Very Ample Line Bundle
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In mathematics, a distinctive feature of
algebraic geometry Algebraic geometry is a branch of mathematics, classically studying zeros of multivariate polynomials. Modern algebraic geometry is based on the use of abstract algebraic techniques, mainly from commutative algebra, for solving geometrical ...
is that some
line bundle In mathematics, a line bundle expresses the concept of a line that varies from point to point of a space. For example, a curve in the plane having a tangent line at each point determines a varying line: the ''tangent bundle'' is a way of organisin ...
s on a
projective variety In algebraic geometry, a projective variety over an algebraically closed field ''k'' is a subset of some projective ''n''-space \mathbb^n over ''k'' that is the zero-locus of some finite family of homogeneous polynomials of ''n'' + 1 variables w ...
can be considered "positive", while others are "negative" (or a mixture of the two). The most important notion of positivity is that of an ample line bundle, although there are several related classes of line bundles. Roughly speaking, positivity properties of a line bundle are related to having many global
sections Section, Sectioning or Sectioned may refer to: Arts, entertainment and media * Section (music), a complete, but not independent, musical idea * Section (typography), a subdivision, especially of a chapter, in books and documents ** Section sig ...
. Understanding the ample line bundles on a given variety ''X'' amounts to understanding the different ways of mapping ''X'' into
projective space In mathematics, the concept of a projective space originated from the visual effect of perspective, where parallel lines seem to meet ''at infinity''. A projective space may thus be viewed as the extension of a Euclidean space, or, more generally ...
. In view of the correspondence between line bundles and
divisors In mathematics, a divisor of an integer n, also called a factor of n, is an integer m that may be multiplied by some integer to produce n. In this case, one also says that n is a multiple of m. An integer n is divisible or evenly divisible by ...
(built from
codimension In mathematics, codimension is a basic geometric idea that applies to subspaces in vector spaces, to submanifolds in manifolds, and suitable subsets of algebraic varieties. For affine and projective algebraic varieties, the codimension equals the ...
-1 subvarieties), there is an equivalent notion of an ample divisor. In more detail, a line bundle is called basepoint-free if it has enough sections to give a
morphism In mathematics, particularly in category theory, a morphism is a structure-preserving map from one mathematical structure to another one of the same type. The notion of morphism recurs in much of contemporary mathematics. In set theory, morphisms a ...
to projective space. A line bundle is semi-ample if some positive power of it is basepoint-free; semi-ampleness is a kind of "nonnegativity". More strongly, a
line bundle In mathematics, a line bundle expresses the concept of a line that varies from point to point of a space. For example, a curve in the plane having a tangent line at each point determines a varying line: the ''tangent bundle'' is a way of organisin ...
on ''X'' is very ample if it has enough sections to give a closed immersion (or "embedding") of ''X'' into projective space. A line bundle is ample if some positive power is very ample. An ample line bundle on a projective variety ''X'' has positive degree on every
curve In mathematics, a curve (also called a curved line in older texts) is an object similar to a line (geometry), line, but that does not have to be Linearity, straight. Intuitively, a curve may be thought of as the trace left by a moving point (ge ...
in ''X''. The converse is not quite true, but there are corrected versions of the converse, the Nakai–Moishezon and Kleiman criteria for ampleness.


Introduction


Pullback of a line bundle and hyperplane divisors

Given a morphism f\colon X \to Y of schemes, a
vector bundle In mathematics, a vector bundle is a topological construction that makes precise the idea of a family of vector spaces parameterized by another space X (for example X could be a topological space, a manifold, or an algebraic variety): to every po ...
''E'' on ''Y'' (or more generally a
coherent sheaf In mathematics, especially in algebraic geometry and the theory of complex manifolds, coherent sheaves are a class of sheaves closely linked to the geometric properties of the underlying space. The definition of coherent sheaves is made with refe ...
on ''Y'') has a
pullback In mathematics, a pullback is either of two different, but related processes: precomposition and fiber-product. Its dual is a pushforward. Precomposition Precomposition with a function probably provides the most elementary notion of pullback: in ...
to ''X'', f^*E (see Sheaf of modules#Operations). The pullback of a vector bundle is a vector bundle of the same rank. In particular, the pullback of a line bundle is a line bundle. (Briefly, the fiber of f^*E at a point ''x'' in ''X'' is the fiber of ''E'' at ''f''(''x'').) The notions described in this article are related to this construction in the case of a morphism to projective space :f\colon X \to \mathbb P^n, with ''E'' = ''O''(1) the line bundle on projective space whose global sections are the
homogeneous polynomial In mathematics, a homogeneous polynomial, sometimes called quantic in older texts, is a polynomial whose nonzero terms all have the same degree. For example, x^5 + 2 x^3 y^2 + 9 x y^4 is a homogeneous polynomial of degree 5, in two variables; t ...
s of degree 1 (that is, linear functions) in variables x_0,\ldots,x_n. The line bundle ''O''(1) can also be described as the line bundle associated to a
hyperplane In geometry, a hyperplane is a subspace whose dimension is one less than that of its ''ambient space''. For example, if a space is 3-dimensional then its hyperplanes are the 2-dimensional planes, while if the space is 2-dimensional, its hyper ...
in \mathbb P^n (because the zero set of a section of ''O''(1) is a hyperplane). If ''f'' is a closed immersion, for example, it follows that the pullback f^*O(1) is the line bundle on ''X'' associated to a hyperplane section (the intersection of ''X'' with a hyperplane in \mathbb^n).


Basepoint-free line bundles

Let ''X'' be a scheme over a
field Field may refer to: Expanses of open ground * Field (agriculture), an area of land used for agricultural purposes * Airfield, an aerodrome that lacks the infrastructure of an airport * Battlefield * Lawn, an area of mowed grass * Meadow, a grass ...
''k'' (for example, an algebraic variety) with a line bundle ''L''. (A line bundle may also be called an invertible sheaf.) Let a_0,...,a_n be elements of the ''k''-
vector space In mathematics and physics, a vector space (also called a linear space) is a set whose elements, often called ''vectors'', may be added together and multiplied ("scaled") by numbers called '' scalars''. Scalars are often real numbers, but can ...
H^0(X,L) of global sections of ''L''. The zero set of each section is a closed subset of ''X''; let ''U'' be the open subset of points at which at least one of a_0,\ldots,a_n is not zero. Then these sections define a morphism :f\colon U\to \mathbb^_k,\ x \mapsto _0(x),\ldots,a_n(x) In more detail: for each point ''x'' of ''U'', the fiber of ''L'' over ''x'' is a 1-dimensional vector space over the residue field ''k''(''x''). Choosing a basis for this fiber makes a_0(x),\ldots,a_n(x) into a sequence of ''n''+1 numbers, not all zero, and hence a point in projective space. Changing the choice of basis scales all the numbers by the same nonzero constant, and so the point in projective space is independent of the choice. Moreover, this morphism has the property that the restriction of ''L'' to ''U'' is isomorphic to the pullback f^*O(1). The base locus of a line bundle ''L'' on a scheme ''X'' is the intersection of the zero sets of all global sections of ''L''. A line bundle ''L'' is called basepoint-free if its base locus is empty. That is, for every point ''x'' of ''X'' there is a global section of ''L'' which is nonzero at ''x''. If ''X'' is proper over a field ''k'', then the vector space H^0(X,L) of global sections has finite dimension; the dimension is called h^0(X,L). So a basepoint-free line bundle ''L'' determines a morphism f\colon X\to \mathbb^n over ''k'', where n=h^0(X,L)-1, given by choosing a basis for H^0(X,L). Without making a choice, this can be described as the morphism :f\colon X\to \mathbb(H^0(X,L)) from ''X'' to the space of hyperplanes in H^0(X,L), canonically associated to the basepoint-free line bundle ''L''. This morphism has the property that ''L'' is the pullback f^*O(1). Conversely, for any morphism ''f'' from a scheme ''X'' to projective space \mathbb^n over ''k'', the pullback line bundle f^*O(1) is basepoint-free. Indeed, ''O''(1) is basepoint-free on \mathbb^n, because for every point ''y'' in \mathbb^n there is a hyperplane not containing ''y''. Therefore, for every point ''x'' in ''X'', there is a section ''s'' of ''O''(1) over \mathbb^n that is not zero at ''f''(''x''), and the pullback of ''s'' is a global section of f^*O(1) that is not zero at ''x''. In short, basepoint-free line bundles are exactly those that can be expressed as the pullback of ''O''(1) by some morphism to projective space.


Nef, globally generated, semi-ample

The
degree Degree may refer to: As a unit of measurement * Degree (angle), a unit of angle measurement ** Degree of geographical latitude ** Degree of geographical longitude * Degree symbol (°), a notation used in science, engineering, and mathematics ...
of a line bundle ''L'' on a proper curve ''C'' over ''k'' is defined as the degree of the divisor (''s'') of any nonzero rational section ''s'' of ''L''. The coefficients of this divisor are positive at points where ''s'' vanishes and negative where ''s'' has a pole. Therefore, any line bundle ''L'' on a curve ''C'' such that H^0(C,L)\neq 0 has nonnegative degree (because sections of ''L'' over ''C'', as opposed to rational sections, have no poles). In particular, every basepoint-free line bundle on a curve has nonnegative degree. As a result, a basepoint-free line bundle ''L'' on any proper scheme ''X'' over a field is
nef Nef or NEF may refer to: Businesses and organizations * National Energy Foundation, a British charity * National Enrichment Facility, an American uranium enrichment plant * New Economics Foundation, a British think-tank * Near East Foundation, ...
, meaning that ''L'' has nonnegative degree on every (irreducible) curve in ''X''. More generally, a sheaf ''F'' of O_X-modules on a scheme ''X'' is said to be globally generated if there is a set ''I'' of global sections s_i\in H^0(X,F) such that the corresponding morphism :\bigoplus_O_X\to F of sheaves is surjective. A line bundle is globally generated if and only if it is basepoint-free. For example, every quasi-coherent sheaf on an
affine scheme In commutative algebra, the prime spectrum (or simply the spectrum) of a ring ''R'' is the set of all prime ideals of ''R'', and is usually denoted by \operatorname; in algebraic geometry it is simultaneously a topological space equipped with the ...
is globally generated. Analogously, in complex geometry, Cartan's theorem A says that every coherent sheaf on a Stein manifold is globally generated. A line bundle ''L'' on a proper scheme over a field is semi-ample if there is a positive integer ''r'' such that the
tensor power In mathematics, the tensor algebra of a vector space ''V'', denoted ''T''(''V'') or ''T''(''V''), is the algebra of tensors on ''V'' (of any rank) with multiplication being the tensor product. It is the free algebra on ''V'', in the sense of being ...
L^ is basepoint-free. A semi-ample line bundle is nef (by the corresponding fact for basepoint-free line bundles).


Very ample line bundles

A line bundle ''L'' on a proper scheme ''X'' over a field ''k'' is said to be very ample if it is basepoint-free and the associated morphism :f\colon X\to\mathbb^n_k is a closed immersion. Here n=h^0(X,L)-1. Equivalently, ''L'' is very ample if ''X'' can be embedded into projective space of some dimension over ''k'' in such a way that ''L'' is the restriction of the line bundle ''O''(1) to ''X''. The latter definition is used to define very ampleness for a line bundle on a proper scheme over any
commutative ring In mathematics, a commutative ring is a ring in which the multiplication operation is commutative. The study of commutative rings is called commutative algebra. Complementarily, noncommutative algebra is the study of ring properties that are not sp ...
. The name "very ample" was introduced by Alexander Grothendieck in 1961. Various names had been used earlier in the context of
linear systems of divisors In algebraic geometry, a linear system of divisors is an algebraic generalization of the geometric notion of a family of curves; the dimension of the linear system corresponds to the number of parameters of the family. These arose first in the fo ...
. For a very ample line bundle ''L'' on a proper scheme ''X'' over a field with associated morphism ''f'', the degree of ''L'' on a curve ''C'' in ''X'' is the
degree Degree may refer to: As a unit of measurement * Degree (angle), a unit of angle measurement ** Degree of geographical latitude ** Degree of geographical longitude * Degree symbol (°), a notation used in science, engineering, and mathematics ...
of ''f''(''C'') as a curve in \mathbb^n. So ''L'' has positive degree on every curve in ''X'' (because every subvariety of projective space has positive degree).


Definitions

A line bundle ''L'' on a proper scheme ''X'' over a commutative ring ''R'' is said to be ample if there is a positive integer ''r'' such that the tensor power L^ is very ample. In particular, a proper scheme over ''R'' has an ample line bundle if and only if it is projective over ''R''. An ample line bundle on a proper scheme ''X'' over a field has positive degree on every curve in ''X'', by the corresponding statement for very ample line bundles. A
Cartier divisor In algebraic geometry, divisors are a generalization of codimension-1 subvarieties of algebraic varieties. Two different generalizations are in common use, Cartier divisors and Weil divisors (named for Pierre Cartier and André Weil by David Mu ...
''D'' on a proper scheme ''X'' over a field ''k'' is said to be ample if the corresponding line bundle ''O''(''D'') is ample. (For example, if ''X'' is smooth over ''k'', then a Cartier divisor can be identified with a finite linear combination of closed codimension-1 subvarieties of ''X'' with integer coefficients.) On an arbitrary scheme ''X'', Grothendieck defined a line bundle ''L'' to be ample if ''X'' is
quasi-compact In mathematics, specifically general topology, compactness is a property that seeks to generalize the notion of a closed and bounded subset of Euclidean space by making precise the idea of a space having no "punctures" or "missing endpoints", i ...
and for every point ''x'' in ''X'' there is a positive integer ''r'' and a section s\in H^0(X,L^) such that ''s'' is nonzero at ''x'' and the open subscheme \\subset X is affine. For example, the trivial line bundle O_X is ample if and only if ''X'' is quasi-affine. The rest of this article will concentrate on ampleness on proper schemes over a field. Weakening the notion of "very ample" to "ample" gives a flexible concept with a wide variety of different characterizations. A first point is that tensoring high powers of an ample line bundle with any coherent sheaf whatsoever gives a sheaf with many global sections. More precisely, a line bundle ''L'' on a proper scheme ''X'' over a field (or more generally over a Noetherian ring) is ample if and only if for every coherent sheaf ''F'' on ''X'', there is an integer ''s'' such that the sheaf F\otimes L^ is globally generated for all r\geq s. Here ''s'' may depend on ''F''.Lazarsfeld (2004), Theorem 1.2.6. Another characterization of ampleness, known as the CartanSerreGrothendieck theorem, is in terms of
coherent sheaf cohomology In mathematics, especially in algebraic geometry and the theory of complex manifolds, coherent sheaf cohomology is a technique for producing functions with specified properties. Many geometric questions can be formulated as questions about the ex ...
. Namely, a line bundle ''L'' on a proper scheme ''X'' over a field (or more generally over a Noetherian ring) is ample if and only if for every coherent sheaf ''F'' on ''X'', there is an integer ''s'' such that :H^i(X,F\otimes L^)=0 for all i>0 and all r\geq s. In particular, high powers of an ample line bundle kill cohomology in positive degrees. This implication is called the Serre vanishing theorem, proved by Jean-Pierre Serre in his 1955 paper
Faisceaux algébriques cohérents This is a list of important publications in mathematics, organized by field. Some reasons why a particular publication might be regarded as important: *Topic creator – A publication that created a new topic *Breakthrough – A public ...
.


Examples/Non-examples

* The trivial line bundle O_X on a projective variety ''X'' of positive dimension is basepoint-free but not ample. More generally, for any morphism ''f'' from a projective variety ''X'' to some projective space \mathbb^n over a field, the pullback line bundle L=f^*O(1) is always basepoint-free, whereas ''L'' is ample if and only if the morphism ''f'' is finite (that is, all fibers of ''f'' have dimension 0 or are empty).Lazarsfeld (2004), Theorem 1.2.13. * For an integer ''d'', the space of sections of the line bundle ''O''(''d'') over \mathbb^1_ is the complex vector space of homogeneous polynomials of degree ''d'' in variables ''x'',''y''. In particular, this space is zero for ''d'' < 0. For d\geq 0, the morphism to projective space given by ''O''(''d'') is ::\mathbb^1\to\mathbb^ :by :: ,ymapsto ^d,x^y,\ldots,y^d :This is a closed immersion for d\geq 1, with image a rational normal curve of degree ''d'' in \mathbb^d. Therefore, ''O''(''d'') is basepoint-free if and only if d\geq 0, and very ample if and only if d\geq 1. It follows that ''O''(''d'') is ample if and only if d\geq 1. * For an example where "ample" and "very ample" are different, let ''X'' be a smooth projective curve of
genus Genus ( plural genera ) is a taxonomic rank used in the biological classification of extant taxon, living and fossil organisms as well as Virus classification#ICTV classification, viruses. In the hierarchy of biological classification, genus com ...
1 (an
elliptic curve In mathematics, an elliptic curve is a smooth, projective, algebraic curve of genus one, on which there is a specified point . An elliptic curve is defined over a field and describes points in , the Cartesian product of with itself. If ...
) over C, and let ''p'' be a complex point of ''X''. Let ''O''(''p'') be the associated line bundle of degree 1 on ''X''. Then the complex vector space of global sections of ''O''(''p'') has dimension 1, spanned by a section that vanishes at ''p''. So the base locus of ''O''(''p'') is equal to ''p''. On the other hand, ''O''(2''p'') is basepoint-free, and ''O''(''dp'') is very ample for d\geq 3 (giving an embedding of ''X'' as an elliptic curve of degree ''d'' in \mathbb^). Therefore, ''O''(''p'') is ample but not very ample. Also, ''O''(2''p'') is ample and basepoint-free but not very ample; the associated morphism to projective space is a ramified double cover X\to\mathbb^1. * On curves of higher genus, there are ample line bundles ''L'' for which every global section is zero. (But high multiples of ''L'' have many sections, by definition.) For example, let ''X'' be a smooth plane quartic curve (of degree 4 in \mathbb^2) over C, and let ''p'' and ''q'' be distinct complex points of ''X''. Then the line bundle L=O(2p-q) is ample but has H^0(X,L)=0.


Criteria for ampleness of line bundles


Intersection theory

To determine whether a given line bundle on a projective variety ''X'' is ample, the following ''numerical criteria'' (in terms of intersection numbers) are often the most useful. It is equivalent to ask when a Cartier divisor ''D'' on ''X'' is ample, meaning that the associated line bundle ''O''(''D'') is ample. The intersection number D\cdot C can be defined as the degree of the line bundle ''O''(''D'') restricted to ''C''. In the other direction, for a line bundle ''L'' on a projective variety, the
first Chern class In mathematics, in particular in algebraic topology, differential geometry and algebraic geometry, the Chern classes are characteristic classes associated with complex vector bundles. They have since found applications in physics, Calabi–Yau ma ...
c_1(L) means the associated Cartier divisor (defined up to linear equivalence), the divisor of any nonzero rational section of ''L''. On a smooth projective curve ''X'' over an
algebraically closed field In mathematics, a field is algebraically closed if every non-constant polynomial in (the univariate polynomial ring with coefficients in ) has a root in . Examples As an example, the field of real numbers is not algebraically closed, because ...
''k'', a line bundle ''L'' is very ample if and only if h^0(X,L\otimes O(-x-y))=h^0(X,L)-2 for all ''k''- rational points ''x'',''y'' in ''X''. Let ''g'' be the genus of ''X''. By the Riemann–Roch theorem, every line bundle of degree at least 2''g'' + 1 satisfies this condition and hence is very ample. As a result, a line bundle on a curve is ample if and only if it has positive degree. For example, the canonical bundle K_X of a curve ''X'' has degree 2''g'' − 2, and so it is ample if and only if g\geq 2. The curves with ample canonical bundle form an important class; for example, over the complex numbers, these are the curves with a metric of negative
curvature In mathematics, curvature is any of several strongly related concepts in geometry. Intuitively, the curvature is the amount by which a curve deviates from being a straight line, or a surface deviates from being a plane. For curves, the canonic ...
. The canonical bundle is very ample if and only if g\geq 2 and the curve is not hyperelliptic. The Nakai–Moishezon criterion (named for Yoshikazu Nakai (1963) and
Boris Moishezon Boris Gershevich Moishezon (russian: Борис Гершевич Мойшезон) (October 26, 1937 – August 25, 1993) was a Soviet mathematician. He left the Soviet Union in 1972 for Tel Aviv, and in 1977 moved to Columbia University, where he ...
(1964)) states that a line bundle ''L'' on a proper scheme ''X'' over a field is ample if and only if \int_Y c_1(L)^>0 for every (
irreducible In philosophy, systems theory, science, and art, emergence occurs when an entity is observed to have properties its parts do not have on their own, properties or behaviors that emerge only when the parts interact in a wider whole. Emergence ...
) closed subvariety ''Y'' of ''X'' (''Y'' is not allowed to be a point). In terms of divisors, a Cartier divisor ''D'' is ample if and only if D^\cdot Y>0 for every (nonzero-dimensional) subvariety ''Y'' of ''X''. For ''X'' a curve, this says that a divisor is ample if and only if it has positive degree. For ''X'' a surface, the criterion says that a divisor ''D'' is ample if and only if its
self-intersection number In mathematics, intersection theory is one of the main branches of algebraic geometry, where it gives information about the intersection of two subvarieties of a given variety. The theory for varieties is older, with roots in Bézout's theorem on ...
D^2 is positive and every curve ''C'' on ''X'' has D\cdot C>0.


Kleiman's criterion

To state Kleiman's criterion (1966), let ''X'' be a projective scheme over a field. Let N_1(X) be the real vector space of 1-cycles (real linear combinations of curves in ''X'') modulo numerical equivalence, meaning that two 1-cycles ''A'' and ''B'' are equal in N_1(X) if and only if every line bundle has the same degree on ''A'' and on ''B''. By the Néron–Severi theorem, the real vector space N_1(X) has finite dimension. Kleiman's criterion states that a line bundle ''L'' on ''X'' is ample if and only if ''L'' has positive degree on every nonzero element ''C'' of the closure of the
cone of curves In mathematics, the cone of curves (sometimes the Kleiman-Mori cone) of an algebraic variety X is a combinatorial invariant of importance to the birational geometry of X. Definition Let X be a proper variety. By definition, a (real) ''1-cycle'' ...
NE(''X'') in N_1(X). (This is slightly stronger than saying that ''L'' has positive degree on every curve.) Equivalently, a line bundle is ample if and only if its class in the dual vector space N^1(X) is in the interior of the nef cone. Kleiman's criterion fails in general for proper (rather than projective) schemes ''X'' over a field, although it holds if ''X'' is smooth or more generally Q-factorial. A line bundle on a projective variety is called strictly nef if it has positive degree on every curve . and David Mumford constructed line bundles on smooth projective surfaces that are strictly nef but not ample. This shows that the condition c_1(L)^2>0 cannot be omitted in the Nakai–Moishezon criterion, and it is necessary to use the closure of NE(''X'') rather than NE(''X'') in Kleiman's criterion. Every nef line bundle on a surface has c_1(L)^2\geq 0, and Nagata and Mumford's examples have c_1(L)^2=0. C. S. Seshadri showed that a line bundle ''L'' on a proper scheme over an algebraically closed field is ample if and only if there is a positive real number ε such that deg(''L'', ''C'') ≥ ε''m''(''C'') for all (irreducible) curves ''C'' in ''X'', where ''m''(''C'') is the maximum of the multiplicities at the points of ''C''. Several characterizations of ampleness hold more generally for line bundles on a proper
algebraic space In mathematics, algebraic spaces form a generalization of the schemes of algebraic geometry, introduced by Michael Artin for use in deformation theory. Intuitively, schemes are given by gluing together affine schemes using the Zariski topology, w ...
over a field ''k''. In particular, the Nakai-Moishezon criterion is valid in that generality. The Cartan-Serre-Grothendieck criterion holds even more generally, for a proper algebraic space over a Noetherian ring ''R''. (If a proper algebraic space over ''R'' has an ample line bundle, then it is in fact a projective scheme over ''R''.) Kleiman's criterion fails for proper algebraic spaces ''X'' over a field, even if ''X'' is smooth.


Openness of ampleness

On a projective scheme ''X'' over a field, Kleiman's criterion implies that ampleness is an open condition on the class of an R-divisor (an R-linear combination of Cartier divisors) in N^1(X), with its topology based on the topology of the real numbers. (An R-divisor is defined to be ample if it can be written as a positive linear combination of ample Cartier divisors.) An elementary special case is: for an ample divisor ''H'' and any divisor ''E'', there is a positive real number ''b'' such that H+aE is ample for all real numbers ''a'' of absolute value less than ''b''. In terms of divisors with integer coefficients (or line bundles), this means that ''nH'' + ''E'' is ample for all sufficiently large positive integers ''n''. Ampleness is also an open condition in a quite different sense, when the variety or line bundle is varied in an algebraic family. Namely, let f\colon X\to Y be a proper morphism of schemes, and let ''L'' be a line bundle on ''X''. Then the set of points ''y'' in ''Y'' such that ''L'' is ample on the
fiber Fiber or fibre (from la, fibra, links=no) is a natural or artificial substance that is significantly longer than it is wide. Fibers are often used in the manufacture of other materials. The strongest engineering materials often incorporate ...
X_y is open (in the Zariski topology). More strongly, if ''L'' is ample on one fiber X_y, then there is an affine open neighborhood ''U'' of ''y'' such that ''L'' is ample on f^(U) over ''U''.


Kleiman's other characterizations of ampleness

Kleiman also proved the following characterizations of ampleness, which can be viewed as intermediate steps between the definition of ampleness and numerical criteria. Namely, for a line bundle ''L'' on a proper scheme ''X'' over a field, the following are equivalent: * ''L'' is ample. * For every (irreducible) subvariety Y\sub X of positive dimension, there is a positive integer ''r'' and a section s\in H^0(Y,\mathcal L^) which is not identically zero but vanishes at some point of ''Y''. * For every (irreducible) subvariety Y\sub X of positive dimension, the
holomorphic Euler characteristic In mathematics, especially in algebraic geometry and the theory of complex manifolds, coherent sheaf cohomology is a technique for producing functions with specified properties. Many geometric questions can be formulated as questions about the ex ...
s of powers of ''L'' on ''Y'' go to infinity: ::\chi(Y,\mathcal L^)\to\infty as r\to \infty.


Generalizations


Ample vector bundles

Robin Hartshorne defined a
vector bundle In mathematics, a vector bundle is a topological construction that makes precise the idea of a family of vector spaces parameterized by another space X (for example X could be a topological space, a manifold, or an algebraic variety): to every po ...
''F'' on a projective scheme ''X'' over a field to be ample if the line bundle \mathcal(1) on the space \mathbb(F) of hyperplanes in ''F'' is ample. Several properties of ample line bundles extend to ample vector bundles. For example, a vector bundle ''F'' is ample if and only if high symmetric powers of ''F'' kill the cohomology H^i of coherent sheaves for all i>0. Also, the Chern class c_r(F) of an ample vector bundle has positive degree on every ''r''-dimensional subvariety of ''X'', for 1\leq r\leq \text(F).


Big line bundles

A useful weakening of ampleness, notably in birational geometry, is the notion of a big line bundle. A line bundle ''L'' on a projective variety ''X'' of dimension ''n'' over a field is said to be big if there is a positive real number ''a'' and a positive integer j_0 such that h^0(X,L^)\geq aj^n for all j\geq j_0. This is the maximum possible growth rate for the spaces of sections of powers of ''L'', in the sense that for every line bundle ''L'' on ''X'' there is a positive number ''b'' with h^0(X,L^)\leq bj^n for all ''j'' > 0. There are several other characterizations of big line bundles. First, a line bundle is big if and only if there is a positive integer ''r'' such that the rational map from ''X'' to \mathbb P(H^0(X,L^)) given by the sections of L^ is birational onto its image. Also, a line bundle ''L'' is big if and only if it has a positive tensor power which is the tensor product of an ample line bundle ''A'' and an effective line bundle ''B'' (meaning that H^0(X,B)\neq 0). Finally, a line bundle is big if and only if its class in N^1(X) is in the interior of the cone of effective divisors.Lazarsfeld (2004), Theorem 2.2.26. Bigness can be viewed as a birationally invariant analog of ampleness. For example, if f\colon X\to Y is a dominant rational map between smooth projective varieties of the same dimension, then the pullback of a big line bundle on ''Y'' is big on ''X''. (At first sight, the pullback is only a line bundle on the open subset of ''X'' where ''f'' is a morphism, but this extends uniquely to a line bundle on all of ''X''.) For ample line bundles, one can only say that the pullback of an ample line bundle by a finite morphism is ample. Example: Let ''X'' be the blow-up of the projective plane \mathbb^2 at a point over the complex numbers. Let ''H'' be the pullback to ''X'' of a line on \mathbb^2, and let ''E'' be the exceptional curve of the blow-up \pi\colon X\to\mathbb^2. Then the divisor ''H'' + ''E'' is big but not ample (or even nef) on ''X'', because :(H+E)\cdot E=E^2=-1<0. This negativity also implies that the base locus of ''H'' + ''E'' (or of any positive multiple) contains the curve ''E''. In fact, this base locus is equal to ''E''.


Relative ampleness

Given a quasi-compact morphism of schemes f : X \to S, an invertible sheaf ''L'' on ''X'' is said to be ample relative to ''f'' or ''f''-ample if the following equivalent conditions are met: # For each open affine subset U \subset S, the restriction of ''L'' to f^(U) is ample (in the usual sense). # ''f'' is
quasi-separated In algebraic geometry, a morphism of schemes from to is called quasi-separated if the diagonal map from to is quasi-compact (meaning that the inverse image of any quasi-compact open set is quasi-compact). A scheme is called quasi-separated if ...
and there is an open immersion X \hookrightarrow \operatorname_S(\mathcal), \, \mathcal := f_*\left( \bigoplus_0^ L^ \right) induced by the
adjunction map In mathematics, specifically category theory, adjunction is a relationship that two functors may exhibit, intuitively corresponding to a weak form of equivalence between two related categories. Two functors that stand in this relationship are kno ...
: #:f^* \mathcal \to \bigoplus_0^ L^. # The condition 2. without "open". The condition 2 says (roughly) that ''X'' can be openly compactified to a projective scheme with \mathcal(1)= L (not just to a proper scheme).


See also


General algebraic geometry

*
Algebraic geometry of projective spaces Projective space plays a central role in algebraic geometry. The aim of this article is to define the notion in terms of abstract algebraic geometry and to describe some basic uses of projective space. Homogeneous polynomial ideals Let k be an al ...
* Fano variety: a variety whose canonical bundle is anti-ample * Matsusaka's big theorem *
Divisorial scheme In algebraic geometry, a divisorial scheme is a scheme admitting an ample family of line bundles, as opposed to an ample line bundle. In particular, a quasi-projective variety is a divisorial scheme and the notion is a generalization of "quasi-proj ...
: a scheme admitting an ample family of line bundles


Ampleness in complex geometry

* Holomorphic vector bundle *
Kodaira embedding theorem In mathematics, the Kodaira embedding theorem characterises non-singular projective varieties, over the complex numbers, amongst compact Kähler manifolds. In effect it says precisely which complex manifolds are defined by homogeneous polynomials. ...
: on a compact complex manifold, ampleness and positivity coincide. *
Kodaira vanishing theorem In mathematics, the Kodaira vanishing theorem is a basic result of complex manifold theory and complex algebraic geometry, describing general conditions under which sheaf cohomology groups with indices ''q'' > 0 are automatically zero. The implica ...
*
Lefschetz hyperplane theorem In mathematics, specifically in algebraic geometry and algebraic topology, the Lefschetz hyperplane theorem is a precise statement of certain relations between the shape of an algebraic variety and the shape of its subvarieties. More precisely, the ...
: an ample divisor in a complex projective variety ''X'' is topologically similar to ''X''.


Notes


Sources

* * * * * * * * * * *. *. *. *. *. * *. {{refend


External links


The Stacks Project
Algebraic geometry Geometry of divisors Vector bundles