sketch of pf for Zpn

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jgarnek 2024-10-17 15:02:25 +02:00
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commit 00c319f4c0
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@ -112,7 +112,7 @@ hyperref, bbm, mathtools, mathrsfs}
%opening %opening
\begin{document} \begin{document}
\title[The de Rham...]{?? The de Rham cohomology of covers with cyclic $p$-Sylow subgroup} \title[The de Rham...]{?? The de Rham cohomology of covers\\ with cyclic $p$-Sylow subgroup}
\author[A. Kontogeorgis and J. Garnek]{Aristides Kontogeorgis and J\k{e}drzej Garnek} \author[A. Kontogeorgis and J. Garnek]{Aristides Kontogeorgis and J\k{e}drzej Garnek}
\address{???} \address{???}
\email{jgarnek@amu.edu.pl} \email{jgarnek@amu.edu.pl}
@ -129,8 +129,15 @@ hyperref, bbm, mathtools, mathrsfs}
\maketitle \maketitle
\bibliographystyle{plain} \bibliographystyle{plain}
% %
\section{} \section{Introduction}
% %
\begin{mainthm}
Suppose that $G$ is a group with a $p$-cyclic Sylow subgroup.
Let $X$ be a curve with an action of~$G$ over a field $k$ of characteristic $p$.
The $k[G]$-module structure of $H^1_{dR}(X)$ is uniquely determined by the lower ramification groups and the fundamental characters of closed
points $x$ of $X$ that are ramified in the cover $X \to X/G$.
\end{mainthm}
\section{Cyclic covers} \section{Cyclic covers}
% %
Let for any $\ZZ/p^n$-cover $X \to Y$ Let for any $\ZZ/p^n$-cover $X \to Y$
@ -206,7 +213,17 @@ Note also that for $j \ge 1$:
???? ????
\end{proof} \end{proof}
% %
\begin{Lemma}
For any $i \le p^n - 1$:
%
\[
(\sigma - 1) : T^{i+1} M \hookrightarrow T^i M.
\]
\end{Lemma}
\begin{proof}
\end{proof}
%
\begin{proof}[Proof of Theorem ????] \begin{proof}[Proof of Theorem ????]
We use the following notation: $H' := \langle \sigma^p \rangle \cong \ZZ/p^{n-1}$, We use the following notation: $H' := \langle \sigma^p \rangle \cong \ZZ/p^{n-1}$,
$H'' := H/\langle \sigma^{p^{n-1}} \rangle \cong \ZZ/p^{n-1}$, $Y' := X/H'$, $X'' := X/H''$. $H'' := H/\langle \sigma^{p^{n-1}} \rangle \cong \ZZ/p^{n-1}$, $Y' := X/H'$, $X'' := X/H''$.
@ -224,7 +241,7 @@ Note also that for $j \ge 1$:
m' := m' :=
\begin{cases} \begin{cases}
n-1, & \textrm{ if } m = n,\\ n-1, & \textrm{ if } m = n,\\
n, & \textrm{ otherwise.} m, & \textrm{ otherwise.}
\end{cases} \end{cases}
\] \]
@ -236,7 +253,50 @@ Note also that for $j \ge 1$:
???, ???,
\end{cases} \end{cases}
\end{align*} \end{align*}
%
In particular, $\dim_k \mc T^1 M = \ldots = \dim_k \mc T^{p^{n-1} - p^{n-2}} M$.
On the other hand, by Lemma ??:
%
\begin{align*}
\dim_k \mc T^1 M &= \dim_k T^1 M + \ldots + \dim_k T^p M\\
&\ge \dim_k T^{p^n - p^{n-1}} M + \ldots + \dim_k T^{p^n - p^{n-1}} M
= \dim_k \mc T^{p^{n-1} - p^{n-2}} M.
\end{align*}
%
Since the left-hand side and right hand side are equal, we conclude by Lemma ???
that
%
\[
\dim_k T^1 M = \ldots = \dim_k T^{p^n - p^{n-1}} M = \frac{1}{p} \dim_k \mc T^1 M.
\]
%
If the cover $X \to X''$ is \'{e}tale, then the cover $X \to Y$ must be also \'{e}tale.
Thus the proof follows in this case by~\cite{Nakajima??Inventiones}. Suppose now that
$X \to X''$ is not \'{e}tale. Then, by Lemma ???, the map $\tr_{X/X''} : H^1_{dR}(X) \to H^1_{dR}(X'')$ is surjective. Moreover, note that in the group ring $k[H]$ we have:
%
\[
\tr_{X/X''} = \sum_{j = 0}^{p-1} (\sigma^{p^{n-1}})^j = (\sigma^{p^{n-1}} - 1)^{p-1} =
(\sigma - 1)^{p^n - p^{n-1}}.
\]
%
This implies that:
%
\[
\ker(\tr_{X/X''} : M \to M'') = M^{(p^n - p^{n-1})}
\]
%
and that $\tr_{X/X''}$ induces a $k$-linear isomorphism $T^{i + p^n - p^{n-1}} M \to \mc T^i M''$ for any $i \ge 1$. Thus:
%
\[
\dim_k T^{i + p^n - p^{n-1}} M = \dim_k \mc T^i M'' = ....
\]
%
This ends the proof.
\end{proof} \end{proof}
\section{Hypoelementary covers}
%
Assume now that $G = H \rtimes_{\chi} \ZZ/??n$.
\bibliography{bibliografia} \bibliography{bibliografia}
\end{document} \end{document}