Spin–orbit interaction: Difference between revisions

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In [[algebraic geometry]], the '''Néron–Severi group''' of a [[algebraic variety|variety]] is
the group of divisors modulo [[algebraic equivalence]]; in other words it is the group of [[Component (group theory)|components]] of the [[Picard scheme]] of a variety. Its rank is called the [[Picard number]].  It is named after [[Francesco Severi]] and [[André Néron]].
 
==Definition==
In the cases of most importance to classical algebraic geometry, for a [[complete variety]] ''V'' that is [[non-singular]], the [[connected space|connected component]] of the Picard scheme is an [[abelian variety]] written
 
:Pic<sup>0</sup>(''V'')
 
and the quotient
 
:Pic(''V'')/Pic<sup>0</sup>(''V'')
 
is an abelian group NS(''V''), called the '''Néron–Severi group''' of ''V''. This is a [[finitely-generated abelian group]] by the Néron–Severi theorem, which was proved by Severi over the complex numbers and by Néron over more general fields.
 
In other words the Picard group fits into an [[exact sequence]]
 
:<math>1\to \mathrm{Pic}^0(V)\to\mathrm{Pic}(V)\to \mathrm{NS}(V)\to 0</math>
 
The fact that the rank is finite is [[Francesco Severi]]'s '''theorem of the base'''; the rank is the '''Picard number''' of ''V'', often denoted ρ(''V''). The elements of finite order are called Severi divisors, and form a finite group which is a birational invariant and whose order is called the '''Severi number'''. Geometrically NS(''V'') describes the [[algebraic equivalence]] classes of [[divisor (algebraic geometry)|divisors]] on ''V''; that is, using a stronger, non-linear equivalence relation in place of [[linear equivalence of divisors]], the classification becomes amenable to discrete invariants. Algebraic equivalence is closely related to [[numerical equivalence]], an essentially topological classification by [[intersection number]]s.
 
==First Chern class and integral valued 2-cocycles==
The [[exponential sheaf sequence]]
:<math>0\to 2\pi i\mathbb Z \to \mathcal O_V\to\mathcal O_V^*\to 0</math>  
gives rise to a long exact sequence featuring
:<math>\cdots \to H^1(V, \mathcal O_V^*)\to H^2(V, \mathbb Z)\to H^2(V,\mathcal O_V)\to \cdots.</math>
The first arrow is the [[first Chern class]] on the [[Picard group]]
:<math>c_1 : \mathrm {Pic}(V)\to H^2(V, \mathbb Z),</math>
and the second
:<math>\exp^* : H^2(V, 2i\pi \mathbb Z)\to H^2(V,\mathcal O_V).</math>
The Neron-Severi group can be identified with the image of the first Chern class, or equivalently, by exactness, as the kernel of the second arrow exp*.  
 
In the complex case, the Neron-Severi group is therefore the group of 2-cocycles whose [[Poincaré dual]] is represented by a complex hypersurface, that is, a [[Weil divisor]].
 
==References==
*{{springer|id=N/n066300|title=Néron–Severi group|author=V.A. Iskovskikh}}
*A. Néron,  ''Problèmes arithmétiques et géometriques attachée à la notion de rang d'une courbe algébrique dans un corps''  Bull. Soc. Math. France, 80  (1952)  pp.&nbsp;101–166
*A. Néron,  ''La théorie de la base pour les diviseurs sur les variétés algébriques'', Coll. Géom. Alg. Liège, G. Thone  (1952)  pp.&nbsp;119–126
* F. Severi,  ''La base per le varietà algebriche di dimensione qualunque contenute in una data e la teoria generale delle corrispondénze fra i punti di due superficie algebriche''  Mem. Accad. Ital., 5  (1934)  pp.&nbsp;239–283
 
{{DEFAULTSORT:Neron-Severi Group}}
[[Category:Algebraic geometry]]

Revision as of 20:37, 18 November 2013

In algebraic geometry, the Néron–Severi group of a variety is the group of divisors modulo algebraic equivalence; in other words it is the group of components of the Picard scheme of a variety. Its rank is called the Picard number. It is named after Francesco Severi and André Néron.

Definition

In the cases of most importance to classical algebraic geometry, for a complete variety V that is non-singular, the connected component of the Picard scheme is an abelian variety written

Pic0(V)

and the quotient

Pic(V)/Pic0(V)

is an abelian group NS(V), called the Néron–Severi group of V. This is a finitely-generated abelian group by the Néron–Severi theorem, which was proved by Severi over the complex numbers and by Néron over more general fields.

In other words the Picard group fits into an exact sequence

1Pic0(V)Pic(V)NS(V)0

The fact that the rank is finite is Francesco Severi's theorem of the base; the rank is the Picard number of V, often denoted ρ(V). The elements of finite order are called Severi divisors, and form a finite group which is a birational invariant and whose order is called the Severi number. Geometrically NS(V) describes the algebraic equivalence classes of divisors on V; that is, using a stronger, non-linear equivalence relation in place of linear equivalence of divisors, the classification becomes amenable to discrete invariants. Algebraic equivalence is closely related to numerical equivalence, an essentially topological classification by intersection numbers.

First Chern class and integral valued 2-cocycles

The exponential sheaf sequence

02πi𝒪V𝒪V*0

gives rise to a long exact sequence featuring

H1(V,𝒪V*)H2(V,)H2(V,𝒪V).

The first arrow is the first Chern class on the Picard group

c1:Pic(V)H2(V,),

and the second

exp*:H2(V,2iπ)H2(V,𝒪V).

The Neron-Severi group can be identified with the image of the first Chern class, or equivalently, by exactness, as the kernel of the second arrow exp*.

In the complex case, the Neron-Severi group is therefore the group of 2-cocycles whose Poincaré dual is represented by a complex hypersurface, that is, a Weil divisor.

References

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  • A. Néron, Problèmes arithmétiques et géometriques attachée à la notion de rang d'une courbe algébrique dans un corps Bull. Soc. Math. France, 80 (1952) pp. 101–166
  • A. Néron, La théorie de la base pour les diviseurs sur les variétés algébriques, Coll. Géom. Alg. Liège, G. Thone (1952) pp. 119–126
  • F. Severi, La base per le varietà algebriche di dimensione qualunque contenute in una data e la teoria generale delle corrispondénze fra i punti di due superficie algebriche Mem. Accad. Ital., 5 (1934) pp. 239–283