Mordell–Weil group

Template:Short description In arithmetic geometry, the Mordell–Weil group is an abelian group associated to any abelian variety ${\displaystyle A}$ defined over a number field ${\displaystyle K}$. It is an arithmetic invariant of the Abelian variety. It is simply the group of ${\displaystyle K}$-points of ${\displaystyle A}$, so ${\displaystyle A(K)}$ is the Mordell–Weil group^{[1][2]pg 207}. The main structure theorem about this group is the Mordell–Weil theorem which shows this group is in fact a finitely-generated abelian group. Moreover, there are many conjectures related to this group, such as the Birch and Swinnerton-Dyer conjecture which relates the rank of ${\displaystyle A(K)}$ to the zero of the associated L-function at a special point.

Constructing^[3] explicit examples of the Mordell–Weil group of an abelian variety is a non-trivial process which is not always guaranteed to be successful, so we instead specialize to the case of a specific elliptic curve

. Let

be defined by the Weierstrass equation

${\displaystyle y^2=x(x-6)(x+6)}$

over the rational numbers. It has discriminant

(and this polynomial can be used to define a global model

). It can be found^[3]

${\displaystyle E(\mathbb{Q})\cong \mathbb{Z}/2\times \mathbb{Z}/2\times \mathbb{Z}}$

through the following procedure. First, we find some obvious torsion points by plugging in some numbers, which are

${\displaystyle \mathrm{\infty },(0,0),(6,0),(-6,0)}$

In addition, after trying some smaller pairs of integers, we find

is a point which is not obviously torsion. One useful result for finding the torsion part of

is that the torsion of prime to

, for

having good reduction to

, denoted

injects into

, so

${\displaystyle E(\mathbb{Q}{)}_{\mathrm{t}\mathrm{o}\mathrm{r}\mathrm{s},p}\hookrightarrow E({𝔽}_p)}$

We check at two primes

and calculate the cardinality of the sets

${\displaystyle \begin{array}{cc}\mathrm{\#}E({𝔽}_5)& =8=2^3\\ \mathrm{\#}E({𝔽}_7)& =12=2^2\cdot 3\end{array}}$

note that because both primes only contain a factor of

, we have found all the torsion points. In addition, we know the point

has infinite order because otherwise there would be a prime factor shared by both cardinalities, so the rank is at least

. Now, computing the rank is a more arduous process consisting of calculating the group

where

using some long exact sequences from homological algebra and the Kummer map.

There are many theorems in the literature about the structure of the Mordell–Weil groups of abelian varieties of specific dimension, over specific fields, or having some other special property.

For a hyperelliptic curve

and an abelian variety

defined over a fixed field

, we denote the

the twist of

(the pullback of

to the function field

) by a 1-cocyle

${\displaystyle b\in Z^1(\mathrm{Gal}(k(C)/k(t)),\text{Aut}(A))}$

for Galois cohomology of the field extension associated to the covering map

. Note

which follows from the map being hyperelliptic. More explicitly, this 1-cocyle is given as a map of groups

${\displaystyle G\times G\to \mathrm{Aut}(A)}$

which using universal properties is the same as giving two maps

, hence we can write it as a map

${\displaystyle b=(b_{id},b_{\iota })}$

where

is the inclusion map and

is sent to negative

. This can be used to define the twisted abelian variety

defined over

using general theory of algebraic geometry^{[4]pg 5}. In particular, from universal properties of this construction,

is an abelian variety over

which is isomorphic to

after base-change to

.

For the setup given above,^[5] there is an isomorphism of abelian groups

${\displaystyle A_b(k(t))\cong {\mathrm{Hom}}_k(J(C),A)\oplus A_2(k)}$

where

is the Jacobian of the curve

, and

is the 2-torsion subgroup of

.

• Mordell–Weil theorem

• The Mordell–Weil Group of Curves of Genus 2
• Determining the Mordell–Weil group of a universal elliptic curve
• Galois descent and twists of an abelian variety
• On Mordell–Weil groups of Jacobians over function fields