2.1 The field K

Let $\Gamma $ be the set of automorphisms $\gamma $ of the field E for which there is a primitive Dirichlet character $\chi _\gamma $ that satisfies

(2.1) $$ \begin{align} \gamma(a_p) = \chi_\gamma(p) a_p \end{align} $$

for all primes $p\nmid N$ . The set of primes p with $a_p\neq 0$ has density $1$ since f is non-CM, so the image of $\chi _\gamma $ lies in $E^\times $ and the character $\chi _\gamma $ is uniquely determined from $\gamma $ .

Define M to be N or $4N$ if N is odd or even, respectively. The conductor of $\chi _\gamma $ divides M (cf. [Reference Momose12, Remark 1.6]). Moreover, there is a quadratic Dirichlet character $\alpha $ with conductor dividing M and an integer i such that $\chi _\gamma $ is the primitive character coming from $\alpha \varepsilon ^i$ (cf. [Reference Momose12, Lemma 1.5(i)]).

For each prime $p\nmid N$ , we have (cf. [Reference Ribet15, p. 21]), so complex conjugation induces an automorphism $\gamma $ of E and $\chi _\gamma $ is the primitive character coming from $\varepsilon ^{-1}$ . In particular, $\Gamma \neq 1$ if $\varepsilon $ is nontrivial.

The set $\Gamma $ is in fact an abelian subgroup of $\operatorname {\mathrm {Aut}}(E)$ (cf. [Reference Momose12, Lemma 1.5(ii)]). Denote by $E^{\Gamma }$ the fixed field of E by $\Gamma $ .

Proof Take any $p\nmid N$ . For each $\gamma \in \Gamma $ , we have

$$\begin{align*}\gamma(r_p) = \gamma(a_p^2)/\gamma(\varepsilon(p)) = \chi_\gamma(p)^2 a_p^2/\gamma(\varepsilon(p)) = a_p^2/\varepsilon(p) = r_p, \end{align*}$$

where we have used that $\chi _\gamma (p)^2 = \gamma (\varepsilon (p))/\varepsilon (p)$ (cf. [Reference Momose12, Proof of Lemma 1.5(ii)]). This shows that $r_p$ belong in $E^{\Gamma} $ and hence $K\subseteq E^{\Gamma} $ since $p\nmid N$ was arbitrary. To complete the proof of the lemma, it thus suffices to show that $E^{\Gamma} ={\mathbb Q}(r_p)$ for some prime $p\nmid N$ .

For $\gamma \in \Gamma $ , let $\widetilde \chi _\gamma \colon G \to {\mathbb C}^\times $ be the continuous character such that $\widetilde \chi _\gamma (\operatorname {\mathrm {Frob}}_p)=\chi _\gamma (p)$ for all $p\nmid N$ . Define the group $H = \bigcap _{\gamma \in \Gamma } \ker \widetilde \chi _\gamma $ ; it is an open normal subgroup of G with $G/H$ is abelian. Let ${\mathcal K}$ be the subfield of ${\overline {\mathbb Q}}$ fixed by H; it is a finite abelian extension of ${\mathbb Q}$ .

Fix a prime $\ell $ and a prime ideal $\Lambda | \ell $ of ${\mathcal O}$ . In the proof of Theorem 3.1 of [Reference Ribet16], Ribet proved that $E^{\Gamma} ={\mathbb Q}(a_v^2)$ for a positive density set of finite place $v\nmid N\ell $ of ${\mathcal K}$ , where $a_v:=\operatorname {\mathrm {tr}}(\rho _\Lambda (\operatorname {\mathrm {Frob}}_v))$ . There is thus a finite place $v\nmid N\ell $ of ${\mathcal K}$ of degree $1$ such that $E^{\Gamma} ={\mathbb Q}(a_v^2)$ . We have $a_v=a_p$ , where p is the rational prime that v divides, so $E^{\Gamma} ={\mathbb Q}(a_p^2)$ . Since v has degree $1$ and ${\mathcal K}/{\mathbb Q}$ is abelian, the prime p must split completely in ${\mathcal K}$ and hence $\chi _\gamma (p)=1$ for all $\gamma \in \Gamma $ ; in particular, $\varepsilon (p)=1$ . Therefore, $E^{\Gamma} ={\mathbb Q}(r_p)$ .

2.2 The field L

Recall that we defined L to be the extension of K in ${\mathbb C}$ obtained by adjoining the square root of $r_p = a_p^2/\varepsilon (p)$ for all $p\nmid N$ . The following allows one to find a finite set of generators for the extension $L/K$ and gives a way to check the criterion of Theorem 1.2.

Proof Take any prime $p\nmid N$ . To prove part (i), it suffices to show that $\sqrt {r_p}$ belongs to the field $L':=K(\sqrt {r_{p_1}},\ldots ,\sqrt {r_{p_m}})$ . This is obvious if $r_p=0$ , so assume that $r_p\neq 0$ . Since the $p_i$ generate $({\mathbb Z}/M{\mathbb Z})^\times $ by assumption, there are integers $e_i\geq 0$ such that $p\equiv p_1^{e_1} \cdots p_m^{e_m} \ \pmod {M}$ . Take any $\gamma \in \Gamma $ . Using that the conductor of $\chi _\gamma $ divides M and (2.1), we have

$$\begin{align*}\gamma\Big( \frac{a_p}{{\prod}_i a_{p_i}^{e_i}} \Big) =\frac{\chi_\gamma(p)}{\chi_\gamma({\prod}_i p_i^{e_i})} \cdot \frac{a_p}{{\prod}_i a_{p_i}^{e_i}} = \frac{\chi_\gamma(p)}{\chi_\gamma(p)}\cdot \frac{a_p}{{\prod}_i a_{p_i}^{e_i}} = \frac{a_p}{{\prod}_i a_{p_i}^{e_i}}. \end{align*}$$

Since $E^{\Gamma} =K$ by Lemma 2.2(i), the value $a_p/{\prod }_i a_{p_i}^{e_i}$ belongs to K; it is nonzero since $r_p\neq 0$ and $r_{p_i}\neq 0$ . We have $\varepsilon (p) = \prod _i \varepsilon (p_i)^{e_i}$ since the conductor of $\varepsilon $ divides M. Therefore,

$$\begin{align*}\frac{r_p}{{\prod}_i r_{p_i}^{e_i}} = \frac{a_p^2}{{\prod}_i (a_{p_i}^2)^{e_i}} = \bigg(\frac{a_p}{{\prod}_i a_{p_i}^{e_i}}\bigg)^2 \in (K^\times)^2. \end{align*}$$

This shows that $\sqrt {r_p}$ is contained in $L'$ as desired. This proves (i); part (ii) is an easy consequence of (i).

5.1 Some group theory

Fix a prime $\ell $ and an integer $r\geq 1$ . A Borel subgroup of $\operatorname {GL}_2({\mathbb F}_{\ell ^r})$ is a subgroup conjugate to the subgroup of upper triangular matrices. A split Cartan subgroup of $\operatorname {GL}_2({\mathbb F}_{\ell ^r})$ is a subgroup conjugate to the subgroup of diagonal matrices. A nonsplit Cartan subgroup of $\operatorname {GL}_2({\mathbb F}_{\ell ^r})$ is a subgroup that is cyclic of order $(\ell ^r)^2-1$ . Fix a Cartan subgroup ${\mathcal C}$ of $\operatorname {GL}_2({\mathbb F}_{\ell ^r})$ . Let ${\mathcal N}$ be the normalizer of ${\mathcal C}$ in $\operatorname {GL}_2({\mathbb F}_{\ell ^r})$ . One can show that $[{\mathcal N}:{\mathcal C}] = 2$ and that $\operatorname {\mathrm {tr}}(g)=0$ and $g^2$ is scalar for all $g\in {\mathcal N}-{\mathcal C}$ .

5.2 Image of inertia at $\ell $

Fix an inertia subgroup ${\mathcal I}_\ell $ of $G=\operatorname {\mathrm {Gal}}({\overline {\mathbb Q}}/{\mathbb Q})$ for the prime $\ell $ ; it is uniquely defined up to conjugacy. The following gives important information concerning the representation for large $\ell $ . Let $\chi _\ell \colon\ G\twoheadrightarrow {\mathbb F}_\ell ^\times $ be the character such that for each prime $p\nmid \ell $ , $\chi _\ell $ is unramified at p and $\chi _\ell (\operatorname {\mathrm {Frob}}_p)\equiv p \ \pmod {\ell }$ .

5.3 Borel case

Suppose that

is a reducible subgroup of $\operatorname {GL}_2({\mathbb F})$ . There are, thus, characters $\psi _1,\psi _2 \colon\ G \to {\mathbb F}^\times $ such that after conjugating the ${\mathbb F}$ -representation

, we have

The characters $\psi _1$ and $\psi _2$ are unramified at each prime $p\nmid N\ell $ since

is unramified at such primes.

Take any $i\in \{1,2\}$ . By Lemma 5.4, there is a unique $0\leq m_i < \ell -1$ such that the character

$$\begin{align*}\tilde{\psi}_i:=\psi_i\chi_\ell^{-m_i}\colon\ G\to {\mathbb F}^\times \end{align*}$$

is unramified at $\ell $ and at all primes $p\nmid N$ . There is a character $\chi _i \colon\ ({\mathbb Z}/N_i{\mathbb Z})^\times \to {\mathbb F}^\times $ with $N_i\geq 1$ dividing some power of N and $\ell \nmid N_i$ such that $\tilde \psi _i(\operatorname {\mathrm {Frob}}_p) = \chi _i(p)$ for all $p\nmid N\ell $ . We may assume that $\chi _i$ is taken so that $N_i$ is minimal.

Proof We first recall the notion of an Artin conductor. Consider a representation $\rho \colon\ G\to \operatorname {\mathrm {Aut}}_{{\mathbb F}}(V)$ , where V is a finite-dimensional ${\mathbb F}$ -vector space. Take any prime $p\neq \ell $ . A choice of embedding ${\overline {\mathbb Q}}\subseteq {\overline {\mathbb Q}}_p$ induces an injective homomorphism $\operatorname {\mathrm {Gal}}({\overline {\mathbb Q}}_p/{\mathbb Q}_p) \hookrightarrow G$ . Choose any finite Galois extension $L/{\mathbb Q}_p$ for which $\rho (\operatorname {\mathrm {Gal}}({\overline {\mathbb Q}}_p/L))=\{I\}$ . For each $i\geq 0$ , let $H_i$ be the ith ramification subgroup of $\operatorname {\mathrm {Gal}}(L/{\mathbb Q}_p)$ with respect to the lower numbering. Define the integer

$$\begin{align*}f_p(\rho)= \sum_{i\geq 0} [H_0:H_i]^{-1}\cdot \dim_{{\mathbb F}} V/V^{H_i}. \end{align*}$$

The Artin conductor of $\rho $ is the integer $N(\rho ):=\prod _{p\neq \ell } p^{f_p(\rho )}$ .

Using that the character $\tilde \psi _i\colon\ G \to {\mathbb F}^\times $ is unramified at $\ell $ , one can verify that $N(\tilde \psi _i)=N_i$ . Consider our representation . For a fixed prime $p\neq \ell $ , take L and $H_i$ as above. The semisimplification of is $V_1\oplus V_2$ , where $V_i$ is the one-dimensional representation given by $\psi _i$ . We have since $\dim _{{\mathbb F}} V^{H_i} \leq \dim _{{\mathbb F}} V_1^{H_i} + \dim _{{\mathbb F}} V_2^{H_i}$ . By using this for all $p\neq \ell $ , we deduce that $N(\psi _1) N(\psi _2)=N_1 N_2$ divides . The lemma follows since divides N (cf. [Reference Livné11, Proposition 0.1]).

Fix an $i\in \{1,2\}$ ; if $\ell \geq k-1$ and $\ell \nmid N$ , then we may suppose that $m_i=0$ by Lemma 5.4. Since the conductor of $\chi _i$ divides N by Lemma 5.5, assumption (a) implies that there is a prime $p\nmid N\ell $ for which $\chi _i(p) p^{m_i} \in {\mathbb F}$ is not a root of $x^2-a_p x + \varepsilon (p)p^{k-1} \in {\mathbb F}[x]$ . However, this is a contradiction since

$$\begin{align*}\chi_i(p) p^{m_i} = \tilde\psi_i(\operatorname{\mathrm{Frob}}_p) \chi_\ell(\operatorname{\mathrm{Frob}}_p)^{m_i} = \psi_i(\operatorname{\mathrm{Frob}}_p) \end{align*}$$

is a root of $x^2-a_p x + \varepsilon (p)p^{k-1}$ .

Therefore, the ${\mathbb F}$ -representation is irreducible. In particular, is not contained in a Borel subgroup of $\operatorname {GL}_2({\mathbb F}_\Lambda )$ .

5.4 Cartan case

5.5 Normalizer of a Cartan case

Suppose that

is contained in the normalizer ${\mathcal N}$ of a Cartan subgroup ${\mathcal C}$ of $\operatorname {GL}_2({\mathbb F}_\Lambda )$ . The group ${\mathcal C}$ has index $2$ in ${\mathcal N}$ , so we obtain a character

The character $\beta _\Lambda $ is nontrivial since

by Lemma 5.6.

Let $\chi $ be the primitive Dirichlet character that satisfies $\beta _\Lambda (\operatorname {\mathrm {Frob}}_p)=\chi (p)$ for all primes $p\nmid N\ell $ . Since $\beta _\Lambda $ is a quadratic character, Lemma 5.7 implies that the conductor of $\chi $ divides ${\mathcal M}$ . The character $\chi $ is nontrivial since $\beta _\Lambda $ is nontrivial. Assumption (b) implies that there is a prime $p\nmid N\ell $ satisfying $\chi (p)=-1$ and $r_p \not \equiv 0 \ \pmod {\lambda }$ . We thus have $g\in {\mathcal N}-{\mathcal C}$ and $\operatorname {\mathrm {tr}}(g)\neq 0$ , where . However, this contradicts that $\operatorname {\mathrm {tr}}(A)=0$ for all $A\in {\mathcal N}-{\mathcal C}$ .

Therefore, the image of does not lie in the normalizer of a Cartan subgroup of $\operatorname {GL}_2({\mathbb F}_\Lambda )$ .

5.6 $\mathfrak {A}_5$ case

Assume that is isomorphic to $\mathfrak {A}_5$ with $\#k_\lambda \notin \{4,5\}$ .

The image of $r_p/p^{k-1}= a_p^2/(\varepsilon (p)p^{k-1})$ in ${\mathbb F}_\lambda $ is equal to $\operatorname {\mathrm {tr}}(A)^2/\det (A)$ with . Every element of $\mathfrak {A}_5$ has order $1$ , $2$ , $3$ , or $5$ , so Lemma 5.2 implies that the image of $r_p/p^{k-1}$ in ${\mathbb F}_\lambda $ is $0$ , $1$ , $4$ , or is a root of $x^2-3x+1$ for all $p\nmid N\ell $ . If $\lambda | 5$ , then Lemma 5.2 implies that $k_\lambda ={\mathbb F}_5$ , which is excluded by our assumption on $k_\lambda $ . So $\lambda \nmid 5$ and Lemma 5.2 ensures that $k_\lambda $ is the splitting field of $x^2-3x+1$ over ${\mathbb F}_\ell $ . So $k_\lambda $ is ${\mathbb F}_\ell $ if $\ell \equiv \pm 1 \ \pmod {5}$ and ${\mathbb F}_{\ell ^2}$ if $\ell \equiv \pm 2 \ \pmod {5}$ .

From assumption (c), we find that $\ell> 5k-4$ and $\ell \nmid N$ . By Lemma 5.3, the group contains an element of order at least $(\ell -1)/(k-1)> ((5k-4)-1)/(k-1) = 5$ . This is a contradiction since $\mathfrak {A}_5$ has no elements with order greater than $5$ .

5.7 $\mathfrak {A}_4$ and $\mathfrak {S}_4$ cases

Suppose that is isomorphic to $\mathfrak {A}_4$ or $\mathfrak {S}_4$ with $\#k_\lambda \neq 3$ .

First suppose that $\#k_\lambda \notin \{5,7\}$ . The image of $r_p/p^{k-1}= a_p^2/(\varepsilon (p)p^{k-1})$ in ${\mathbb F}_\lambda $ is equal to $\operatorname {\mathrm {tr}}(A)^2/\det (A)$ with . Since every element of $\mathfrak {S}_4$ has order at most $4$ , Lemma 5.2 implies that $r_p/p^{k-1}$ is congruent to $0$ , $1$ , $2$ , or $4$ modulo $\lambda $ for all primes $p\nmid N\ell $ . In particular, $k_\lambda ={\mathbb F}_\ell $ . By assumption (d), we must have $\ell>4k-3$ and $\ell \nmid N$ . By Lemma 5.3, the group contains an element of order at least $(\ell -1)/(k-1)> ((4k-3)-1)/(k-1) = 4$ . This is a contradiction since $\mathfrak {S}_4$ has no elements with order greater than $4$ .

Now, suppose that $\#k_\lambda \in \{5,7\}$ . By assumption (e), with any $\chi $ , there is a prime $p\nmid N\ell $ such that $a_p^2/(\varepsilon (p)p^{k-1}) \equiv 2 \ \pmod {\lambda }$ . The element

has order $1$ , $2$ , $3$ , or $4$ . By Lemma 5.2, we deduce that g has order $4$ . Since $\mathfrak {A}_4$ has no elements of order $4$ , we deduce that

is isomorphic to $\mathfrak {S}_4$ . Let $H'$ be the unique index $2$ subgroup of H; it is isomorphic to $\mathfrak {A}_4$ . Define the character

The quadratic character $\beta $ corresponds to a Dirichlet character $\chi $ whose conductor divides $4^e \ell N$ . By assumption (e), there is a prime $p\nmid N\ell $ such that $\chi (p)=1$ and $a_p^2/(\varepsilon (p)p^{k-1})\equiv 2 \ \pmod {\lambda }$ . Since $\beta (\operatorname {\mathrm {Frob}}_p)=\chi (p)=1$ , we have

. Since $H'\cong \mathfrak {A}_4$ , Lemma 5.2 implies that the image of $a_p^2/(\varepsilon (p)p^{k-1})$ in ${\mathbb F}_\lambda $ is $0$ , $1$ , or $4$ . This contradicts $a_p^2/(\varepsilon (p)p^{k-1})\equiv 2 \ \pmod {\lambda }$ .

Therefore, the image of is not isomorphic to either of the groups $\mathfrak {A}_4$ or $\mathfrak {S}_4$ .

5.8 End of proof

In Section 5.3, we saw that is not contained in a Borel subgroup of $\operatorname {GL}_2({\mathbb F}_\Lambda )$ . In Section 5.5, we saw that is not contained in the normalizer of a Cartan subgroup of $\operatorname {GL}_2({\mathbb F}_\Lambda )$ .

In Section 5.6, we showed that if $\#k_\lambda \notin \{4,5\}$ , then is not isomorphic to $\mathfrak {A}_5$ . We want to exclude the cases $\#k_\lambda \in \{4,5\}$ since $\operatorname {PSL}_2({\mathbb F}_4)$ and $\operatorname {PSL}_2({\mathbb F}_5)$ are both isomorphic to $\mathfrak {A}_5$ .

In Section 5.7, we showed that if $\#k_\lambda \neq 3$ , then is not isomorphic to $\mathfrak {A}_4$ and not isomorphic to $\mathfrak {S}_4$ . We want to exclude the case $\#k_\lambda =3$ since $\operatorname {PSL}_2({\mathbb F}_3)$ and $\operatorname {PGL}_2({\mathbb F}_3)$ are isomorphic to $\mathfrak {A}_4$ and $\mathfrak {S}_4$ , respectively.

By Lemma 5.1, the group must be conjugate in $\operatorname {PGL}_2({\mathbb F}_\Lambda )$ to $\operatorname {PSL}_2({\mathbb F}')$ or $\operatorname {PGL}_2({\mathbb F}')$ , where ${\mathbb F}'$ is a subfield of ${\mathbb F}_\Lambda $ . One can then show that ${\mathbb F}'$ is the subfield of ${\mathbb F}_\Lambda $ generated by the set . By the Chebotarev density theorem, the field ${\mathbb F}'$ is the subfield of ${\mathbb F}_\Lambda $ generated by the images of $a_p^2/(\varepsilon (p) p^{k-1})=r_p/p^{k-1}$ with $p\nmid N\ell $ . Therefore, ${\mathbb F}'=k_\lambda $ and hence is conjugate in $\operatorname {PGL}_2({\mathbb F}_\Lambda )$ to $\operatorname {PSL}_2(k_\lambda )$ or $\operatorname {PGL}_2(k_\lambda )$ .

6.1 Example from Section 1.2

Let f be the newform from Section 1.2. We have $E={\mathbb Q}(i)$ . We know that $\Gamma \neq 1$ since $\varepsilon $ is nontrivial. Therefore, $\Gamma =\operatorname {\mathrm {Gal}}({\mathbb Q}(i)/{\mathbb Q})$ and $K=E^{\Gamma }$ equals ${\mathbb Q}$ . So $\Gamma $ is generated by complex conjugation and we have for $p\nmid N$ . As noted in Section 1.2, this implies that $r_p$ is a square in ${\mathbb Z}$ for all $p\nmid N$ and hence L equals $K={\mathbb Q}$ . Fix a prime $\ell =\lambda $ and a prime ideal $\Lambda | \ell $ of ${\mathcal O}={\mathbb Z}[i]$ .

Set $q_1=109$ and $q_2=379$ ; they are primes that are congruent to $1$ modulo $27$ . Set $p_1=5$ , and we have $\chi (p_1)=-1$ , where $\chi $ is the unique nontrivial character $({\mathbb Z}/3{\mathbb Z})^\times \to \{\pm 1\}$ . Set $q=5$ ; the field ${\mathbb Q}(r_q)$ equals $K={\mathbb Q}$ and hence ${\mathbb Z}[r_{q}]={\mathbb Z}$ .

One can verify that $a_{109}=164$ , $a_{379}=704$ , and $a_5=-3i$ , so $r_{109}=164^2$ , $r_{379}=704^2$ , and $r_5=3^2$ . We have $r_{109} - (1+109^2)^2 = -2^2\times 3^3\times 7\times 19\times 31\times 317$ and $r_{379} - (1+379^2)^2 = -2^2 \times 3^3\times 2,647 \times 72,173$ . So if $\ell \geq 11$ , then there is an $i\in \{1,2\}$ such that $\ell \neq q_i$ and $r_{q_i}\not \equiv (1+q_i^2)^2\ \pmod {\ell }$ .

Let S be the set from Section 4 with the above choice of $q_1$ , $q_2$ , $p_1$ , and q. We find that $S = \{2,3,5,7,11\}$ . Theorem 4.3 implies that is conjugate in $\operatorname {PGL}_2({\mathbb F}_\Lambda )$ to $\operatorname {PSL}_2({\mathbb F}_\ell )$ when $\ell>11$ .

Now, take $\ell \in \{7,11\}$ . Choose a prime ideal $\Lambda $ of ${\mathcal O}$ dividing $\ell $ . We have $e_0=e_1=e_2=0$ and ${\mathcal M}=3$ . The subfield $k_\ell $ generated over ${\mathbb F}_\ell $ by the images of $r_p$ modulo $\ell $ with $p\nmid N\ell $ is of course ${\mathbb F}_\ell $ (since the $r_p$ are rational integers). We now verify the conditions of Theorem 4.1.

We first check condition (a). Suppose there is a character $\chi \colon\ ({\mathbb Z}/27{\mathbb Z})^\times \to {\mathbb F}_\ell ^\times $ such that $\chi (q_2)$ is a root of $x^2-a_{q_2} x + \varepsilon (q_2) q_2^2$ modulo $\ell $ . Since $q_2\equiv 1\ \pmod {27}$ and $a_{q_2}=704$ , we find that $1$ is a root of $x^2-a_{q_2} x + q_2^2 \in {\mathbb F}_\ell [x]$ . Therefore, $a_{q_2} \equiv 1+q_2^2 \ \pmod {\ell }$ and hence $r_{q_2}^2 = a_{q_2}^2 \equiv (1+ q_2^2)^2 \ \pmod {\ell }$ . However, $r_{379} - (1+379^2)^2 \not \equiv 0 \ \pmod {\ell }$ from the explicit value of it computed above. So the character $\chi $ does not exist and we have verified condition (a).

We now check condition (b). Let $\chi \colon\ ({\mathbb Z}/3{\mathbb Z})^\times \to \{\pm 1\}$ be the nontrivial character. We have $\chi (5)=-1$ and $r_5 = 9 \not \equiv 0 \ \pmod {\ell }$ . Therefore, condition (b) holds.

We now check condition (c). If $\ell =7$ , we have $\ell \equiv 2 \ \pmod {5}$ and $\#k_\ell = \ell \neq \ell ^2$ , so condition (c) holds. Take $\ell =11$ . We have $a_5^2/(\varepsilon (5) 5^2) = 9/5^2 \equiv 3 \ \pmod {11}$ , which verifies condition (c).

Condition (d) holds since $\#k_\ell = 5$ if $\ell = 7$ , and $\ell>4k-3=9$ and $\ell \nmid N$ if $\ell =11$ .

Finally, we explain why condition (e) holds when $\ell =7$ . Let $\chi \colon\ ({\mathbb Z}/7\cdot 27 {\mathbb Z})^\times \to \{\pm 1\}$ be any nontrivial character. A quick computation shows that there is a prime $p\in \{13,37,41\}$ such that $\chi (p)=1$ and that $a_p^2/(\varepsilon (p) p^2) \equiv 2 \ \pmod {7}$ .

Theorem 4.1 implies that is conjugate in $\operatorname {PGL}_2({\mathbb F}_\Lambda )$ to $\operatorname {PSL}_2({\mathbb F}_\ell )$ or $\operatorname {PGL}_2({\mathbb F}_\ell )$ . Since $L=K$ , the group isomorphic to $\operatorname {PSL}_2({\mathbb F}_{\ell })$ by Theorem 1.2(i).

6.2 Example from §1.3

Let f be a newform as in Section 1.3; we have $k=3$ and $N=160$ . The Magma code below verifies that f is uniquely determined up to replacing by a quadratic twist and then a Galois conjugate. So the group , up to isomorphism, does not depend on the choice of f.

Define $b = \zeta _{13}^1 + \zeta _{13}^5+\zeta _{13}^8 +\zeta _{13}^{12}$ , where $\zeta _{13}$ is a primitive $13$ th root of unity in ${\overline {\mathbb Q}}$ (note that $\{1,5,8,12\}$ is the unique index $3$ subgroup of ${\mathbb F}_{13}^\times $ ). The characteristic polynomial of b is $x^3 + x^2 - 4x + 1$ , and hence ${\mathbb Q}(b)$ is the unique cubic extension of ${\mathbb Q}$ in ${\mathbb Q}(\zeta _{13})$ . The code below shows that the coefficient field E is equal to ${\mathbb Q}(b,i)$ (it is a degree $6$ extension of ${\mathbb Q}$ that contains roots of $x^3 + x^2 - 4x + 1$ and $x^2+1$ ).

Fix notation as in Section 2.1. We have $\Gamma \neq 1$ since $\varepsilon $ is nontrivial. The character $\chi _\gamma ^2$ is trivial for $\gamma \in \Gamma $ (since $\chi _\gamma $ is always a quadratic character times some power of $\varepsilon $ ). Therefore, $\Gamma $ is a $2$ -group. The field $K=E^{\Gamma} $ is thus ${\mathbb Q}(b)$ , which is the unique cubic extension of ${\mathbb Q}$ in E. Therefore, $r_p = a_p^2/\varepsilon (p)$ lies in $K={\mathbb Q}(b)$ for all $p\nmid N$ .

The code below verifies that $r_3$ , $r_7$ , and $r_{11}$ are squares in K that do not lie in ${\mathbb Q}$ (and, in particular, are nonzero). Since $3$ , $7$ , and $11$ generate the group $({\mathbb Z}/40{\mathbb Z})^\times $ , we deduce from Lemma 2.3 that the field $L=K(\{\sqrt {r_p}:p\nmid N\})$ is equal to K.

Let $N_{K/{\mathbb Q}}\colon\ K\to {\mathbb Q}$ be the norm map. The following code verifies that $N_{K/{\mathbb Q}}(r_3) = 2^6$ , $N_{K/{\mathbb Q}}(r_7) = 2^6$ , $N_{K/{\mathbb Q}}(r_{11}) = 2^{12}5^4$ , $N_{K/{\mathbb Q}}(r_{13})=2^{12} 13^2$ , $N_{K/{\mathbb Q}}(r_{17}) = 2^{18}5^2$ , and that

(6.1) $$ \begin{align} \gcd\Big( 641\cdot N_{K/{\mathbb Q}}(r_{641}-(1+642^2)^2), \, 1,061\cdot N_{K/{\mathbb Q}}(r_{1061}-(1+1,061^2)^2)\Big) = 2^{12}.\\[-25pt] \nonumber \end{align} $$

Set $q_1=641$ and $q_2=1,061$ ; they are primes congruent to $1$ modulo $160$ . Let $\lambda $ be a prime ideal of R dividing a rational prime $\ell>3$ . From (6.1), we find that $\ell \neq q_i$ and $r_{q_i} \not \equiv (1+q_i^2)^2 \ \pmod {\lambda }$ for some $i\in \{1,2\}$ (otherwise, $\lambda $ would divide $2$ ).

Set $p_1=3$ , $p_2= 7$ , and $p_3=11$ . For each nontrivial quadratic character $\chi \colon\ ({\mathbb Z}/40 {\mathbb Z})^\times \to \{\pm 1\}$ , we have $\chi (p_i)=-1$ for some prime $i\in \{1,2,3\}$ (since $3$ , $7$ , and $11$ generate the group $({\mathbb Z}/40{\mathbb Z})^\times $ ). From the computed values of $N_{K/{\mathbb Q}}(r_p)$ , we find that $r_{p_i} \not \equiv 0 \ \pmod {\lambda }$ for all $i\in \{1,2,3\}$ and all nonzero prime ideals $\lambda \nmid N$ of R.

Set $q=3$ . We have noted that $r_{q}\in K-{\mathbb Q}$ , so $K={\mathbb Q}(r_{q})$ . The index of the order ${\mathbb Z}[r_{q}]$ in R is a power of $2$ since $N_{K/{\mathbb Q}}(q)$ is a power of $2$ .

Let S be the set from Section 4 with the above choice of $q_1$ , $q_2$ , $p_1$ , $p_2$ , $p_3$ , and q. The above computations show that S consists of the prime ideals $\lambda $ of R that divide a prime $\ell \leq 11$ .

Now, let $\ell $ be an odd prime congruent to $\pm 2$ , $\pm 3$ , $\pm 4$ , or $\pm 6$ modulo $13$ . Since K is the unique cubic extension in ${\mathbb Q}(\zeta _{13})$ , we find that the ideal $\lambda := \ell R$ is prime in R and that ${\mathbb F}_\lambda \cong {\mathbb F}_{\ell ^3}$ . The above computations show that $\lambda \notin S$ when $\ell \notin \{3,7,11\}$ . Theorem 4.3 implies that if $\ell \notin \{3,7,11\}$ , then is conjugate in $\operatorname {PGL}_2({\mathbb F}_\Lambda )$ to $\operatorname {PSL}_2({\mathbb F}_\lambda )$ or $\operatorname {PGL}_2({\mathbb F}_\lambda )$ , where $\Lambda $ is a prime ideal of ${\mathcal O}$ dividing $\lambda $ . So if $\ell \notin \{3,7,11\}$ , the group isomorphic to $\operatorname {PSL}_2({\mathbb F}_\lambda )\cong \operatorname {PSL}_2({\mathbb F}_{\ell ^3})$ by Theorem 1.2(i) and the equality $L=K$ .

Now, take $\lambda = \ell R$ with $\ell \in \{3,7,11\}$ ; it is a prime ideal. Choose a prime ideal $\Lambda $ of ${\mathcal O}$ dividing $\lambda $ . We noted above that ${\mathbb Z}[r_3]$ is an order in R with index a power of $2$ ; the same argument shows that this also holds for the order ${\mathbb Z}[r_7]$ . Therefore, the field $k_\lambda $ generated over ${\mathbb F}_\ell $ by the images of $r_p$ modulo $\lambda $ with $p\nmid N\ell $ is equal to ${\mathbb F}_\lambda $ . Since $\#{\mathbb F}_\lambda =\ell ^3$ , we find that conditions (c)–(e) of Theorem 4.1 hold.

We now show that condition (a) of Theorem 4.1 holds for our fixed $\Lambda $ . We have $e_0=0$ , so take any character $\chi \colon\ ({\mathbb Z}/N{\mathbb Z})^\times \to {\mathbb F}_\Lambda ^\times $ . We claim that $\chi (q_i)\in {\mathbb F}_\Lambda $ is not a root of $x^2-a_{q_i} x + \varepsilon (q_i) q_i^2$ for some $i\in \{1,2\}$ . Since $q_i\equiv 1\ \pmod {N}$ , the claim is equivalent to showing that $a_{q_i} \not \equiv 1 + q_i^2 \ \pmod {\Lambda }$ for some $i\in \{1,2\}$ . So we need to prove that $r_{q_i} \equiv (1 + q_i^2)^2 \ \pmod {\lambda }$ for some $i\in \{1,2\}$ ; this is clear since otherwise $\ell $ divides the quantity (6.1). This completes our verification of condition (a).

We now show that condition (b) of Theorem 4.1 holds. We have $r_p \not \equiv 0 \ \pmod {\lambda }$ for all primes $p\in \{3,7,11,13,17\}$ ; this is a consequence of $N_{K/{\mathbb Q}}(r_p)\not \equiv 0 \ \pmod {\ell }$ . We have ${\mathcal M}= 120$ if $\ell =3$ and ${\mathcal M}=40$ otherwise. Condition (b) holds since $({\mathbb Z}/{\mathcal M}{\mathbb Z})^\times $ is generated by the primes $p\in \{3,7,11,13,17\}$ for which $p\nmid {\mathcal M}\ell $ .

Theorem 4.1 implies that is conjugate in $\operatorname {PGL}_2({\mathbb F}_\Lambda )$ to $\operatorname {PSL}_2({\mathbb F}_\lambda )$ or $\operatorname {PGL}_2({\mathbb F}_\lambda )$ . Since $L=K$ , the group is isomorphic to $\operatorname {PSL}_2({\mathbb F}_\lambda )\cong \operatorname {PSL}_2({\mathbb F}_{\ell ^3})$ by Theorem 1.2(i).