Pluricanonical ring
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In mathematics, the pluricanonical ring of an algebraic variety V (which is non-singular), or of a complex manifold, is the graded ring R(V,K) = R(V,KV) of sections of powers of the canonical bundle K. Its nth graded component (for ) is:
- Rn: = H0(V,Kn),
that is, the space of sections of the n-th tensor product Kn of the canonical bundle K.
The 0th graded component R0 is sections of the trivial bundle, and is canonically the ring of regular functions; thus R is an algebra over the regular functions on V.
One can define an analogous ring for any line bundle L over V; the analogous dimension is called the Iitaka dimension. A line bundle is called big if the Iitaka dimension equals the dimension of the variety.
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[edit] Fundamental conjecture of birational geometry
A basic conjecture is that the pluricanonical ring is finitely generated. This is considered a major step in the Mori program.
Announcements were made in 2007 claiming proofs[1][2].
[edit] The plurigenera
The dimension
is the classically-defined n-th plurigenus of V. The pluricanonical divisor Kn, via the corresponding linear system of divisors, gives a map to projective space , called the n-canonical map.
[edit] Kodaira dimension
The size of R is a basic invariant of V, and is called the Kodaira dimension.
[edit] Definition
The Kodaira dimension, named for Kunihiko Kodaira, of V is defined as any of the following:
- The dimension of the Proj construction (this variety is called the canonical model of V).
- The dimension of the image of the n-canonical mapping for n large enough.
- The transcendence degree of R, minus one, i.e. t − 1, where t is the number of algebraically independent generators one can find.
- The rate of growth of the plurigenera: it is the smallest number κ such that is bounded. In Big O notation, it is the minimal κ such that Pn = O(nκ).
Conventionally, when R is trivial (R = R0 = underlying field (constant functions); the plurigenera are all zero (other than P0 = 1); the pluricanonical divisors are not effective), which happens for example when V is rational, one takes κ = − 1 (in agreement with the transcendence degree definition), or sometimes (which is a conventional dimension of the empty set, as it preserves additivity under multiplication).
Kodaira dimensions can take any value from −1 to the dimension of V.
[edit] Application
The Kodaira dimension is a relatively coarse invariant, and helps to give the outline for the classification of algebraic varieties: it is coarse in that there are generally several distinct families of varieties with a given Kodaira dimension.
Varieties with low Kodaira dimension are special, while varieties of maximal Kodaira dimension are (suggestively) called general type.
Geometrically, there is a rough correspondence between Kodaira dimension and curvature: negative Kodaira dimension corresponds to positive curvature, zero Kodaira dimension corresponds to flatness, and maximum Kodaira dimension (general type) corresponds to negative curvature.
The specialness of varieties of low Kodaira dimension corresponds to the specialness of Riemannian manifolds of positive curvature (and general type corresponds to the genericity of non-positive curvature); see classical theorems, especially on Pinched sectional curvature and Positive curvature.
The above statements are made more precise below.
[edit] Dimension 1
Complex non-singular algebraic curves are discretely classified by genus, which can be any natural number .
By "discretely classified" we mean that for a given genus, there is a connected, irreducible moduli space of curves of that genus.
The Kodaira dimension of an algebraic curve is:
- κ = − 1: genus 0 (projective line): K is not effective, Pn = 0
- κ = 0: genus 1 (elliptic curves): K is a trivial bundle, Pn = 1
- κ = 1: genus 2 or more: K is ample
Compare with the Uniformization theorem for surfaces (real surfaces, which are the analogue in differential geometry of algebraic curves): Kodaira dimension -1 corresponds to positive curvature, Kodaira dimension 0 corresponds to flat, Kodaira dimension 1 corresponds to negative curvature. Note that the generic surface is of general type: in the moduli space of surfaces, 2 components have Kodaira dimension below 1, while all other components have Kodaira dimension 1. Further, the component corresponding to genus 0 is a point, to genus 1 is 1-dimensional, and to genus is (3g − 3)-dimensional.
[edit] Dimension 2
The Enriques-Kodaira classification classifies surfaces: coarsely by Kodaira dimension, then in more detail within a given dimension.
[edit] General dimension
Rational varieties have negative Kodaira dimension (corresponding to positive curvature). Abelian varieties and Calabi-Yau manifolds (in dimension 1, elliptic curves; in dimension 2, complex tori and K3 surfaces) have Kodaira dimension zero (corresponding to admitting flat metrics and Ricci flat metrics, respectively).
[edit] General type
A variety of general type V is one of maximal Kodaira dimension (Kodaira dimension equal to its dimension):
Equivalently, K is an ample line bundle; equivalently, the n-canonical map is an immersion for n sufficiently large. Formally, it is a kind of dual concept to Fano variety, whose anticanonical bundle is ample.
In some sense varieties of general type are generic, hence the term (discrete invariants of varieties of general type vary in more dimensions, and moduli space of varieties of general type have more dimensions; this is made more precise for curves and surfaces).
Varieties of general type are poorly understood, even for surfaces. For instance, in the Enriques-Kodaira classification, the surfaces of general type are a category, but are not described in much more detail. It is not even known what Chern numbers can be realized.
[edit] Examples
For genus , the Deligne-Mumford moduli space of curves is of general type. [3]
[edit] Application to classification
An important idea is that Kodaira dimensions add in fibrations. This motivates a classification programme for algebraic varieties, in which it is sought to represent V as a fibration over a variety of general type, with typical fiber of Kodaira dimension 0. This is quite a natural idea, given that the application of the Proj construction to the pluricanonical ring should produce a projective variety in which the sections of powers of K 'capture' as much as they can about V.