Néron model


In algebraic geometry, the Néron model
for an abelian variety AK defined over the field of fractions K of a Dedekind domain R is the "push-forward" of AK from Spec to Spec, in other words the "best possible" group scheme AR defined over R corresponding to AK.
They were introduced by for abelian varieties over the quotient field of a Dedekind domain R with perfect residue fields, and extended this construction to semiabelian varieties over all Dedekind domains.

Definition

Suppose that R is a Dedekind domain with field of fractions K, and suppose that AK is a smooth separated scheme over K. Then a Néron model of AK is defined to be a smooth separated scheme AR over R with fiber AK that is universal in the following sense.
In particular, the canonical map is an isomorphism. If a Néron model exists then it is unique up to unique isomorphism.
In terms of sheaves, any scheme A over Spec represents a sheaf on the category of schemes smooth over Spec with the smooth Grothendieck topology, and this has a pushforward by the injection map from Spec to Spec, which is a sheaf over Spec. If this pushforward is representable by a scheme, then this scheme is the Néron model of A.
In general the scheme AK need not have any Néron model.
For abelian varieties AK Néron models exist and are unique and are commutative quasi-projective group schemes over R. The fiber of a Néron model over a closed point of Spec is a smooth commutative algebraic group, but need not be an abelian variety: for example, it may be disconnected or a torus. Néron models exist as well for certain commutative groups other than abelian varieties such as tori, but these are only locally of finite type. Néron models do not exist for the additive group.

Properties

The Néron model of an elliptic curve AK over K can be constructed as follows. First form the minimal model over R in the sense of algebraic surfaces. This is a regular proper surface over R but is not in general smooth over R or a group scheme over R. Its subscheme of smooth points over R is the Néron model, which is a smooth group scheme over R but not necessarily proper over R. The fibers in general may have several irreducible components, and to form the Néron model one discards all multiple components, all points where two components intersect, and all singular points of the components.
Tate's algorithm calculates the special fiber of the Néron model of an elliptic curve, or more precisely the fibers of the minimal surface containing the Néron model.