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slides-muenchenwiler2018.tex
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\title{New reduction techniques in commutative algebra driven by logical methods}
\author{Ingo Blechschmidt}
\date{October 24th, 2018}
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\textcolor{#2}{The forcing model}
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\begin{document}
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{\usebackgroundtemplate{\begin{minipage}{\paperwidth}\vspace*{4.95cm}\includegraphics[width=\paperwidth]{topos-horses}\end{minipage}}
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\centering
\bigskip
\includegraphics[width=0.4\textwidth]{external-internal-small}
\bigskip
\hil{New reduction techniques in commutative algebra driven by logical methods}
\scriptsize
\textit{-- an invitation --}
\bigskip
Ingo Blechschmidt \\
Università di Verona
\bigskip
Münchenwiler Meeting Autumn 2018 \\
October 24th, 2018
\par
\end{frame}}
\section{Summary}
\setbeamertemplate{headline}{\mynav{black}{gray}{gray}}
\begin{frame}{Summary}
\vspace*{-1em}
\visible<4>{
\begin{changemargin}{-2.0em}{-0.5em}
\begin{itemize}
\item \ \\[-1.2em]\mbox{For any reduced ring~$A$, there is a ring~$A^\sim$ in a certain topos with}
\[ \models \bigl(\forall x\?A^\sim\_ \neg(\exists y\?A^\sim\_ xy = 1) \Rightarrow x = 0\bigr). \]
\item This semantics is sound with respect to intuitionistic logic.
\item \ \\[-1.2em]\mbox{It has uses in classical and constructive commutative
algebra.}
\end{itemize}
\end{changemargin}
}
\vspace*{-1.5em}
\begin{columns}[t]
\begin{column}[t]{0.52\textwidth}
\centering
\begin{varblock}{\textwidth}{A baby example}
\justifying
Let~$M$ be an injective matrix with more columns than rows over a
reduced ring~$A$.
Then~$1 = 0$ in~$A$.
\end{varblock}
\vspace*{-0.5em}
\only<1>{
\scalebox{0.8}{$\begin{pmatrix}
\cdot & \cdot & \cdot & \cdot & \cdot \\
\cdot & \cdot & \cdot & \cdot & \cdot \\
\cdot & \cdot & \cdot & \cdot & \cdot
\end{pmatrix}$}
}
\visible<2->{
\justifying
\textbf{Proof.} \bad{Assume not.} Then there is a \bad{minimal
prime ideal} $\ppp \subseteq A$. The matrix is injective over the \bad{field}~$A_\ppp = A[(A
\setminus \ppp)^{-1}]$; contradiction to basic linear algebra.
}
\end{column}
\begin{column}[t]{0.46\textwidth}
\centering
\begin{varblock}{\textwidth}{Generic freeness\phantom{p}}
\justifying
Generically, any finitely generated module over a reduced ring
is free.\phantom{g}
\end{varblock}
\vspace*{-0.5em}
\only<1-2>{{
\scriptsize\raggedright
(A ring is reduced iff $x^n=0$ implies $x=0$.)
\par
}}
\only<1-2>{\includegraphics[width=0.73\textwidth]{generic-freeness}}
\visible<3->{
\justifying
\textbf{Proof.} See [Stacks Project].
}
\end{column}
\end{columns}
\end{frame}
\section{The forcing model}
\setbeamertemplate{headline}{\mynav{gray}{black}{gray}}
\begin{frame}{Motivating the semantics}
\centering
\begin{varblockextra}{0.8\textwidth}{}{
\hil{Examples:}\phantom{Non-}\,\! $k,\ k[[X]],\ \CC\{z\},\ \ZZ_{(p)}$ \\[0.2em]
\hil{Non-examples:} $\ZZ,\ k[X],\ \ZZ/(pq)$
}
\justifying
A ring is \hil{local} iff~$1 \neq 0$ and if~$x + y = 1$ implies that~$x$ is
invertible or~$y$ is invertible.
\end{varblockextra}
\begin{varblockextra}{0.8\textwidth}{}{
Let~$x + y = 1$ in a ring~$A$.
Then:
\begin{itemize}
\item The element $x$ is invertible in~$A[x^{-1}]$.
\item The element $y$ is invertible in~$A[y^{-1}]$.
\end{itemize}
}
\hil{Locally,} any ring is local.
\end{varblockextra}
\end{frame}
\begin{frame}{The Kripke--Joyal semantics}
\small
\mbox{\!\!\!Recall~$A[f^{-1}] = \bigl\{ \frac{u}{f^n} \,|\, u \in A, n \in \NN \bigr\}$.
Let~``$\models \varphi$'' be short for~``$1 \models \varphi$''.}
\only<1>{\[ \renewcommand{\arraystretch}{1.25}\begin{array}{@{}l@{\quad}c@{\quad}l@{}}
f \models \top &\text{iff}& \top \\
f \models \bot &\text{iff}& \text{$f$ is nilpotent} \\
f \models x = y &\text{iff}& x = y \in A[f^{-1}] \\
f \models \varphi \wedge \psi &\text{iff}&
\text{$f \models \varphi$ and $f \models \psi$} \\
f \models \varphi \vee \psi &\text{iff}&
\text{there exists a partition~$f^n = fg_1 + \cdots + fg_m$ with,} \\
&&\quad\text{for each~$i$, $fg_i \models \varphi$ or $fg_i \models \psi$} \\
f \models \varphi \Rightarrow \psi &\text{iff}&
\text{for all~$g \in A$, $fg \models \varphi$ implies $fg \models \psi$} \\
f \models \forall x\?A^\sim\_ \varphi &\text{iff}&
\text{for all~$g \in A$ and all $x_0 \in A[(fg)^{-1}]$, $fg \models \varphi[x_0/x]$} \\
f \models \exists x\?A^\sim\_ \varphi &\text{iff}&
\text{there exists a partition~$f^n = fg_1 + \cdots + fg_m$ with,} \\
&&\quad\text{for each~$i$, $fg_i \models \varphi[x_0/x]$ for some~$x_0 \in A[(fg_i)^{-1}]$}
\end{array} \]}
\only<2->{\[ \renewcommand{\arraystretch}{1.25}\begin{array}{@{}l@{\quad}c@{\quad}l@{}}
f \models x = y &\text{iff}& x = y \in A[f^{-1}] \\
f \models \varphi \wedge \psi &\text{iff}&
\text{$f \models \varphi$ and $f \models \psi$} \\
f \models \varphi \vee \psi &\text{iff}&
\text{there exists a partition~$f^n = fg_1 + \cdots + fg_m$ with,} \\
&&\quad\text{for each~$i$, $fg_i \models \varphi$ or $fg_i \models \psi$}
\end{array} \]}
\pause
\begin{columns}
\begin{column}{0.50\textwidth}
\begin{varblock}{\textwidth}{Monotonicity}{}
If~$f \models \varphi$, then also~$fg \models \varphi$.
\end{varblock}
\end{column}
\begin{column}{0.50\textwidth}
\begin{varblock}{\textwidth}{Locality}{}
\justifying
If~$f^n = fg_1 + \cdots + fg_m$ and~$fg_i \models \varphi$ for all~$i$,
then also~$f \models \varphi$.
\end{varblock}
\end{column}
\end{columns}
\begin{columns}
\begin{column}{0.50\textwidth}
\begin{varblock}{\textwidth}{Soundness\phantom{p}}{}
If~$\varphi \vdash \psi$ and~$f \models \varphi$,
then~$f \models \psi$.
\end{varblock}
\end{column}
\begin{column}{0.50\textwidth}
\begin{varblock}{\textwidth}{Forced properties}{}
$A \models \speak{$A^\sim$ is a local ring}$.
\end{varblock}
\end{column}
\end{columns}
\end{frame}
\tikzstyle{topos} = [draw=mypurple, very thick, rectangle, rounded corners, inner sep=5pt, inner ysep=10pt]
\tikzstyle{title} = [fill=mypurple, text=white]
\input{images/primes.tex}
%\renewcommand{\sieve}[2]{SIEVE}
%\renewcommand{\fakesieve}[2]{SIEVE}
\newcommand{\drawbox}[4]{
\node[topos, #4] [fit = #3] (#1) {};
\node[title] at (#1.north) {#2};
}
\newcommand{\muchstuff}{
\includegraphics[height=3em]{filmat}
\scalebox{0.5}{\sieve{14}{2}}
}
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\scalebox{0.5}{\fakesieve{14}{2}}
}
\newcommand{\fewstuff}{
\includegraphics[height=3em]{filmat}
\scalebox{0.5}{\sieve{7}{2}}
}
\begin{frame}[fragile]{A universal property}
The displayed semantics is the first-order fragment of the \hil{higher-order
internal language} of the \hil{little Zariski topos}.
\begin{tikzpicture}
\node[scale=0.4] (objs-set1) at (-4.0,-2.5) {
\only<1->{\fewstuff}
};
\node[scale=0.4] (objs-eff1) at (4.0,-2.5) {
\only<1->{\fewstuff}
};
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\only<1->{\fewstuff}
};
\node (prop-set1) [below of=objs-set1, align=left, inner ysep=0pt] {
The usual laws \\
of logic hold.
};
\node (prop-eff1) [below of=objs-eff1, align=left, inner ysep=0pt] {
Every function \\
is computable.
};
\node (prop-sh1) [below of=objs-sh1, align=left, inner sep=0pt] {
The intermediate \\
value theorem fails.
};
\begin{scope}
\drawbox{set1}{$\mathrm{Set}$}{(objs-set1) (prop-set1)}{}
\end{scope}
\begin{scope}
\drawbox{eff1}{Ef{}f}{(objs-eff1) (prop-eff1)}{tape}
\end{scope}
\begin{scope}
\drawbox{sh1}{$\mathrm{Sh}\, X$}{(objs-sh1) (prop-sh1)}{draw=none}
\def\R{8pt}
\begin{pgfonlayer}{background}
\draw[decoration={bumps,segment length=8pt}, decorate, very thick, draw=mypurple]
($(sh1.south west) + (\R, 0)$) arc(270:180:\R) --
($(sh1.north west) + (0, -\R)$) arc(180:90:\R) --
($(sh1.north east) + (-\R, 0)$) arc(90:0:\R) --
($(sh1.south east) + (0, \R)$) arc(0:-90:\R) --
cycle;
\end{pgfonlayer}
\end{scope}
\end{tikzpicture}
\pause
Is there a \hil{free local ring}~$A \to A'$ over~$A$?
\begin{columns}[t]
\begin{column}{0.4\textwidth}
$\xymatrix{
A \ar[rd] \ar[rrr]^\alpha &&& {\substack{\text{local}\\\text{\normalsize$R$}\\\phantom{\text{local}}}} \\
& {\substack{\text{\normalsize$A'$}\\\text{local}}} \ar@{-->}_[@!34]{\text{local}}[rru]
}$
\end{column}
\begin{column}{0.50\textwidth}
\small\justifying
For a fixed ring~$R$, the localization $A' \defeq A[S^{-1}]$ with $S \defeq
\alpha^{-1}[R^\times]$ would do the job.
\medskip
Hence we need the \hil{generic filter}.
\end{column}
\end{columns}
\end{frame}
\begin{frame}{Investigating the forcing model}
Let~$A$ be a reduced commutative ring ($x^n = 0 \Rightarrow x = 0$).
The \hil{little Zariski topos} of~$A$ is equivalently
\vspace*{-0.5em}
\begin{itemize}
\item the topos of sheaves over~$\Spec(A)$,
\item the locale given by the frame of radical ideals of~$A$,
% \item the classifying topos of local localizations of~$A$ or
\item the classifying topos of filters of~$A$
\end{itemize}
\vspace*{-0.5em}
and contains a \hil{mirror image} of~$A$, the sheaf of rings $A^\sim$.
\vspace*{-1.5em}
\small
\begin{columns}
\begin{column}{0.5\textwidth}
\begin{varblock}{\textwidth}{}
\justifying
Assuming the Boolean Prime Ideal Theorem, a first-order
formula ``$\forall \ldots \forall\_ (\cdots \Longrightarrow \cdots\!\,)$'',
where the two subformulas may not contain~``$\Rightarrow$'' and~``$\forall$'',
holds for~$A^\sim$ iff it holds for all stalks~$A_\ppp$.
\end{varblock}
\end{column}
\begin{column}{0.5\textwidth}
\begin{varblock}{\textwidth}{}
$A^\sim$ inherits any property of~$A$ which is
\hil{localization-stable}.
\end{varblock}
\vspace*{-1.7em}
\setbeamercolor{block body}{bg=red!30}
\setbeamercolor{structure}{fg=purple}
\begin{varblock}{\textwidth}{}
$A^\sim$ is a \hil{local ring} and a \hil{field}.
$A^\sim$ has \hil{$\boldsymbol{\neg\neg}$-stable equality}.
\mbox{$A^\sim$ is \hil{anonymously Noetherian}.}\\[-1.2em]
\end{varblock}
\end{column}
\end{columns}
\visible<2>{\begin{tikzpicture}[overlay]
\draw[fill=white, draw=white, opacity=0.85] (-1,0) rectangle (\paperwidth,7.4);
\node[anchor=south west,inner sep=0] (image) at (0,0.8) {\vbox{
\centering
\includegraphics[width=0.9\textwidth]{tierney-on-the-spectrum-of-a-ringed-topos} \\
\footnotesize
Miles Tierney. On the spectrum of a ringed topos. 1976.
}};
\end{tikzpicture}}
\end{frame}
\renewcommand{\insertframeextra}{}
\section{Revisiting the test cases}
\setbeamertemplate{headline}{\mynav{gray}{gray}{black}}
\begin{frame}{Revisiting the test cases}
\vspace*{-1em}
Let~$A$ be a reduced commutative ring ($x^n = 0 \Rightarrow x = 0$). \\
Let~$A^\sim$ be its mirror image in the little Zariski topos.
\begin{columns}[t]
\begin{column}[t]{0.48\textwidth}
\centering
\scalebox{0.5}{$\begin{pmatrix}
\cdot & \cdot & \cdot & \cdot & \cdot \\
\cdot & \cdot & \cdot & \cdot & \cdot \\
\cdot & \cdot & \cdot & \cdot & \cdot
\end{pmatrix}$}
\vspace*{-0.5em}
\begin{varblock}{\textwidth}{A baby example}
\justifying
Let~$M$ be an injective matrix over~$A$ with more columns than rows.
Then~$1 = 0$ in~$A$.
\end{varblock}
\justifying
\textbf{Proof.} $M$ is also injective as a matrix over~$A^\sim$.
Since~$A^\sim$ is a field, this is a contradiction by basic linear
algebra. Thus~$\models \bot$. This amounts to~$1 = 0$ in~$A$.
\end{column}
\begin{column}[t]{0.57\textwidth}
\centering
\includegraphics[height=1.9em]{generic-freeness}
\vspace*{-0.5em}
\begin{varblock}{\textwidth}{Generic freeness\phantom{p}}
\justifying
Let~$M$ be a finitely generated~$A$-module.
If~$f = 0$ is the only element of~$A$ such that~$M[f^{-1}]$ is a
free~$A[f^{-1}]$-module, then~$1 = 0$ in~$A$.
\end{varblock}
\vspace*{-0.1em}
\justifying
\textbf{Proof.} The claim amounts to \mbox{$\models
\text{``$M^\sim$}$}$\text{
is \hil{not not} free''}$. Since~$A^\sim$ is a field, this follows from
basic linear algebra.
\end{column}
\end{columns}
\end{frame}
\backupstart
\setbeamertemplate{headline}{\mynav{gray}{gray}{gray}}
{\usebackgroundtemplate{\begin{minipage}{\paperwidth}\vspace*{4.95cm}\includegraphics[width=\paperwidth]{topos-horses}\end{minipage}}
\begin{frame}
\bigskip
\centering
\includegraphics[height=3em]{heart}
\par
\raggedright
The Zariski topos and related toposes have applications in:
\begin{itemize}
\item classical algebra and classical algebraic geometry
\item constructive algebra and constructive algebraic geometry
\item synthetic algebraic geometry (``schemes are just sets'')
\end{itemize}
Connections with:
\begin{itemize}
\item understanding quasicoherence
\item the age-old mystery of nongeometric sequents
\end{itemize}
\end{frame}}
\begin{frame}[plain,c]
\centering%
\hil{Further reading}
\medskip
\framebox{\href{https://pizzaseminar.speicherleck.de/skript2/zariski-topos-klein.pdf}{\includegraphics[height=0.8\textheight]{fun-with-the-zariski-topos}}}\qquad%
\framebox{\href{https://rawgit.com/iblech/internal-methods/master/notes.pdf}{\includegraphics[height=0.8\textheight]{phd-cover}}}
\par
\end{frame}
\begin{frame}{Applications in algebraic geometry}
\vspace*{-1.5em}
\begin{varblock}{0.9\textwidth}{}
\justifying
Understand notions of algebraic geometry over a scheme~$X$ as
notions of algebra internal to~$\Sh(X)$.
\end{varblock}
\small\centering
\scalebox{0.83}{\begin{tabular}{ll}
\toprule
externally & internally to $\Sh(X)$ \\
\midrule
sheaf of sets & set \\
%sheaf of rings & ring \\
sheaf of modules & module \\
sheaf of finite type & finitely generated module \\
% finite locally free sheaf & finite free module \\
% coherent sheaf & coherent module \\
tensor product of sheaves & tensor product of modules \\
% sheaf of Kähler differentials & module of Kähler differentials \\
sheaf of rational functions & total quotient ring of~$\O_X$ \\
dimension of $X$ & Krull dimension of~$\O_X$ \\
spectrum of a sheaf of~$\O_X$-algebras & ordinary spectrum [with a twist] \\
higher direct images & sheaf cohomology \\
\bottomrule
\end{tabular}}
\begin{columns}[c]
\begin{column}{0.47\textwidth}
\begin{exampleblock}{}
\justifying
Let $0 \to \F' \to \F \to \F'' \to 0$ be a short exact sequence
of sheaves of~$\O_X$-modules. If~$\F'$ and~$\F''$ are of finite type,
so is~$\F$.
\end{exampleblock}
\end{column}
\begin{column}{0.1\textwidth}
\vspace*{0.7em}
\scalebox{3}{$\Leftarrow$}
\end{column}
\begin{column}{0.44\textwidth}
\begin{exampleblock}{}
\justifying
Let~$0 \to M' \to M \to M'' \to 0$ be a short exact sequence of
modules. If~$M'$ and~$M''$ are finitely generated, so is~$M$.
\end{exampleblock}
\end{column}
\end{columns}
\end{frame}
\begin{frame}{Synthetic algebraic geometry}
Usual approach to algebraic geometry: \hil{layer schemes above ordinary set theory}
using either
\begin{itemize}
\item locally ringed spaces
\small
\begin{multline*}
\text{set of prime ideals of~$\ZZ[X,Y,Z]/(X^n+Y^n-Z^n)$} + {} \\
\text{Zariski topology} + \text{structure sheaf}
\end{multline*}
\normalsize
\item or Grothendieck's functor-of-points account, where a scheme is a functor~$\mathrm{Ring} \to \mathrm{Set}$.
\small\[ A \longmapsto \{ (x,y,z) \in A^3 \,|\, x^n+y^n-z^n=0 \} \]
\end{itemize}
\bigskip
\hil{Synthetic approach:} model schemes \hil{directly as sets} in a certain
nonclassical set theory, the internal universe of the \mbox{\hil{big Zariski
topos}} of a base scheme.
\small
\[ \{ (x,y,z) \? (\affl)^3 \,|\, x^n+y^n-z^n=0 \} \]
\end{frame}
\backupend
\end{document}
% FUTURE:
% Better explain that, at the point where we just have syntax, A~ is not really
% anything, but just notation.