ex.24.13.1.3775_5455_7117.e

Base Field

\(F = \) 2.1.2.2a1.1 \( = \mathbb{Q}_{ 2 }(a) = \mathbb{Q}_{ 2 }[x] / (x^{2} + 2 x + 2 )\) View on LMFDB ↗

Description

exceptional, SL(2,3)

Construction

Extension to \(I_F\) of \( \tau = \operatorname{Ind}^{I_K}_{I_L} \chi \), with \(L, K\) and \(\chi\) as below

Semistability defect

\( e = 24\)

Conductor exponent

\( v(N) = 13\)

Character Order

4

Triply Field

The inertial type \(\tau\) becomes an induction (triply imprimitive) over: \( L = F(\mu_3, b) \), with \(\mu_3\) a root of \(x^2+x+1\) and \(b\) a root of \(x^{3} + a \)

Inducing Field

The inertial type \(\tau\) becomes reducible over \(K = L(c)\), \(c\) a root of \(x^{2} + ((a + 1)b^{6} )x + (3b^{2} + (-3a - 1)\mu_3)b \)

Underlying Character

Character \(\chi^A:\mathcal O_K^\times \to \mathbb C^\times\) with the following properties:

Order

4

Conductor exponent

23

Values on generators of \((\mathcal{O}_K/\mathfrak p^{ 23 })^\times/U_{\mathfrak{p}^{ 23 } }\) :

\(\begin{array}{l} \chi^A\left(\mu_3c + 1 \right) &= i^{ 2 } \\ \chi^A\left((((3a + 2)\mu_3 + (3a + 2))b^{2} + (2a + 2)\mu_3b)\cdot c + (2a\cdot \mu_3 + 2a)\cdot b^{2} + 1 \right) &= i^{ 0 } \\ \chi^A\left((3a\cdot \mu_3b + 4)c + 1 \right) &= i^{ 0 } \\ \chi^A\left(((3a + 1)\mu_3b + (3a + 4))c + (2a + 2)\mu_3b + 2a + 1 \right) &= i^{ 0 } \\ \chi^A\left((((2a + 1)\mu_3 + 1)b^{2} + ((a + 1)\mu_3 + (3a + 3))b + ((a + 2)\mu_3 - 2))c + ((a + 2)\mu_3 + (3a + 2))b^{2} + (3a\cdot \mu_3 + (3a + 2))b + 1 \right) &= i^{ 0 } \\ \chi^A\left(((3a\cdot \mu_3 + 1)b^{2} + (2a\cdot \mu_3 + 3a)\cdot b - 2\mu_3 + a - 2)c + (a\cdot \mu_3 + (2a + 3))b^{2} + (2a\cdot \mu_3 + (2a + 3))b + (a + 2)\mu_3 + 1 \right) &= i^{ 3 } \\ \chi^A\left((-\mu_3 + 3)c + -\mu_3 + 3 \right) &= i^{ 0 } \\ \chi^A\left(((a\cdot \mu_3 + a)b + 4\mu_3)c + 1 \right) &= i^{ 2 } \\ \chi^A\left(((a\cdot \mu_3 + a)b^{2} + 2\mu_3b + (a - 2))c + (2a\cdot \mu_3 + 2a)\cdot b^{2} + 2a - 3 \right) &= i^{ 0 } \\ \chi^A\left((((2a + 2)\mu_3 + 2)b^{2} + (2\mu_3 + 2)b + (2a + 4)\mu_3)c + 2a\cdot \mu_3b^{2} + (3a + 1)b + (a + 4)\mu_3 + a + 1 \right) &= i^{ 0 } \\ \chi^A\left(((a + 2)b^{2} + ((2a + 2)\mu_3 + (2a + 2))b)\cdot c + 2a\cdot b^{2} + 1 \right) &= i^{ 1 } \\ \chi^A\left(((3\mu_3 + (a + 1))b^{2} + ((2a + 3)\mu_3 + (2a + 3))b + (4\mu_3 + (a + 4)))c + ((3a + 2)\mu_3 + (2a + 3))b^{2} + ((2a + 2)\mu_3 + 1)b + (3a + 2)\mu_3 + 2a + 1 \right) &= i^{ 0 } \\ \chi^A\left(((2a\cdot \mu_3 + 2a)\cdot b + (2a + 2)\mu_3)c + 1 \right) &= i^{ 0 } \\ \chi^A\left((3a\cdot b^{2} + (2\mu_3 + 2)b + (a - 2)\mu_3)c + 2a\cdot b^{2} + (2a + 4)\mu_3 + 1 \right) &= i^{ 1 } \end{array} \)

Inertia Polynomial

The following polynomial defines a field \(L\) such that \(L^{un}\) is the fixed field of \(\tau\).

\( x^{48} + (24a + 24 )x^{47} + (24a + 24 )x^{46} + (8a + 16 )x^{45} + 4a x^{44} + (12a + 8 )x^{43} + (28a + 4 )x^{42} + (4a + 24 )x^{41} + (12a + 28 )x^{40} + (20a + 16 )x^{39} + (28a + 16 )x^{38} + (28a + 8 )x^{37} + (18a + 20 )x^{36} + (4a + 24 )x^{35} + 24 x^{34} + 24 x^{33} + (28a + 10 )x^{32} + 4a x^{31} + (8a + 20 )x^{30} + (12a + 20 )x^{28} + 16 x^{27} + (4a + 20 )x^{26} + 16 x^{25} + (12a + 10 )x^{24} + 8a x^{23} + 24 x^{22} + (8a + 16 )x^{21} + (4a + 8 )x^{20} + (24a + 8 )x^{19} + (24a + 8 )x^{18} + (24a + 24 )x^{17} + (20a + 24 )x^{16} + (8a + 24 )x^{15} + (24a + 8 )x^{14} + (16a + 8 )x^{13} + (28a + 4 )x^{12} + (24a + 24 )x^{11} + (24a + 24 )x^{10} + (24a + 16 )x^{9} + (22a + 20 )x^{8} + (8a + 24 )x^{7} + (20a + 24 )x^{6} + 16 x^{5} + (20a + 16 )x^{4} + (24a + 16 )x^{3} + (12a + 8 )x^{2} + 16a + 14 \)