--- a/pnas/pnas.tex Sun Nov 14 16:02:06 2010 -0800
+++ b/pnas/pnas.tex Sun Nov 14 16:13:12 2010 -0800
@@ -239,10 +239,7 @@
\nn{say something about defining plain and infty cases simultaneously}
There are five basic ingredients
-(not two, or four, or seven, but {\bf five} basic ingredients,
-which he shall wield all wretched sinners and that includes on you, sir, there in the front row!
-(cf.\ Monty Python, Life of Brian, http://www.youtube.com/watch?v=fIRb8TigJ28))
-of an $n$-category definition:
+\cite{life-of-brian} of an $n$-category definition:
$k$-morphisms (for $0\le k \le n$), domain and range, composition,
identity morphisms, and special behavior in dimension $n$ (e.g. enrichment
in some auxiliary category, or strict associativity instead of weak associativity).
@@ -636,7 +633,7 @@
\subsection{Specializations}
\label{sec:specializations}
-The blob complex has two important special cases.
+The blob complex has several important special cases.
\begin{thm}[Skein modules]
\label{thm:skein-modules}
@@ -663,6 +660,20 @@
Theorem \ref{thm:hochschild} is established by extending the statement to bimodules as well as categories, then verifying that the universal properties of Hochschild homology also hold for $\bc_*(S^1; -)$.
+\begin{thm}[Mapping spaces]
+\label{thm:map-recon}
+Let $\pi^\infty_{\le n}(T)$ denote the $A_\infty$ $n$-category based on maps
+$B^n \to T$.
+(The case $n=1$ is the usual $A_\infty$-category of paths in $T$.)
+Then
+$$\bc_*(X; \pi^\infty_{\le n}(T)) \simeq \CM{X}{T}.$$
+\end{thm}
+
+This says that we can recover (up to homotopy) the space of maps to $T$ via blob homology from local data.
+Note that there is no restriction on the connectivity of $T$ as there is for the corresponding result in topological chiral homology \cite[Theorem 3.8.6]{0911.0018}.
+\todo{sketch proof}
+
+
\subsection{Structure of the blob complex}
\label{sec:structure}
@@ -700,12 +711,6 @@
\end{equation*}
\end{thm}
-\nn{if we need to save space, I think this next paragraph could be cut}
-Since the blob complex is functorial in the manifold $X$, this is equivalent to having chain maps
-$$ev_{X \to Y} : \CH{X \to Y} \tensor \bc_*(X) \to \bc_*(Y)$$
-for any homeomorphic pair $X$ and $Y$,
-satisfying corresponding conditions.
-
\begin{proof}(Sketch.)
The most convenient way to prove this is to introduce yet another homotopy equivalent version of
the blob complex, $\cB\cT_*(X)$.
@@ -774,22 +779,8 @@
\nn{Theorem \ref{thm:product} is proved in \S \ref{ss:product-formula}, and Theorem \ref{thm:gluing} in \S \ref{sec:gluing}.}
-\section{Applications}
+\section{Higher Deligne conjecture}
\label{sec:applications}
-Finally, we give two applications of the above machinery.
-
-\begin{thm}[Mapping spaces]
-\label{thm:map-recon}
-Let $\pi^\infty_{\le n}(T)$ denote the $A_\infty$ $n$-category based on maps
-$B^n \to T$.
-(The case $n=1$ is the usual $A_\infty$-category of paths in $T$.)
-Then
-$$\bc_*(X; \pi^\infty_{\le n}(T)) \simeq \CM{X}{T}.$$
-\end{thm}
-
-This says that we can recover (up to homotopy) the space of maps to $T$ via blob homology from local data.
-Note that there is no restriction on the connectivity of $T$ as there is for the corresponding result in topological chiral homology \cite[Theorem 3.8.6]{0911.0018}.
-\todo{sketch proof}
\begin{thm}[Higher dimensional Deligne conjecture]
\label{thm:deligne}
@@ -845,7 +836,6 @@
Justin Roberts,
and
Peter Teichner.
-\nn{not full list from big paper, but only most significant names}
We also thank the Aspen Center for Physics for providing a pleasant and productive
environment during the last stages of this project.
\end{acknowledgments}
--- a/pnas/preamble.tex Sun Nov 14 16:02:06 2010 -0800
+++ b/pnas/preamble.tex Sun Nov 14 16:13:12 2010 -0800
@@ -99,8 +99,8 @@
\applytolist{bbc}QWERTYUIOPLKJHGFDSAZXCVBNM;
% \def\bA{{\mathbf A}} for A..Z
-\def\bc#1{\expandafter\def\csname b#1\endcsname{{\mathbf #1}}}
-\applytolist{bc}QWERTYUIOPLKJHGFDSAZXCVBNM;
+\def\bfc#1{\expandafter\def\csname bf#1\endcsname{{\mathbf #1}}}
+\applytolist{bfc}QWERTYUIOPLKJHGFDSAZXCVBNM;
% \DeclareMathOperator{\pr}{pr} etc.
\def\declaremathop#1{\expandafter\DeclareMathOperator\csname #1\endcsname{#1}}