Yafaev: Descent on certain Shimura curves

Joint work with A. Skorobogatov.

Let be an indefinite division quaternion algebra over $\mathbb{Q}$ (indefinite means that $\mathbb{R}\tensor B = M_2(\mathbb{R})$ ). Let $\mathcal{O}_B$ be a maximal order in . Let be the discriminant of (the product of primes that do not split ), and suppose . Let $\mathbb{H}^{\pm}$ be the union of the upper and lower half planes and consider the Shimura curve

$\displaystyle S = \mathcal{O}_B^\times \backslash \mathbb{H}^{\pm}.$

Then

is a compact Riemann surface

with a canonical model over $\mathbb{Q}$ .

Let be a prime, . Let $\Gamma_0(N)$ , $\Gamma_1(N)$ be the inverse images in $\mathcal{O}_B^\times$ of the usual subgroups of $GL_2(\mathbb{Z}/N)$ . Let $X = \Gamma_1(N)\backslash\mathbb{H}^{\pm}$ , $Y = \Gamma_0(N)\backslash\mathbb{H}^{\pm}$ . Then $X \rightarrow Y$ is a Galois covering, with Galois group $\mathbb{Z}/N\mathbb{Z}^\times$ , which is unramified if $\exists p, q \vert D$ such that $p \equiv 1 \pmod{4}$ , $q\equiv 1 \pmod{3}$ .

$\begin{theorem}[Shimura] We have $S(\mathbb{R}) = \emptyset$, and if $k$\ is im... ... M_2(k)$, and $\vert Cl(k)\vert = 1$, then $S(k) \neq \emptyset$. \end{theorem}$

Jordan and Livne gave a complete description of points of over local fields.
Jordan gave some results on points of over imaginary quadratic fields. For example, if , $k = \mathbb{Q}(\sqrt{-3})$ , then does not satisfy the Hasse Principle.
Skorobogatov and Siksek showed that if does not have a -rational divisor class of degree 1 and $\Sh({\mathrm{Jac}}(S_k))$ is finite, then the failure of the Hasse Principle for is accounted for by the Manin obstruction.

Consider now the covering $X \rightarrow Y$ of curves over $\mathbb{Q}$ , as defined above. We want to find an imaginary quadratic field and and such that for any twist of by a character ${\mathrm{Gal}}(\overline{k}/k) \xrightarrow{\sigma}{} (\mathbb{Z}/N)^\times/\pm 1$ , $X^\sigma(\mathbb{A}_k) = \emptyset$ but $Y(\mathbb{A}_k) \neq \emptyset$ . Since, as in Skorobogatov's talk, $Y(k) = \bigcup_\sigma X^\sigma(k)$ , this shows that the Hasse principle for fails and provides a cohomological obstruction that explains this failure.

Suppose first that $v \vert p$ for a prime dividing . Then has bad reduction at . Furthermore, it is known (Jordan-Livne-Varshavsky) that $Y(k_v) \neq \emptyset$ if is inert. So we suppose that all primes dividing are inert in .

Now consider what happens at . We have the usual model of $Y_{\mathbb{F}_N}$ with two components $S_{\mathbb{F}_N}$ , intersecting at supersingular points defined over $\mathbb{F}_{N^2}$ . We assume again that is inert. It can be shown that $\vert S(\mathbb{F}_{N^2}) \setminus \{$ Supersingular Points $\}\vert > 0$ . This then shows that if is inert, $Y(k_v) \neq \emptyset$ for $v\vert N$ .

Finally, we consider places which do not divide . If $\sigma: {\mathrm{Gal}}(\overline{k}/k) \rightarrow (\mathbb{Z}/N)^\times/\pm 1$ is ramified at such a place , $X^\sigma(k_v) = \emptyset$ . So we need only consider characters unramified outside . If we suppose further

that is prime to for any $p\vert D$
$\vert Cl(k)\vert$ is prime to

then we are left with characters corresponding to $\mathbb{Q}(\zeta_N)^+k/k$ .

Now, and $X^\sigma$ have good reduction outside . To deal with places $v\notdivides ND$ , we count points to show that the curve has points over $\mathbb{F}_v$ (which is $\mathbb{F}_{p}$ or $\mathbb{F}_{p^2}$ according as is split or inert in ), then lift them using Hensels Lemma.

The point counts make use of the following trace formulas: $p \notdivides ND$ then

$\displaystyle {\mathrm{Tr}}(F_p^r\vert H^1_{\text{\'et}}(Y_{\overline{\mathbb{F}}_p}, \mathbb{Q}_\ell))$	$\displaystyle =$	$\displaystyle {\mathrm{Tr}}(pT_{p^{r-2}} - T_{p^r}\vert H^0(Y_{\overline{\mathbb{F}}_p}, \Omega^1))$
$\displaystyle {\mathrm{Tr}}(F_p^r\vert H^1_{\text{\'et}}(X^\sigma_{\overline{\mathbb{F}}_p}, \mathbb{Q}_\ell))$	$\displaystyle =$	$\displaystyle {\mathrm{Tr}}(\gamma^r pT_{p^{r-2}} - \gamma^r T_{p^r}\vert H^0(X_{\overline{F}_p}, \Omega^1))$

where

is Frobenius and $\gamma = \sigma(F_p)$ . We get $Y(\mathbb{F}_{p^2})\vert > 0$ , and $Y(\mathbb{F}_p)\vert > 0$ if $\exists t \in \mathbb{Z}$ , $\vert t\vert < 2\sqrt{p}$ such that

all primes dividing are split in $\mathbb{Q}(\sqrt{t^2-4p})$
$p \notdivides t$ or is not split in $\mathbb{Q}(\sqrt{t^2-4p})$
is not inert in $\mathbb{Q}(\sqrt{t^2-4p})$ .

Putting these together we get the following proposition:
$\begin{proposition}[Local points on $X^\sigma$] Suppose that for all $m \in \{ 0... ...acters $\sigma$\ we have $X^\sigma(\mathbb{A}_k) = \emptyset$. \end{proposition}$
We can now find counterexamples to the Hasse principle as follows:

Choose , with $q_1 \equiv 1 \pmod{4}$ and $q_2 \equiv 1 \pmod{3}$ .
Choose such that is coprime to .
Let be a prime such that $p \notdivides ND$ . Call good if there exists such that condition above is satisfied, bad otherwise. (The set of bad primes is finite.) Now find a good such that () is satisfied.
Now choose a field imaginary quadratic such that are inert in , bad primes are inert, primes from Step are split or ramified, and $\vert Cl(k)\vert$ is prime to . Ono can prove that if there is one satisfying these conditions there are infinitely many.

Example: , , $k = \mathbb{Q}(\sqrt{-127})$ .

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