# HG changeset patch # User Kevin Walker # Date 1269991889 25200 # Node ID a36840bd763161330dcd44391feee4dfd4aba6af # Parent 0488412c274b0caa35b8c0e36982929e5d49afc4# Parent fa0ec034acc63e8898b48de4774a63a059eb4962 Automated merge with https://tqft.net/hg/blob/ diff -r 0488412c274b -r a36840bd7631 blob1.tex --- a/blob1.tex Tue Mar 30 10:03:48 2010 -0700 +++ b/blob1.tex Tue Mar 30 16:31:29 2010 -0700 @@ -44,6 +44,7 @@ On the other hand, if you are only going to read this paper once, {\bf then don't read this version,} as a more complete version will be available in a couple of months. +\nn{maybe to do: add appendix on various versions of acyclic models} %\tableofcontents diff -r 0488412c274b -r a36840bd7631 text/hochschild.tex --- a/text/hochschild.tex Tue Mar 30 10:03:48 2010 -0700 +++ b/text/hochschild.tex Tue Mar 30 16:31:29 2010 -0700 @@ -329,8 +329,9 @@ %and the two boundary points of $N_\ep$ are not labeled points of $b$. For a field $y$ on $N_\ep$, let $s_\ep(y)$ be the equivalent picture with~$*$ labeled by $1\otimes 1$ and the only other labeled points at distance $\pm\ep/2$ from $*$. -(See Figure \ref{fig:sy}.) Note that $y - s_\ep(y) \in U(N_\ep)$. We can think of -$\sigma_\ep$ as a chain map $K_*^\ep \to K_*^\ep$ given by replacing the restriction $y$ to $N_\ep$ of each field +(See Figure \ref{fig:sy}.) Note that $y - s_\ep(y) \in U(N_\ep)$. +Let $\sigma_\ep: K_*^\ep \to K_*^\ep$ be the chain map +given by replacing the restriction $y$ to $N_\ep$ of each field appearing in an element of $K_*^\ep$ with $s_\ep(y)$. Note that $\sigma_\ep(x) \in K'_*$. \begin{figure}[!ht] @@ -369,21 +370,22 @@ $x \in K_*^\ep$. (This is true for any chain in $K_*(C\otimes C)$, since chains are sums of finitely many blob diagrams.) -Then $x$ is homologous to $s_\ep(x)$, which is in $K'_*$, so the inclusion map +Then $x$ is homologous to $\sigma_\ep(x)$, which is in $K'_*$, so the inclusion map $K'_* \sub K_*(C\otimes C)$ is surjective on homology. -If $y \in K_*(C\otimes C)$ and $\bd y = x \in K'_*$, then $y \in K_*^\ep$ for some $\ep$ +If $y \in K_*(C\otimes C)$ and $\bd y = x \in K_*(C\otimes C)$, then $y \in K_*^\ep$ for some $\ep$ and \eq{ \bd y = \bd (\sigma_\ep(y) + j_\ep(x)) . } -Since $\sigma_\ep(y) + j_\ep(x) \in F'$, it follows that the inclusion map is injective on homology. +Since $\sigma_\ep(y) + j_\ep(x) \in K'_*$, it follows that the inclusion map is injective on homology. This completes the proof that $K'_*$ is quasi-isomorphic to $K_*(C\otimes C)$. Let $K''_* \sub K'_*$ be the subcomplex of $K'_*$ where $*$ is not contained in any blob. We will show that the inclusion $i: K''_* \to K'_*$ is a homotopy equivalence. -First, a lemma: Let $G''_*$ and $G'_*$ be defined the same as $K''_*$ and $K'_*$, except with -$S^1$ replaced some (any) neighborhood of $* \in S^1$. +First, a lemma: Let $G''_*$ and $G'_*$ be defined similarly to $K''_*$ and $K'_*$, except with +$S^1$ replaced by some neighborhood $N$ of $* \in S^1$. +($G''_*$ and $G'_*$ depend on $N$, but that is not reflected in the notation.) Then $G''_*$ and $G'_*$ are both contractible and the inclusion $G''_* \sub G'_*$ is a homotopy equivalence. For $G'_*$ the proof is the same as in (\ref{bcontract}), except that the splitting @@ -391,8 +393,8 @@ For $G''_*$ we note that any cycle is supported \nn{need to establish terminology for this; maybe in ``basic properties" section above} away from $*$. Thus any cycle lies in the image of the normal blob complex of a disjoint union -of two intervals, which is contractible by (\ref{bcontract}) and (\ref{disjunion}). -Actually, we need the further (easy) result that the inclusion +of two intervals, which is contractible by (\ref{bcontract}) and (\ref{disj-union-contract}). +Finally, it is easy to see that the inclusion $G''_* \to G'_*$ induces an isomorphism on $H_0$. Next we construct a degree 1 map (homotopy) $h: K'_* \to K'_*$ such that @@ -465,7 +467,7 @@ \label{fig:hochschild-1-chains} \end{figure} -In degree 2, we send $m\ot a \ot b$ to the sum of 24 (=6*4) 2-blob diagrams as shown in +In degree 2, we send $m\ot a \ot b$ to the sum of 24 ($=6\cdot4$) 2-blob diagrams as shown in Figure \ref{fig:hochschild-2-chains}. In Figure \ref{fig:hochschild-2-chains} the 1- and 2-blob diagrams are indicated only by their support. We leave it to the reader to determine the labels of the 1-blob diagrams. \begin{figure}[!ht] @@ -482,7 +484,8 @@ 1-blob diagrams in its boundary. Such a 2-cell corresponds to a sum of the 2-blob diagrams obtained by adding $V$ as an outer (non-twig) blob to each of the 1-blob diagrams in the boundary of the 2-cell. -Figure \ref{fig:hochschild-example-2-cell} shows this explicitly for one of the 2-cells. +Figure \ref{fig:hochschild-example-2-cell} shows this explicitly for the 2-cell +labeled $A$ in Figure \ref{fig:hochschild-2-chains}. Note that the (blob complex) boundary of this sum of 2-blob diagrams is precisely the sum of the 1-blob diagrams corresponding to the boundary of the 2-cell. (Compare with the proof of \ref{bcontract}.)