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Difference between revisions of "Arithmetic genus"

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A numerical invariant of algebraic varieties (cf. [[Algebraic variety|Algebraic variety]]). For an arbitrary projective variety $X$ (over a field $k$) all irreducible components of which have dimension $n$, and which is defined by a homogeneous ideal $I$ in the ring $k[T_0,\ldots,T_N]$, the arithmetic genus $p_a(X)$ is expressed using the constant term $\phi(I,0)$ of the [[Hilbert polynomial|Hilbert polynomial]] $\phi(I,m)$ of $I$ by the formula
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A numerical invariant of algebraic varieties (cf. [[Algebraic variety|Algebraic variety]]). For an arbitrary projective variety $X$ (over a field $k$) all irreducible components of which have dimension $n$, and which is defined by a homogeneous ideal $I$ in the ring $k[T_0,\dots,T_N]$, the arithmetic genus $p_a(X)$ is expressed using the constant term $\phi(I,0)$ of the [[Hilbert polynomial|Hilbert polynomial]] $\phi(I,m)$ of $I$ by the formula
  
 
$$p_a(X)=(-1)^n(\phi(I,0)-1).$$
 
$$p_a(X)=(-1)^n(\phi(I,0)-1).$$

Latest revision as of 12:41, 19 August 2014

A numerical invariant of algebraic varieties (cf. Algebraic variety). For an arbitrary projective variety $X$ (over a field $k$) all irreducible components of which have dimension $n$, and which is defined by a homogeneous ideal $I$ in the ring $k[T_0,\dots,T_N]$, the arithmetic genus $p_a(X)$ is expressed using the constant term $\phi(I,0)$ of the Hilbert polynomial $\phi(I,m)$ of $I$ by the formula

$$p_a(X)=(-1)^n(\phi(I,0)-1).$$

This classical definition is due to F. Severi [1]. In the general case it is equivalent to the following definition:

$$p_a(X)=(-1)^n(\chi(X,\mathcal O_X)-1),$$

where

$$\chi(X,\mathcal O_X)=\sum_{i=0}^n(-1)^i\dim_kH^i(X,\mathcal O_X)$$

is the Euler characteristic of the variety $X$ with coefficients in the structure sheaf $\mathcal O_X$. In this form the definition of the arithmetic genus can be applied to any complete algebraic variety, and this definition also shows the invariance of $p_a(X)$ relative to biregular mappings. If $X$ is a non-singular connected variety, and $k=\mathbf C$ is the field of complex numbers, then

$$p_a(X)=\sum_{i=0}^{n-1}g_{n-1}(X),$$

where $g_k(X)$ is the dimension of the space of regular differential $k$-forms on $X$. Such a definition for $n=1,2$ was given by the school of Italian geometers. For example, if $n=1$, then $p_a(X)$ is the genus of the curve $X$; if $n=2$,

$$p_a(X)=-q+p_g,$$

where $q$ is the irregularity of the surface $X$, while $p_g$ is the geometric genus of $X$.

For any divisor $D$ on a normal variety $X$, O. Zariski (see [1]) defined the virtual arithmetic genus $p_a(D)$ as the constant term of the Hilbert polynomial of the coherent sheaf $\mathcal O_X(D)$ corresponding to $D$. If the divisors $D$ and $D'$ are algebraically equivalent, one has

$$p_a(D)=p_a(D').$$

The arithmetic genus is a birational invariant in the case of a field $k$ of characteristic zero; in the general case this has so far (1977) been proved for dimensions $n\leq3$ only.

References

[1] M. Baldassarri, "Algebraic varieties" , Springer (1956) MR0082172 Zbl 0995.14003 Zbl 0075.15902
[2] F. Hirzebruch, "Topological methods in algebraic geometry" , Springer (1978) (Translated from German) MR1335917 MR0202713 Zbl 0376.14001
How to Cite This Entry:
Arithmetic genus. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Arithmetic_genus&oldid=33008
This article was adapted from an original article by I.V. Dolgachev (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article