2.1 Classifying $\mu _p$ -covers

Let X be a proper variety over a field F. Let $\mu _p$ be the F-group scheme of p-th roots of unity. A $\mu _p$ -cover of Y (or more formally, a $\mu _p$ -torsor over Y in the fppf topology) is a Y-scheme X together with a $\mu _p$ -action that is simply transitive on fibers over Y. The $\mu _p$ -covers of Y form a category $\mathcal {M}_p(Y)$ whose morphisms are $\mu _p$ -equivariant isomorphisms. The following proposition gives a concrete way to think about $\mu _p$ -covers.

Proof. This is well known (see [Reference Arsie and Vistoli1] or [Reference Mumford29, pg. 71]), so we just describe the functors in both directions. If $\pi \colon X \to Y$ is a $\mu _p$ -cover, then there is a $\mathbb {Z}/p\mathbb {Z}$ -grading on the $\mathcal {O}_Y$ -module

$$\begin{align*}\pi_*\mathcal{O}_X = \mathcal{O}_Y \oplus \bigoplus_{i = 1}^{p-1} \mathcal{L}_i\end{align*}$$

where each $\mathcal {L}_i$ is the invertible subsheaf of $\pi _*\mathcal {O}_X$ on which $\mu _p$ acts by $\zeta \cdot s = \zeta ^i s$ . The algebra structure of $\pi _*\mathcal {O}_X$ gives isomorphisms $\mathcal {L}_i \otimes \mathcal {L}_j \simeq \mathcal {L}_{i + j}$ , where indices are to be taken modulo p and where $\mathcal {L}_0 = \mathcal {O}_Y$ . Thus, we obtain an isomorphism $\mathcal {L}_1^{\otimes p} \simeq \mathcal {O}_Y$ . Conversely, starting with a pair $(\mathcal {L},\eta )$ , we can define a sheaf of $\mathcal {O}_Y$ -algebras $\mathcal {O}_Y \oplus \bigoplus _{i = 1}^{p-1} \mathcal {L}^i$ using the given isomorphism $\eta $ to define the multiplication $\mathcal {L}^i \otimes \mathcal {L}^j \simeq \mathcal {L}^{i+j} \simeq \mathcal {L}^{i+j - p}$ on the factors with $i + j \geq p$ . The relative spectrum of this sheaf over Y is then naturally endowed with a $\mu _p$ -action making it a $\mu _p$ -cover.

2.2 $\mu _p$ -covers of abelian varieties

Let us now specialize to the case where Y is an abelian variety over a field F of characteristic not p. We will think of a $\mu _p$ -cover $\pi \colon X \to Y$ in terms of the corresponding pair $(\mathcal {L}, \eta )$ . The isomorphism class of $\mathcal {L}$ is a well-defined element of $\mathrm {Pic}(Y) = \mathrm {Pic}_Y(F)$ , called the Steinitz class of $\pi $ . The existence of $\eta $ means that $\mathcal {L}$ is p-torsion, so that $\mathcal {L} \in \widehat {Y}[p](F)$ , where $\widehat {Y} = \mathrm {Pic}^0_Y \subset \mathrm {Pic}_Y$ is the dual abelian variety parameterizing algebraically trivial line bundles on Y.

From one $\mu _p$ -cover $(\mathcal {L}, \eta )$ , we may construct many more, simply by scaling $\eta \colon \mathcal {L}^{\otimes p} \to \mathcal {O}_Y$ by any $r \in F^*$ . Two $\mu _p$ -covers $(\mathcal {L}, r\eta )$ and $(\mathcal {L}, s\eta )$ are isomorphic if and only if $r/s\in F^{*p}$ . More generally, given two $\mu _p$ -covers $(\mathcal {L},\eta )$ and $(\mathcal {L}', \eta ')$ , the tensor product $(\mathcal {L} \otimes \mathcal {L}', \eta \otimes \eta ')$ is another. Let $H^1(Y, \mu _p)$ denote the set of isomorphism classes of $\mu _p$ -covers of Y.

Proposition 2.3. The set $H^1(Y, \mu _p)$ is naturally an abelian group and sits in a short exact sequence

$$\begin{align*}0 \to F^*/F^{*p} \to H^1(Y, \mu_p) \to \widehat{Y}[p](F) \to 0.\end{align*}$$

Suppose now that $\pi \colon X \to Y$ is a geometrically connected $\mu _p$ -cover corresponding to $(\mathcal {L}, \eta )$ , so that $\mathcal {L} \not \simeq \mathcal {O}_Y$ . Since every connected finite étale cover of the abelian variety $Y_{\bar F}$ is itself an abelian variety [Reference Mumford29, §18], X becomes an abelian variety over the algebraic closure $\overline {F}$ . It follows that X is a torsor for a certain abelian variety, which we will now identify.

Let $ \widehat {\psi } \colon \widehat {Y} \to \widehat {Y}/\langle \mathcal {L} \rangle $ be the degree p isogeny obtained by modding out by $\mathcal {L}$ . Let $\psi \colon A_{\mathcal {L}} \to Y$ be the dual isogeny, which is also of degree p. Then $\psi $ can itself be given the structure of $\mu _p$ -cover. Indeed, we have

$$\begin{align*}\ker(\psi) \simeq \widehat{\ker(\widehat{\psi})} \simeq \widehat{\mathbb{Z}/p\mathbb{Z}} = \mathrm{Hom}(\mathbb{Z}/p\mathbb{Z}, \mathbb{G}_m) \simeq \mu_p.\end{align*}$$

Note that there are $p-1$ different isomorphisms $\ker (\psi ) \simeq \mu _p$ , corresponding to the different $\mathbb {Z}/p\mathbb {Z}$ -gradings we can put on $\psi _*\mathcal {O}_{A_{\mathcal {L}}}$ . Exactly one of them will have the property that the corresponding $\mu _p$ -cover has Steinitz class $\mathcal {L}_1 \subset \psi _*\mathcal {O}_{A_{\mathcal {L}}}$ isomorphic to $\mathcal {L}$ . We choose this $\mu _p$ -cover structure for $\psi $ .

Proof. If $\psi \colon A_{\mathcal {L}} \to Y$ corresponds to $(\mathcal {L}, \eta )$ , then $\pi \colon X \to Y$ corresponds to $(\mathcal {L}, s \eta )$ for some scalar $s \in F^*$ . Over $\bar {F}$ there is an isomorphism $\rho \colon (A_{\mathcal {L}})_{\bar {F}} \to X_{\bar {F}}$ of $\mu _p$ -covers, which satisfies

$$\begin{align*}\rho^g(P) = \sqrt[p]{s}^g/\sqrt[p]{s} + \rho(P)\end{align*}$$

for all $g \in \mathrm {Gal}(\bar F/F)$ and $P \in A_{\mathcal {L}}(\bar {F})$ ; here, $\sqrt [p]{s}^g/\sqrt [p]{s} \in \mu _p$ and $+$ is the torsor action. The torsor structure $A_{\mathcal {L}} \times X \to X$ is given by $(P, Q) \mapsto \rho (P + \rho ^{-1}(Q))$ . Using the formula for $\rho ^g$ , we see that this torsor is indeed defined over F.

We have seen that for each nonzero $\mathcal {L} \in \widehat {Y}[p](F)$ , there is, in fact, a distinguished $\mu _p$ -cover with Steinitz class $\mathcal {L}$ – namely, the cover $A_{\mathcal {L}} \to Y$ . This means there must be a distinguished isomorphism $\eta \colon \mathcal {L}^p \simeq \mathcal {O}_Y$ . We will describe this isomorphism $\eta $ in Lemma 3.6, in the context of rational points. For simplicity, we will specialize to the case where Y is a Jacobian, and in particular principally polarized (so that $\widehat {Y} \simeq Y$ ). However, most of what we prove can be generalized to arbitrary abelian varieties in a straightforward way.

2.3 $\mu _p$ -covers of Jacobians

Let C be a smooth projective geometrically integral curve over F, and let $J = \mathrm {Pic}^0(C)$ be its Jacobian. Let g be the genus of C, and hence also the dimension of the abelian variety J. Let $D \in J[p](F)$ be a divisor class of order p. Let $J \to J/\langle D \rangle $ be the quotient and let $\psi \colon A_D\to \widehat {J}$ be the corresponding dual isogeny, where $A_D$ is the dual of $J/\langle D \rangle $ . Then $\psi $ is a $\mu _p$ -cover of $\widehat {J}$ corresponding to a pair $(\mathcal {L}, \eta )$ , as in the previous section.

From now on, we identify J and $\widehat {J}$ via the principal polarization $\lambda \colon J \to \widehat J$ coming from the theta divisor of the curve C. To make this explicit, we assume that C contains a rational point $\infty \in C(F)$ . The theta divisor $\Theta \subset J$ is the subvariety of degree 0 divisor classes of the form $E - (g-1)\infty $ , where E is an effective divisor of degree $g -1$ . The isomorphism $J \to \widehat {J}$ sends P to $t_P^*\mathcal {O}_J(\Theta ) \otimes \mathcal {O}_J(\Theta )^{-1}$ , where $t_P \colon J \to J$ is translation by P. We can also describe $\lambda (P)$ as the line bundle on J associated to the divisor $[\Theta - P] - [\Theta ]$ .

After making the identification $J \simeq \widehat {J}$ , we may view $\psi $ as a $\mu _p$ -cover of J and $\eta $ as an isomorphism $\mathcal {L}^{\otimes p} \to \mathcal {O}_J$ . By Proposition 2.3, we have the exact sequence

$$\begin{align*}0 \to F^*/F^{*p} \to H^1(J, \mu_p) \to J[p](F) \to 0. \end{align*}$$

3.1 Descent over general fields

Fix $D \in J[p](F)$ and $(\mathcal {L}, \eta )$ , as above. Given $P \in J(F)$ , we may consider the $\mu _p$ -cover $\psi _P = t_P \circ \psi \colon A_D \to J$ , where $t_P \colon J \to J$ is translation by P. The $\mu _p$ -cover $\psi _P$ is endowed with the same $\mu _p$ -action as $\psi $ , but different structure map to J. Since the Steinitz class is in $\mathrm {Pic}^0(J)$ , it is invariant under translation, and hence, $\psi _P$ and $\psi $ have isomorphic Steinitz classes. If $\psi _P = (\mathcal {L}', \eta ')$ , then we can choose an isomorphism $\mathcal {L}' \simeq \mathcal {L}$ , and under this isomorphism, we have $\eta ' = r_P \eta $ for some $r_P \in F^*$ . Any other choice of isomorphism $\mathcal {L}' \simeq \mathcal {L}$ differs by a scalar, so the element $r_P$ is well defined up to $F^{*p}$ .

For completeness, we state the following result, connecting the map $\partial ^D$ to a boundary map in Galois cohomology:

Lemma 3.2. The map $\partial ^D$ is the boundary map $J(F) \to H^1(F, \mu _p) \simeq F^*/F^{*p}$ in the long exact sequence in group cohomology for the short exact sequence of $\mathrm {Gal}(\bar F/F)$ -modules

$$\begin{align*}0 \to \mu_p \to A_D(\bar F) \stackrel{\psi}{\longrightarrow} J(\bar F) \to 0. \end{align*}$$

The following lemma is immediate from the definitions and can be used to give an explicit formula for the homomorphism $\partial ^D$ .

Thinking of $\eta ^{-1}$ as a function on J allows us to distinguish the unique $\mu _p$ -cover $(\mathcal {L}, \eta )$ corresponding to $\psi \colon A_D \to J$ among all $\mu _p$ -covers with Steinitz class $\mathcal {L}$ , as promised.

Let $\mathrm {Sym}^g C = C^g/S_g$ be the g-th symmetric power of C. Points of $\mathrm {Sym}^g C$ correspond to effective degree g divisors E on C. Recall that the map $\mathrm {Sym}^g C \to J$ sending $E \mapsto E - g\infty $ is birational [Reference Milne, Cornell and Silverman27, Thm. 5.1], and hence induces an isomorphism of function fields $F(\mathrm {Sym}^g C) \simeq F(J)$ .

Proof. Assume, for simplicity, that $D = \infty - Q$ for some $Q \in C(F)$ . Under the polarization $J \to \widehat {J}$ , the point D gets sent to the divisor $[\Theta - D] - [\Theta ]$ . Note that

$$\begin{align*}\Theta - D = \{E + Q - g\infty \colon E \, \mbox{effective of degree } g-1\}\end{align*}$$

is the locus of poles of the function f. Similarly, $\Theta $ is the zero locus. Taking into account multiplicities, the divisor of f is $p[\Theta - D] - p[\Theta ]$ , as claimed. The general case where $D = \sum _j (\infty - Q_j)$ is similar.

Finally, we will use a generalization of the map $\partial $ and Lemma 3.1. Let $H = \{D_1, \ldots , D_m\} \subset J[p](F)$ be a subset of $\mathbb {F}_p$ -linearly independent elements. For each $i = 1, \ldots , m$ , let $\psi _i \colon A_i \to J$ be the $\mu _p$ -covers corresponding to $D_i$ . Let $A_H = \widehat {J/\langle H\rangle }$ and let $\psi _H \colon A_H \to J$ be the isogeny dual to $J \to J/\langle H\rangle $ . Then we have a homomorphism

$$\begin{align*}\tilde \partial^H \colon J(F) \longrightarrow \prod_{i = 1}^m F^*/F^{*p}\end{align*}$$

sending P to $(\partial ^{D_1}(P), \ldots , \partial ^{D_m}(P))$ .

Proof. We prove this in the case $m = 2$ , which is the only case we will use. The general case follows by an inductive argument. Suppose $\tilde \partial ^{D_1}(P) = 0$ and $\tilde \partial ^{D_2}(P) = 0$ , so that $P = \psi _i(Q_i)$ for some $Q_i \in A_i(F)$ by Lemma 3.1. Let $g_i \colon A_H \to A_i$ be the natural maps, of degree p; note that $\psi _1 g_1 = \psi _2 g_2$ . The fiber diagram

(3.1) $$ \begin{align} \begin{array}{ccc} A_H &\longrightarrow&A_2 \\ \downarrow & &\downarrow \\ A_1& \longrightarrow&J\\ \end{array} \end{align} $$

shows that there is a unique point Q in $A_H(\bar F)$ such that $g_i(Q) = Q_i$ for $i = 1,2$ . The uniqueness of Q implies that it is $\mathrm {Gal}(\bar F/F)$ -stable, and so we have $P = \psi _H(Q)$ with $Q \in A_H(F)$ . This shows that $\partial ^H$ is injective.

3.2 Descent over global fields

Suppose now that C is a curve over $\mathbb {Q}$ . The preceding discussion applies for $F =\mathbb {Q}$ , but also for $F =\mathbb {Q}_{\ell }$ for any prime $\ell \leq \infty $ . Having fixed $D \in J[p](\mathbb {Q})$ , let

$$\begin{align*}\mathrm{Sel}(A_D) \subset \mathbb{Q}^*/\mathbb{Q}^{*p} \end{align*}$$

be the subgroup of classes r with the property that for every prime $\ell $ , the class of r in $\mathbb {Q}_{\ell }^*/\mathbb {Q}_{\ell }^{*p}$ is in the image of $\partial ^D \colon J(\mathbb {Q}_{\ell })/\psi (A_D(\mathbb {Q}_{\ell })) \to \mathbb {Q}_{\ell }^*/\mathbb {Q}_{\ell }^{*p}$ . In other words, an element of $\mathrm {Sel}(A_D)$ is a $\mu _p$ -cover $X \to J$ with Steinitz class D and such that $X(\mathbb {Q}_{\ell }) \neq \emptyset $ for every prime $\ell $ .

Recall that if A is an abelian variety over $\mathbb {Q}$ , then is the group of A-torsors which are trivial over $\mathbb {Q}_{\ell }$ , for all primes $\ell \leq \infty $ .

Proposition 3.9. Let be the Tate-Shafarevich group of $A_D$ . There is an exact sequence

where is the kernel of the map induced by $\psi $ .

The group $\mathrm {Sel}(A_D)$ is isomorphic to the usual Selmer group

$$\begin{align*}\mathrm{Sel}_\psi(A_D) \subset H^1(F, A_D[\psi]) \simeq H^1(F, \mu_p) \simeq F^*/F^{*p}.\end{align*}$$

In particular, it is finite. This can also be seen from the following proposition.

We will also consider more general Selmer groups. Given a subset $H = \{D_1, \ldots , D_m\} \subset J[p](F)$ of linearly independent elements, we can define an analogous Selmer group $\mathrm {Sel}(A_H) \subset \prod _{i = 1}^m F^*/F^{*p}$ which sits in an exact sequence

and which is isomorphic to the usual Selmer group $\mathrm {Sel}_{\psi _H}(A_H)$ .

4.1 A special family of curves

Let $p> 5$ be a prime and let $e_0, e_1,e_2$ be distinct integers. Let C be the smooth projective curve over $\mathbb {Q}$ with affine model

(4.1) $$ \begin{align} y^p = (x-e_0)(x-e_1)(x-e_2). \end{align} $$

There is no loss in generality in assuming $e_0 = 0$ , so we will do so. The affine model is itself smooth, and its complement in C is a single rational point we call $\infty $ . The genus of C is $g = p-1$ . For more details on such curves, see [Reference Poonen and Schaefer30].

Let J be the Jacobian of C. Note that $J(\mathbb {Q})$ has p-torsion of rank at least $2$ , generated by the three divisor classes $D_i = [(e_i,0) - \infty ]$ , for $i \in \{0,1,2\}$ . The equality of divisors $D_0 + D_1 + D_2 = \mathrm {div}(y)$ means that $D_0 + D_1 + D_2 = 0$ in J. Let $D = D_0 + D_1$ and define the abelian varieties

(4.2) $$ \begin{align} {\widehat{A}} = J/\langle D_0, D_1 \rangle \end{align} $$

(4.3) $$ \begin{align} {\widehat{B}} = J/\langle D \rangle \end{align} $$

and the corresponding quotient isogenies ${\widehat \phi } : J \rightarrow {\widehat {A}}$ and ${\widehat \psi } \colon J \to {\widehat {B}}$ . As before, we identify J with its dual via the canonical principal polarization, so that we may write $\phi : A \to J$ and $\psi \colon B \to J$ for the dual isogenies. We also define $A_{D_i}$ to be the dual of $J/\langle D_i\rangle $ for $i = 0,1,2$ with isogenies $\psi _i \colon A_{D_i} \to J$ . We have $B \simeq A_{D_2}$ since $D = -D_2$ .

Let $H = \langle D_0, D_1\rangle $ , and define the map

(4.4) $$ \begin{align} \begin{aligned} \partial^H : &J(\mathbb{Q})/\phi\bigl( A(\mathbb{Q}) \bigr) \longrightarrow {\mathbb{Q}}^*/\mathbb{Q}^{*p} \times {\mathbb{Q}}^*/\mathbb{Q}^{*p},\\ &\left[ \sum_{j=1}^g (x_j,y_j) - g \cdot \infty \right] \mapsto \Bigl( \prod_{j=1}^g x_j,\ \prod_{j=1}^g (x_j - e_1) \Bigr) \end{aligned} \end{align} $$

as in Lemmas 3.5 and 3.7 of Section 2.3. In the above definition, each $x_j,y_j \in \overline {\mathbb {Q}}$ , the divisor $\sum _{j=1}^g (x_j,y_j) - g \cdot \infty $ is Galois stable, and the left-hand side is its divisor class. That such representatives exist follows from the fact that $C(\mathbb {Q}) \neq \emptyset $ [Reference Schaefer34, Prop. 2.7]. The above description of $\partial ^H$ applies whenever it makes sense – that is, when all $x_j$ and $x_j - e_1$ are nonzero. Every class in $J(\mathbb {Q})/\phi \bigl ( A(\mathbb {Q}) \bigr )$ can be represented by such a divisor [Reference Lang21, pg.166].

For $i \in \{1,2,3\}$ , we have similar homomorphisms

(4.5) $$ \begin{align} \begin{aligned} \partial^{D_i} :&J(\mathbb{Q})/\psi_i\bigl( A_{D_i}(\mathbb{Q}) \bigr) \longrightarrow {\mathbb{Q}}^*/\mathbb{Q}^{*p},\\ &\left[ \sum_{j=1}^g (x_j,y_j) - g \cdot \infty \right] \mapsto \prod_{j=1}^g \Bigl( x_j - e_i \Bigr), \end{aligned} \end{align} $$

as well as the homomorphism

(4.6) $$ \begin{align} \begin{aligned} \partial^{D} :&J(\mathbb{Q})/\psi\bigl( B(\mathbb{Q}) \bigr) \longrightarrow {\mathbb{Q}}^*/\mathbb{Q}^{*p},\\ &\left[ \sum_{j=1}^g (x_j,y_j) - g \cdot \infty \right] \mapsto \prod_{j=1}^g \Bigl( x_j(x_j - e_1) \Bigr). \end{aligned} \end{align} $$

As before, the description of these maps is for representative divisors for which it makes sense. However, note that by the equation for the curve, we have $\partial ^{D_0} \cdot \partial ^{D_1} \cdot \partial ^{D_2} = 1$ . This allows us to describe the maps $\partial ^{D_i}$ even on points where the formula above is not well defined. For example,

Lemma 4.1. We have

$$\begin{align*}\partial^H(\left[(0,0)-\infty\right]) = [ e_1^{-1}e_2^{-1}, -e_1 ]\end{align*}$$

and

$$\begin{align*}\partial^H( \left[(e_1,0)-\infty\right]) = [e_1, e_1^{-1}(e_1 - e_2)^{-1} ].\end{align*}$$

In the next section, we will make critical use of the following commutative diagram

(4.7) $$ \begin{align} \begin{array}{ccc} J(\mathbb{Q})/\phi\bigl( A(\mathbb{Q}) \bigr) &\overset{\partial^H}{\longrightarrow}&{\mathbb{Q}}^*/\mathbb{Q}^{*p}\times {\mathbb{Q}}^*/\mathbb{Q}^{*p}\\ \downarrow & &\downarrow \\ J(\mathbb{Q})/\psi\bigl(B(\mathbb{Q})\bigr)&\overset{\partial^D} {\longrightarrow}&{\mathbb{Q}}^*/\mathbb{Q}^{*p},\\ \end{array} \end{align} $$

whose right vertical map is $[r_1,r_2] \mapsto r_1r_2$ .

4.2 Models

There are simple birational models for the $\mu _p$ -covers of J with a given Steinitz class. For concreteness, assume that the Steinitz class is $D = D_0 + D_1$ . The distinguished $\mu _p$ -cover with this Steinitz class is the cover $B \to J$ . A birational model for J is given by the equations

$$\begin{align*}y_i^p = x_i(x_i - e_1)(x_i - e_2)\end{align*}$$

for $i = 1,\ldots , g$ , modulo the action of $S_g$ . By Lemmas 3.5, 3.6 and 3.7, a birational model for B is given by the same g equations above along with the additional equation

$$\begin{align*}z^p = \prod_{i = 1}^g x_i(x_i - e_1),\end{align*}$$

all modulo the action of $S_g$ . Similarly, if $r \in \mathbb {Q}^\times $ , then the $\mu _p$ -cover corresponding to $(\mathcal {L}, r\eta )$ is given by the same equations, with the last one twisted by r:

$$\begin{align*}y_i^p = x_i(x_i - e_1)(x_i - e_2)\end{align*}$$

for $i = 1,\ldots , g$ and

$$\begin{align*}rz^p = \prod_{i = 1}^g x_i(x_i - e_1), \end{align*}$$

again modulo the action of $S_g$ .