/math] is zero.^[11] It follows that L is nef, but no positive multiple of [math]\displaystyle{ c_1(L) }[/math] is numerically equivalent to an effective divisor. In particular, the space of global sections [math]\displaystyle{ H^0(X,L^{\otimes a}) }[/math] is zero for all positive integers a.

Contractions and the nef cone

A contraction of a normal projective variety X over a field k is a surjective morphism [math]\displaystyle{ f\colon X\to Y }[/math] with Y a normal projective variety over k such that [math]\displaystyle{ f_*O_X=O_Y }[/math]. (The latter condition implies that f has connected fibers, and it is equivalent to f having connected fibers if k has characteristic zero.^[12]) A contraction is called a fibration if dim(Y) < dim(X). A contraction with dim(Y) = dim(X) is automatically a birational morphism.^[13] (For example, X could be the blow-up of a smooth projective surface Y at a point.)

A face F of a convex cone N means a convex subcone such that any two points of N whose sum is in F must themselves be in F. A contraction of X determines a face F of the nef cone of X, namely the intersection of Nef(X) with the pullback [math]\displaystyle{ f^*(N^1(Y))\subset N^1(X) }[/math]. Conversely, given the variety X, the face F of the nef cone determines the contraction [math]\displaystyle{ f\colon X\to Y }[/math] up to isomorphism. Indeed, there is a semi-ample line bundle L on X whose class in [math]\displaystyle{ N^1(X) }[/math] is in the interior of F (for example, take L to be the pullback to X of any ample line bundle on Y). Any such line bundle determines Y by the Proj construction:^[14]

[math]\displaystyle{ Y=\text{Proj }\bigoplus_{a\geq 0}H^0(X,L^{\otimes a}). }[/math]

To describe Y in geometric terms: a curve C in X maps to a point in Y if and only if L has degree zero on C.

As a result, there is a one-to-one correspondence between the contractions of X and some of the faces of the nef cone of X.^[15] (This correspondence can also be formulated dually, in terms of faces of the cone of curves.) Knowing which nef line bundles are semi-ample would determine which faces correspond to contractions. The cone theorem describes a significant class of faces that do correspond to contractions, and the abundance conjecture would give more.

Example: Let X be the blow-up of the complex projective plane [math]\displaystyle{ \mathbb{P}^2 }[/math] at a point p. Let H be the pullback to X of a line on [math]\displaystyle{ \mathbb{P}^2 }[/math], and let E be the exceptional curve of the blow-up [math]\displaystyle{ \pi\colon X\to\mathbb{P}^2 }[/math]. Then X has Picard number 2, meaning that the real vector space [math]\displaystyle{ N^1(X) }[/math] has dimension 2. By the geometry of convex cones of dimension 2, the nef cone must be spanned by two rays; explicitly, these are the rays spanned by H and H − E.^[16] In this example, both rays correspond to contractions of X: H gives the birational morphism [math]\displaystyle{ X\to\mathbb{P}^2 }[/math], and H − E gives a fibration [math]\displaystyle{ X\to\mathbb{P}^1 }[/math] with fibers isomorphic to [math]\displaystyle{ \mathbb{P}^1 }[/math] (corresponding to the lines in [math]\displaystyle{ \mathbb{P}^2 }[/math] through the point p). Since the nef cone of X has no other nontrivial faces, these are the only nontrivial contractions of X; that would be harder to see without the relation to convex cones.

Notes

References

• "Compact complex manifolds with numerically effective tangent bundles", Journal of Algebraic Geometry 3: 295–345, 1994, https://www-fourier.ujf-grenoble.fr/~demailly/manuscripts/dps1.pdf 
• Birational geometry of algebraic varieties, Cambridge University Press, 1998, doi:10.1017/CBO9780511662560, ISBN 978-0-521-63277-5 
• Lazarsfeld, Robert (2004), Positivity in algebraic geometry, 1, Berlin: Springer-Verlag, doi:10.1007/978-3-642-18808-4, ISBN 3-540-22533-1 
• Reid, Miles (1983), "Minimal models of canonical 3-folds", Algebraic varieties and analytic varieties (Tokyo, 1981), Advanced Studies in Pure Mathematics, 1, North-Holland, pp. 131–180, doi:10.2969/aspm/00110131, ISBN 0-444-86612-4 
• Zariski, Oscar (1962), "The theorem of Riemann-Roch for high multiples of an effective divisor on an algebraic surface", Annals of Mathematics, 2 76 (3): 560–615, doi:10.2307/1970376 

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