I already created [this post on Math Stack Exchange][1] but I was not so sure if this question fits better here. If it is not, I want to apologize in advance and feel free to delete my post.
I want to understand the proof of the following Theorem from ["Euler Factors determine Weil Representations" by Tim and Vladimir Dokchitser][2]:
> **Theorem 1** Every Frobenius-semisimple Weil representation $\rho$ is uniquely determined by its local polynomials $P(\rho/F,T)$ over finite separable extensions $F/K$.
Before we talk about the cyclic case of the proof, let us recall some **definitions** first:
- Let $K$ be a local field and $G_K = \operatorname{Gal}(\bar{K}/K)$ be the absolute Galois group of $K$. An **(arithmetic) Frobenius element** is any element $\operatorname{Frob}_K \in G_K$ that acts as $x \mapsto x^{|k|}$ on $\bar{k}$, the algebraic closure of the residue field $k$ of $K$.
- The **Weil group** $W_K$ is the subgroup of $G_K$ of all automorphisms that act as an integral power of Frobenius on the residue field.
- A **Weil representation** is a representation $\rho: W_K \to \operatorname{GL}_n(\mathbb{C})$ such that $\rho(I_K)$ is finite. It is called **Frobenius-semisimple** if the image of some (equivalently, any) Frobenius element is diagonalizable.
- The **local polynomial** $P(\rho,T)$ is the inverse characteristic polynomial of $\operatorname{Frob}_K^{-1}$ on the inertia invariants of $\rho$, i.e. $$P(\rho,T) = \det(1-T \cdot \operatorname{Frob_K^{-1}}).$$
Similarly, for a finite extension $F/K$, we write $P(\rho/F)$ for the local polynomial of the restriction of $\rho$ to $W_F$, i.e. $$P(\rho/F,T) = P(\rho|_{W_F},T).$$
Now I would like to talk about the **proof of the cyclic case** which is given in the paper:
> **Step 1: Cyclic.** Suppose $\rho$ factors through a finite cyclic group $G = \operatorname{Gal}(F/K) \simeq C_n$ and $F/K$ has ramification degree $e$. By Lemma 2 (cf. below), there is a cyclic totally ramified extension $K/K$ of degree $e$ such that $FL/L$ is unramified of degree $n$. The restriction map $\operatorname{Gal}(FL/L) \to \operatorname{Gal}(F/K)$ is an isomorphism, as it is clearly injective and both groups have order $n$. So $\rho/L$ determines $\rho$, and $\rho/L$ can be recovered from its local polynomial $P(\rho/L,T)$.
In our proof we used the following **Lemma** which we shall take for granted in this post:
> **Lemma 2** Let $F/K$ be a cyclic extension of degree $n$ and ramification degree $e$. Then there exists a cyclic totally ramified extension $L/K$ of degree $e$ such that $FL/L$ is unramified of degree $n$.
Now I have the following specific **questions** about the proof above:
- Could you give me a good argument why the restriction map $\operatorname{Gal}(FL/L) \to \operatorname{Gal}(F/K)$ is injective? Let us say we have $\sigma, \sigma' \in \operatorname{Gal}(FL/L)$ which are not equal. Then there exists an $x \in FL \setminus L$ such that $\sigma(x) \neq \sigma'(x)$. If $x \in F$ then the restrictions $\bar{\sigma}, \bar{\sigma}$ are obviously not equal. But what happens if $x$ is not in $F$?
- Why does $\rho/L$ determine $\rho$ then? And how can we recover $\rho/L$ from its local polynomial $P(\rho/L,T)$? What do "determining" and "recovering" even mean in these cases?
**Additional Remark**:
I would also like to add a **diagram** which my professor drew to explain me something relating to this Theorem (or Lemma?):
$\require{AMScd}\DeclareMathOperator\Gal{Gal}$
\begin{CD}
@. \Gal(L F/L) @>{\text{$\chi|_L$, unramified}}>> \Gal(K^{\mathrm{ur}}/K) \\
@. @V{\simeq}VV @| \\
1 @>>> \Gal(F/K^{\mathrm{ur}}) @>>> \Gal(F/K) @>>> \Gal(K^{\mathrm{ur}}/K) @>>> 1 \\
@. @. @V{\chi}VV \\
@. @. \mathbb C^\times
\end{CD}
And next to this diagram, he also wrote $P(\chi|_L,T) = 1 - \operatorname{Frob}_L \cdot T$.
To this remark, I have the following **questions** (if it is really related to the proof):
- What is $\chi$ supposed to mean?
- Is the diagram commutative?
- Why all of the sudden does the maximal unramified extension (I think?) $K^{ur}$ of $K$ appear here?
- If or how is this related to the proof of Theorem 1 (resp. Lemma 2)?
Could you please help me answering my questions? I feel like I lack a lot of background knowledge which is required here, so it would be really nice if you could explain them to me carefully. Thank you in advance!
[1]: https://math.stackexchange.com/questions/2940155/local-factors-determine-weil-representations-proof-of-the-cyclic-case
[2]: https://arxiv.org/pdf/1112.4889.pdf