Dual abelian variety

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In mathematics, a dual abelian variety can be defined from an abelian variety A, defined over a field K.

Contents

[edit] History and definition

The theory was first put into a good form when K was the field of complex numbers. In that case there is a general form of duality between the Albanese variety of a complete variety V, and its Picard variety; this was realised, for definitions in terms of complex tori, as soon as André Weil had given a general definition of Albanese variety. For an abelian variety A, the Albanese variety is A itself, so the dual should be Pic0(A), the connected component of what in contemporary terminology is the Picard scheme.

For the case of the Jacobian variety J of a compact Riemann surface C, the choice of a principal polarization of J gives rise to an identification of J with its own Picard variety. This in a sense is just a consequence of Abel's theorem. For general abelian varieties, still over the complex numbers, A is in the same isogeny class as its dual. An explicit isogeny can be constructed by use of an invertible sheaf L on A (i.e. in this case a holomorphic line bundle), when the subgroup

K(L)

of translations on L that take L into an isomorphic copy is itself finite. In that case, the quotient

A/K(L)

is isomorphic to the dual abelian variety Â.

This construction of  extends to any field K of characteristic zero.[1] In terms of this definition, the Poincaré bundle, a universal line bundle can be defined on

A × Â.

The construction when K has characteristic p uses scheme theory. The definition of K(L) has to be in terms of a group scheme that is a scheme-theoretic stabilizer, and the quotient taken is now a quotient by a subgroup scheme.[2]

[edit] Dual isogeny (elliptic curve case)

Given an isogeny

f : E \rightarrow E'

of elliptic curves of degree n, the dual isogeny is an isogeny

\hat{f} : E' \rightarrow E

of the same degree such that

f \circ \hat{f} = [n].

Here [n] denotes the multiplication-by-n isogeny e\mapsto ne which has degree n2.

[edit] Construction of the dual isogeny

Often only the existence of a dual isogeny is needed, but the construction is explicit as

 E'\rightarrow \mbox{Div}^0(E')\to\mbox{Div}^0(E)\rightarrow E\,

where Div0 is the group of divisors of degree 0. To do this, we need maps E \rightarrow {\mbox{Div}}^0(E) given by P\to P - O where O is the neutral point of E and {\mbox{Div}}^0(E) \rightarrow E\, given by \sum n_P P \to \sum n_P P.

To see that f \circ \hat{f} = [n], note that the original isogeny f can be written as a composite

 E \rightarrow {\mbox{Div}}^0(E)\to {\mbox{Div}}^0(E')\to E'\,

and that since f is finite of degree n, f * f * is multiplication by n on Div0(E').

Alternatively, we can use the smaller Picard group Pic0, a quotient of Div0. The map E\rightarrow {\mbox{Div}}^0(E) descends to an isomorphism, E\to{\mbox{Pic}}^0(E). The dual isogeny is

 E' \to {\mbox{Pic}}^0(E')\to {\mbox{Pic}}^0(E)\to E\,

Note that the relation f \circ \hat{f} = [n] also implies the conjugate relation \hat{f} \circ f = [n]. Indeed, let \phi = \hat{f} \circ f. Then \phi \circ \hat{f} = \hat{f} \circ [n] = [n] \circ \hat{f}. But \hat{f} is surjective, so we must have φ = [n].

[edit] Notes

  1. ^ Mumford, Abelian Varieties, pp.74-80
  2. ^ Mumford, Abelian Varieties, p.123 onwards

[edit] References

This article incorporates material from Dual isogeny on PlanetMath, which is licensed under the GFDL.