In mathematics, an algebraic surface is an algebraic variety of dimension two. In the case of geometry over the field of complex numbers, an algebraic surface has complex dimension two (as a complex manifold, when it is non-singular) and so of dimension four as a smooth manifold.
The theory of algebraic surfaces is much more complicated than that of algebraic curves (including the compact Riemann surfaces, which are genuine surfaces of (real) dimension two). Many results were obtained, but, in the Italian school of algebraic geometry, and are up to 100 years old.
pa
pg
Examples of algebraic surfaces include (κ is the Kodaira dimension):
For more examples see the list of algebraic surfaces.
The first five examples are in fact birationally equivalent. That is, for example, a cubic surface has a function field isomorphic to that of the projective plane, being the rational functions in two indeterminates. The Cartesian product of two curves also provides examples.
The birational geometry of algebraic surfaces is rich, because of blowing up (also known as a monoidal transformation), under which a point is replaced by the curve of all limiting tangent directions coming into it (a projective line). Certain curves may also be blown down, but there is a restriction (self-intersection number must be -1).
One of the fundamental theorems for the birational geometry of surfaces is Castelnuovo's theorem. This states that any birational map between algebraic surfaces is given by a finite sequence of blowups and blowdowns.
The Nakai criterion says that:
A Divisor D on a surface S is ample if and only if D2 > 0 and for all irreducible curve C on S D•C > 0.
Ample divisors have a nice property such as it is the pullback of some hyperplane bundle of projective space, whose properties are very well known. Let
l{D}(S)
l{D}(S) x l{D}(S) → Z:(X,Y)\mapstoX ⋅ Y
l{D}0(S):=\{D\inl{D}(S)|D ⋅ X=0,forallX\inl{D}(S)\}
l{D}/l{D}0(S):=Num(S)
Num(S) x Num(S)\mapstoZ=(\bar{D},\bar{E})\mapstoD ⋅ E
Num(S)
\bar{D}
\bar{D}
For an ample line bundle H on S, the definition
\{H\}\perp:=\{D\inNum(S)|D ⋅ H=0\}.
for
D\in\{\{H\}\perp|D\ne0\},D ⋅ D<0
\{H\}\perp
Basic results on algebraic surfaces include the Hodge index theorem, and the division into five groups of birational equivalence classes called the classification of algebraic surfaces. The general type class, of Kodaira dimension 2, is very large (degree 5 or larger for a non-singular surface in P3 lies in it, for example).
There are essential three Hodge number invariants of a surface. Of those, h1,0 was classically called the irregularity and denoted by q; and h2,0 was called the geometric genus pg. The third, h1,1, is not a birational invariant, because blowing up can add whole curves, with classes in H1,1. It is known that Hodge cycles are algebraic and that algebraic equivalence coincides with homological equivalence, so that h1,1 is an upper bound for ρ, the rank of the Néron-Severi group. The arithmetic genus pa is the difference
geometric genus - irregularity.
This explains why the irregularity got its name, as a kind of 'error term'.
See main article: Riemann-Roch theorem for surfaces. The Riemann-Roch theorem for surfaces was first formulated by Max Noether. The families of curves on surfaces can be classified, in a sense, and give rise to much of their interesting geometry.