scr.12.5.1.1.s

Base Field

\(F = \) 3.3.1.0a1.1 \( = \mathbb{Q}_{ 3 }(a) = \mathbb{Q}_{ 3 }[x] / (x^{3} + 2 x + 1 )\) View on LMFDB ↗

Description

supercuspidal ramified

Construction

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

Semistability defect

\( e = 12\)

Conductor exponent

\( v(N) = 5\)

Character Order

6

Inducing Field

The inertial type \(\tau\) is reducible, induced from a character of \(K = F(b)\), with \(b\) a root of \(x^{2} - a\cdot 3 \)

Underlying Character

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

Order

6

Conductor exponent

4

Values on generators of \((\mathcal{O}_K/\mathfrak p^{ 4 })^\times/U_{\mathfrak{p}^{ 4 } }\) , with \(\zeta=\frac{1+\sqrt{-3}}{2}\) a 6th root of unity :

\(\begin{array}{l} \chi^A\left((-a^{2} - 3a - 3)b - 3a^{2} - 2a \right) &= \zeta^{ 5 } \\ \chi^A\left((a^{2} + a + 1)b + 1 \right) &= \zeta^{ 0 } \\ \chi^A\left(a^{2}b + 1 \right) &= \zeta^{ 2 } \\ \chi^A\left((-3a + 3)b + 1 \right) &= \zeta^{ 4 } \end{array} \)

Inertia Polynomial

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

\( x^{12} + (9a^{2} + 18 )x^{4} + 3 \)