Kodaira dimension
In algebraic geometry, the Kodaira dimension κ measures the size of the canonical model of a projective variety X.
Igor Shafarevich introduced an important numerical invariant of surfaces with the notation κ in the seminar [|Shafarevich 1965]. extended it and defined the Kodaira dimension for higher dimensional varieties, and later named it after Kunihiko Kodaira in.
The plurigenera
The canonical bundle of a smooth algebraic variety X of dimension n over a field is the line bundle of n-forms,which is the nth exterior power of the cotangent bundle of X.
For an integer d, the dth tensor power of KX is again a line bundle.
For d ≥ 0, the vector space of global sections H0 has the remarkable property that it is a birational invariant of smooth projective varieties X. That is, this vector space is canonically identified with the corresponding space for any smooth projective variety which is isomorphic to X outside lower-dimensional subsets.
For d ≥ 0, the
dth plurigenus of X is defined as the dimension of the vector space
of global sections of KXd:
The plurigenera are important birational invariants of an algebraic variety. In particular, the simplest way to prove that a variety is not rational is to show that some plurigenus Pd with d > 0
is not zero. If the space of sections of KXd is nonzero, then there is a natural rational map from X to the projective space
called the d-canonical map. The canonical ring R of a variety X is the graded ring
Also see geometric genus and arithmetic genus.
The Kodaira dimension of X is defined to be if the plurigenera Pd are zero for all d > 0; otherwise, it is the minimum κ such that Pd/dκ is bounded. The Kodaira dimension of an n-dimensional variety is either or an integer in the range from 0 to n.
Interpretations of the Kodaira dimension
The following integers are equal if they are non-negative. A good reference is, Theorem 2.1.33.- If the canonical ring is finitely generated, which is true in characteristic zero and conjectured in general: the dimension of the Proj construction .
- The dimension of the image of the d-canonical mapping for all positive multiples d of some positive integer.
- The transcendence degree of the fraction field of R, minus one, i.e.,, where t is the number of algebraically independent generators one can find.
- The rate of growth of the plurigenera: that is, the smallest number κ such that is bounded. In Big O notation, it is the minimal κ such that.
Application
The Kodaira dimension gives a useful rough division of all algebraic varieties into several classes.Varieties with low Kodaira dimension can be considered special, while varieties of maximal Kodaira dimension are said to be of general type.
Geometrically, there is a very rough correspondence between Kodaira dimension and curvature: negative Kodaira dimension corresponds to positive curvature, zero Kodaira dimension corresponds to flatness, and maximum Kodaira dimension corresponds to negative curvature.
The specialness of varieties of low Kodaira dimension is analogous to the specialness of Riemannian manifolds of positive curvature ; see classical theorems, especially on Pinched sectional curvature and Positive curvature.
These statements are made more precise below.
Dimension 1
Smooth projective curves are discretely classified by genus, which can be any natural number g = 0, 1,....Here "discretely classified" means that for a given genus, there is an irreducible moduli space of curves of that genus.
The Kodaira dimension of a curve X is:
- κ = : genus 0 : KX is not effective, Pd = 0 for all d > 0.
- κ = 0: genus 1 : KX is a trivial bundle, Pd = 1 for all d ≥ 0.
- κ = 1: genus g ≥ 2: KX is ample, Pd = for all d ≥ 2.
Dimension 2
The Enriques–Kodaira classification classifies algebraic surfaces: coarsely by Kodaira dimension, then in more detail within a given Kodaira dimension. To give some simple examples: the product P1 × X has Kodaira dimension for any curve X; the product of two curves of genus 1 has Kodaira dimension 0; the product of a curve of genus 1 with a curve of genus at least 2 has Kodaira dimension 1; and the product of two curves of genus at least 2 has Kodaira dimension 2 and hence is of general type.For a surface X of general type, the image of the d-canonical map is birational to X if d ≥ 5.
Any dimension
have Kodaira dimension. Abelian varieties have Kodaira dimension zero. More generally, Calabi–Yau manifolds have Kodaira dimension zero.Any variety in characteristic zero that is covered by rational curves, called a uniruled variety, has Kodaira dimension −∞. Conversely, the main conjectures of minimal model theory would imply that every variety of Kodaira dimension −∞ is uniruled. This converse is known for varieties of dimension at most 3.
proved the invariance of plurigenera under deformations for all smooth complex projective varieties. In particular, the Kodaira dimension does not change when the complex structure of the manifold is changed continuously.
A fibration of normal projective varieties X → Y means a surjective morphism with connected fibers.
For a 3-fold X of general type, the image of the d-canonical map is birational to X if d ≥ 61.
General type
A variety of general type X is one of maximal Kodaira dimension :Equivalent conditions are that the line bundle is big, or that the d-canonical map is generically injective for d sufficiently large.
For example, a variety with ample canonical bundle is of general type.
In some sense, most algebraic varieties are of general type. For example, a smooth hypersurface of degree d in the n-dimensional projective space is of general type if and only if. In that sense, most smooth hypersurfaces in projective space are of general type.
Varieties of general type seem too complicated to classify explicitly, even for surfaces. Nonetheless, there are some strong positive results about varieties of general type. For example, Enrico Bombieri showed in 1973 that the d-canonical map of any complex surface of general type is birational for every. More generally, Christopher Hacon and James McKernan, Shigeharu Takayama, and Hajime Tsuji showed in 2006 that for every positive integer n, there is a constant such that the d-canonical map of any complex n-dimensional variety of general type is birational when.
The birational automorphism group of a variety of general type is finite.
Application to classification
Let X be a variety of nonnegative Kodaira dimension over a field of characteristic zero, and let B be the canonical model of X, B = Proj R; the dimension of B is equal to the Kodaira dimension of X. There is a natural rational map X – → B; any morphism obtained from it by blowing up X and B is called the Iitaka fibration. The minimal model and abundance conjectures would imply that the general fiber of the Iitaka fibration can be arranged to be a Calabi–Yau variety, which in particular has Kodaira dimension zero. Moreover, there is an effective Q-divisor Δ on B such that the pair is klt, KB + Δ is ample, and the canonical ring of X is the same as the canonical ring of in degrees a multiple of some d > 0. In this sense, X is decomposed into a family of varieties of Kodaira dimension zero over a base of general type.Given the conjectures mentioned, the classification of algebraic varieties would largely reduce to the cases of Kodaira dimension, 0 and general type. For Kodaira dimension and 0, there are some approaches to classification. The minimal model and abundance conjectures would imply that every variety of Kodaira dimension is uniruled, and it is known that every uniruled variety in characteristic zero is birational to a Fano fiber space. The minimal model and abundance conjectures would imply that every variety of Kodaira dimension 0 is birational to a Calabi-Yau variety with terminal singularities.
The Iitaka conjecture states that the Kodaira dimension of a fibration is at least the sum of the Kodaira dimension of the base and the Kodaira dimension of a general fiber; see for a survey. The Iitaka conjecture helped to inspire the development of minimal model theory in the 1970s and 1980s. It is now known in many cases, and would follow in general from the minimal model and abundance conjectures.