small pice of surgery lecture
This commit is contained in:
parent
2606bba015
commit
7ce1d8a6b9
BIN
images/dehn_twist.pdf
Normal file
BIN
images/dehn_twist.pdf
Normal file
Binary file not shown.
61
images/dehn_twist.pdf_tex
Normal file
61
images/dehn_twist.pdf_tex
Normal file
@ -0,0 +1,61 @@
|
||||
%% Creator: Inkscape inkscape 0.92.2, www.inkscape.org
|
||||
%% PDF/EPS/PS + LaTeX output extension by Johan Engelen, 2010
|
||||
%% Accompanies image file 'dehn_twist.pdf' (pdf, eps, ps)
|
||||
%%
|
||||
%% To include the image in your LaTeX document, write
|
||||
%% \input{<filename>.pdf_tex}
|
||||
%% instead of
|
||||
%% \includegraphics{<filename>.pdf}
|
||||
%% To scale the image, write
|
||||
%% \def\svgwidth{<desired width>}
|
||||
%% \input{<filename>.pdf_tex}
|
||||
%% instead of
|
||||
%% \includegraphics[width=<desired width>]{<filename>.pdf}
|
||||
%%
|
||||
%% Images with a different path to the parent latex file can
|
||||
%% be accessed with the `import' package (which may need to be
|
||||
%% installed) using
|
||||
%% \usepackage{import}
|
||||
%% in the preamble, and then including the image with
|
||||
%% \import{<path to file>}{<filename>.pdf_tex}
|
||||
%% Alternatively, one can specify
|
||||
%% \graphicspath{{<path to file>/}}
|
||||
%%
|
||||
%% For more information, please see info/svg-inkscape on CTAN:
|
||||
%% http://tug.ctan.org/tex-archive/info/svg-inkscape
|
||||
%%
|
||||
\begingroup%
|
||||
\makeatletter%
|
||||
\providecommand\color[2][]{%
|
||||
\errmessage{(Inkscape) Color is used for the text in Inkscape, but the package 'color.sty' is not loaded}%
|
||||
\renewcommand\color[2][]{}%
|
||||
}%
|
||||
\providecommand\transparent[1]{%
|
||||
\errmessage{(Inkscape) Transparency is used (non-zero) for the text in Inkscape, but the package 'transparent.sty' is not loaded}%
|
||||
\renewcommand\transparent[1]{}%
|
||||
}%
|
||||
\providecommand\rotatebox[2]{#2}%
|
||||
\ifx\svgwidth\undefined%
|
||||
\setlength{\unitlength}{473.80897342bp}%
|
||||
\ifx\svgscale\undefined%
|
||||
\relax%
|
||||
\else%
|
||||
\setlength{\unitlength}{\unitlength * \real{\svgscale}}%
|
||||
\fi%
|
||||
\else%
|
||||
\setlength{\unitlength}{\svgwidth}%
|
||||
\fi%
|
||||
\global\let\svgwidth\undefined%
|
||||
\global\let\svgscale\undefined%
|
||||
\makeatother%
|
||||
\begin{picture}(1,0.27139889)%
|
||||
\put(0.93744567,0.84793742){\color[rgb]{0,0,0}\makebox(0,0)[lt]{\begin{minipage}{0.20288042\unitlength}\raggedright \end{minipage}}}%
|
||||
\put(0,0){\includegraphics[width=\unitlength,page=1]{dehn_twist.pdf}}%
|
||||
\put(0.59840374,0.27413395){\color[rgb]{0,0,0}\makebox(0,0)[lt]{\begin{minipage}{0.47239041\unitlength}\raggedright ${\varphi_* (\lambda) =\lambda + \mu }$\end{minipage}}}%
|
||||
\put(0.5317083,0.04744417){\color[rgb]{0,0,0}\makebox(0,0)[lt]{\begin{minipage}{0.06259447\unitlength}\raggedright $\mu$\end{minipage}}}%
|
||||
\put(0,0){\includegraphics[width=\unitlength,page=2]{dehn_twist.pdf}}%
|
||||
\put(0.33797953,0.25664797){\color[rgb]{0,0,0}\makebox(0,0)[lt]{\begin{minipage}{0.04176691\unitlength}\raggedright $\lambda$\end{minipage}}}%
|
||||
\put(0.00765397,0.03952395){\color[rgb]{0,0,0}\makebox(0,0)[lt]{\begin{minipage}{0.06259447\unitlength}\raggedright $\mu$\end{minipage}}}%
|
||||
\put(0,0){\includegraphics[width=\unitlength,page=3]{dehn_twist.pdf}}%
|
||||
\end{picture}%
|
||||
\endgroup%
|
File diff suppressed because it is too large
Load Diff
Before Width: | Height: | Size: 43 KiB After Width: | Height: | Size: 48 KiB |
67
lec_5.tex
67
lec_5.tex
@ -114,9 +114,7 @@ So we can calculate:
|
||||
\end{proof}
|
||||
\begin{corollary}
|
||||
If $t$ is not a root of
|
||||
$\det S S^T - $ \\
|
||||
????????????????\\
|
||||
then
|
||||
$\det (tS - S^T) $, then
|
||||
$\vert \sigma_K(t) \vert \leq 2g$.
|
||||
\end{corollary}
|
||||
\begin{fact}
|
||||
@ -157,33 +155,56 @@ was conjecture in the '70 and proved by P. Kronheimer and T. Mrówka (1994).
|
||||
\end{example}
|
||||
\begin{proposition}
|
||||
$g_4 (T(p, q) \# -T(r, s))$ is in general hopelessly unknown.
|
||||
\\???????????????\\
|
||||
essentially $\sup \vert \sigma_K(t) \vert \leq 2 g_n(K)$
|
||||
\end{proposition}
|
||||
\begin{proposition}
|
||||
Supremum of the signature function of the knot is bounded almost everywhere by two times $4$ - genus:
|
||||
\[
|
||||
\ess \sup \vert \sigma_K(t) \vert \leq 2 g_4(K).
|
||||
\]
|
||||
\end{proposition}
|
||||
\subsection{Topological genus}
|
||||
\begin{definition}
|
||||
A knot $K$ is called topologically slice if $K$ bounds a topological locally flat disc in $B^4$ (it has tubular neighbourhood).
|
||||
A knot $K$ is called topologically slice if $K$ bounds a topological locally flat disc in $B^4$ (i.e. the disk has tubular neighbourhood).
|
||||
\end{definition}
|
||||
\begin{theorem}[Freedman, '82]
|
||||
If $\Delta_K(t) \geq 1$, then $K$ is topologically slice, but not necessarily smoothly slice.
|
||||
If $\Delta_K(t) = 1$, then $K$ is topologically slice (but not necessarily smoothly slice).
|
||||
\end{theorem}
|
||||
\begin{theorem}[Powell, 2015]
|
||||
If $K$ is genus g
|
||||
\\(top. loc.?????????)\\
|
||||
If $K$ is genus $g$
|
||||
(topologically flat)
|
||||
cobordant to $K^\prime$,
|
||||
then $\vert \sigma_K(t) - \sigma_{K^\prime}(t) \vert \leq 2 g$. \\
|
||||
If $g_4^{\mytop}(K) \geq $ ?????ess $\sup \vert \sigma_K(t) \vert$ and ?????????\\
|
||||
$\dim \ker (H_1 (Y) \longrightarrow H_1(\Omega)) = \frac{1}{2} \dim H_1(Y)$.
|
||||
\end{theorem}
|
||||
???????????????
|
||||
then
|
||||
\[
|
||||
H^1 (B^4 \setminus Y, \mathbb{Z}) = [B^4 \setminus Y, S^1]
|
||||
\vert \sigma_K(t) - \sigma_{K^\prime}(t) \vert \leq 2 g
|
||||
\]
|
||||
if $g_4^{\mytop}(K) \geq \ess \sup \vert \sigma_K(t) \vert$.
|
||||
\end{theorem}
|
||||
\noindent
|
||||
The proof for smooth category was based on following equality:
|
||||
\[
|
||||
\dim \ker (H_1 (Y) \longrightarrow H_1(\Omega)) = \frac{1}{2} \dim H_1(Y).
|
||||
\]
|
||||
For this equality we assumed that there exists a $3$ - dimensional manifold $\Omega$ (as shown in Figure \ref{fig:omega_in_B_4}) which was guaranteed by Pontryagin-Thom Construction.\\
|
||||
Pontryagin-Thom Construction relays on taking $\Omega$ as preimage of regular value:
|
||||
\[
|
||||
H^1 (B^4 \setminus Y, \mathbb{Z}) = [B^4 \setminus Y, S^1],
|
||||
\]
|
||||
what relies on Sard's theorem, that the set of regular values has positive measure. But Sard's theorem doesn't work for topologically locally flat category. So there was a gap in the proof for topological locally flat category - the existence of $\Omega$.\\
|
||||
\noindent
|
||||
Remark: unless $p=2$ or $p = 3 \wedge q = 4$:
|
||||
\[
|
||||
g_4^\top (T(p, q)) < q_4(T(p, q))
|
||||
g_4^{\mytop} (T(p, q)) < q_4(T(p, q)).
|
||||
\]
|
||||
%??????????????????????
|
||||
% Wilczyński '93
|
||||
%Feller 2014
|
||||
%Baoder 2017
|
||||
%Lemark
|
||||
\\
|
||||
\noindent
|
||||
From the category of cobordant knots (or topologically cobordant knots) there exists a map to $\mathbb{Z}$ given by signature function. To any element $K$ we can associate a form
|
||||
\[
|
||||
(1 - t)S + (1 - \bar{t})S^T) \in W(\mathbb{Z}[t, t^{-1}]).
|
||||
\] This association is not well define because id depends on the choice of Seifert form. However, different choices lead ever to congruent forms ($S \mapsto CSC^T$) or induced the change on the form by adding or subtracting a hyperbolic element.
|
||||
\begin{definition}
|
||||
The Witt group $W$ of $\mathbb{Z}[t, t^{-1}]$ elements are classes of non-degenerate
|
||||
forms over $\mathbb{Z}[t, t^{-1}]$ under the equivalence relation $V \sim W$ if $V \oplus - W$ is metabolic.
|
||||
@ -191,15 +212,21 @@ forms over $\mathbb{Z}[t, t^{-1}]$ under the equivalence relation $V \sim W$ if
|
||||
\noindent
|
||||
If $S$ differs from $S^\prime$ by a row extension, then
|
||||
$(1 - t) S + (1 - \bar{t}^{-1}) S^T$ is Witt equivalence to $(1 - t) S^\prime + (1 - t^{-1})S^T$.
|
||||
%???????????????????????????
|
||||
\\
|
||||
\noindent
|
||||
A form is meant as hermitian with respect to this involution: $A^T = A: (a, b) = \bar{(a, b)}$.
|
||||
\\
|
||||
????????????????????????????
|
||||
$
|
||||
W(\mathbb{Z}_p) = \mathbb{Z}_2 \oplus
|
||||
\mathbb{Z}_2$ or
|
||||
$\mathbb{Z}_4$
|
||||
\\
|
||||
???????????????????????
|
||||
\\
|
||||
$\sum a_gt^j \longrightarrow \sum a_g t^{-1}$\\
|
||||
\begin{theorem}[Levine '68]
|
||||
\[
|
||||
W(\mathbb{Z}[t^{\pm 1})
|
||||
W(\mathbb{Z}[t^{\pm 1}])
|
||||
\longrightarrow \mathbb{Z}_2^\infty \oplus
|
||||
\mathbb{Z}_4^\infty \oplus
|
||||
\mathbb{Z}
|
||||
|
@ -88,6 +88,7 @@
|
||||
\DeclareMathOperator{\rank}{rank}
|
||||
\DeclareMathOperator{\coker}{coker}
|
||||
\DeclareMathOperator{\ord}{ord}
|
||||
\DeclareMathOperator{\ess}{ess}
|
||||
\DeclareMathOperator{\mytop}{top}
|
||||
\DeclareMathOperator{\Gl}{GL}
|
||||
\DeclareMathOperator{\Sl}{SL}
|
||||
@ -121,27 +122,28 @@
|
||||
%\input{myNotes}
|
||||
|
||||
\section{Basic definitions \hfill\DTMdate{2019-02-25}}
|
||||
\input{lec_1.tex}
|
||||
%\input{lec_1.tex}
|
||||
|
||||
\section{Alexander polynomial \hfill\DTMdate{2019-03-04}}
|
||||
\input{lec_2.tex}
|
||||
%\input{lec_2.tex}
|
||||
%add Hurewicz theorem?
|
||||
|
||||
|
||||
\section{Examples of knot classes
|
||||
\hfill\DTMdate{2019-03-11}}
|
||||
\input{lec_3.tex}
|
||||
%\input{lec_3.tex}
|
||||
|
||||
\section{Concordance group \hfill\DTMdate{2019-03-18}}
|
||||
\input{lec_4.tex}
|
||||
%\input{lec_4.tex}
|
||||
|
||||
\section{Genus $g$ cobordism \hfill\DTMdate{2019-03-25}}
|
||||
\input{lec_5.tex}
|
||||
%\input{lec_5.tex}
|
||||
|
||||
\section{\hfill\DTMdate{2019-04-08}}
|
||||
\input{lec_6.tex}
|
||||
|
||||
\section{\hfill\DTMdate{2019-04-15}}
|
||||
???????????????????\\
|
||||
\begin{theorem}
|
||||
Suppose that $K \subset S^3$ is a slice knot (i.e. $K$ bound a disk in $B^4$).
|
||||
Then if $F$ is a Seifert surface of $K$ and $V$ denotes the associated Seifet matrix, then there exists $P \in \Gl_g(\mathbb{Z})$ such that:
|
||||
@ -236,6 +238,38 @@ H_1(Y, \mathbb{Z}) \times H_1(Y, \mathbb{Z}) &\longrightarrow \quot{\mathbb{Q}}{
|
||||
A = V + V^T.
|
||||
\end{align*}
|
||||
????????????????????????????
|
||||
\\
|
||||
We have a primary decomposition of $H_1(Y, \mathbb{Z}) = U$ (as a group). For any $p \in \mathbb{P}$ we define $U_p$ to be the subgroup of elements annihilated by the same power of $p$. We have $U = \bigoplus_p U_p$.
|
||||
\begin{example}
|
||||
\begin{align*}
|
||||
\text{If } U &=
|
||||
\mathbb{Z}_3 \oplus
|
||||
\mathbb{Z}_{45} \oplus
|
||||
\mathbb{Z}_{15} \oplus
|
||||
\mathbb{Z}_{75}
|
||||
\text{ then }\\
|
||||
U_3 &=
|
||||
\mathbb{Z}_3 \oplus
|
||||
\mathbb{Z}_9 \oplus
|
||||
\mathbb{Z}_3 \oplus
|
||||
\mathbb{Z}_3
|
||||
\text{ and }\\
|
||||
U_5 &=
|
||||
(e) \oplus
|
||||
\mathbb{Z}_5 \oplus
|
||||
\mathbb{Z}_5 \oplus
|
||||
\mathbb{Z}_{25}.
|
||||
\end{align*}
|
||||
\end{example}
|
||||
|
||||
\begin{lemma}
|
||||
Suppose $x \in U_{p_1}$, $y \in U_{p_2}$ and $p_1 \neq p_2$. Then $<x, y > = 0$.
|
||||
\end{lemma}
|
||||
\begin{proof}
|
||||
\begin{align*}
|
||||
x \in U_{p_1}
|
||||
\end{align*}
|
||||
\end{proof}
|
||||
\begin{align*}
|
||||
H_1(Y, \mathbb{Z}) \cong \quot{\mathbb{Z}^n}{A\mathbb{Z}}\\
|
||||
A \longrightarrow BAC^T \quad \text{Smith normal form}
|
||||
@ -511,7 +545,7 @@ $H_1(\bar{X}$
|
||||
|
||||
field of fractions
|
||||
|
||||
\section{\hfill\DTMdate{2019-06-03}}
|
||||
\section{Surgery \hfill\DTMdate{2019-06-03}}
|
||||
\begin{theorem}
|
||||
Let $K$ be a knot and $u(K)$ its unknotting number. Let $g_4$ be a minimal four genus of a smooth surface $S$ in $B^4$ such that $\partial S = K$. Then:
|
||||
\[
|
||||
@ -521,9 +555,9 @@ u(K) \geq g_4(K)
|
||||
Recall that if $u(K)=u$ then $K$ bounds a disk $\Delta$ with $u$ ordinary double points.
|
||||
\\
|
||||
\noindent
|
||||
Remove from $\Delta$ the two self intersecting and glue the Seifert surface for the Hopf link. The reality surface $S$ has Euler characteristic $\chi(S) = 1 - 2u$. Therefore $g_4(S) = u$ .
|
||||
Remove from $\Delta$ the two self intersecting disks and glue the Seifert surface for the Hopf link. The reality surface $S$ has Euler characteristic $\chi(S) = 1 - 2u$. Therefore $g_4(S) = u$.
|
||||
\end{proof}
|
||||
???????????????????\\
|
||||
%Tim D. Cochran and Peter Teichner
|
||||
\begin{example}
|
||||
The knot $8_{20}$ is slice: $\sigma \equiv 0$ almost everywhere but $\sigma(e^{\frac{ 2\pi i}{6}}) = + 1$.
|
||||
\end{example}
|
||||
@ -532,8 +566,8 @@ The knot $8_{20}$ is slice: $\sigma \equiv 0$ almost everywhere but $\sigma(e^{\
|
||||
%Journal-ref: Comment. Math. Helv. 79 (2004) 105-123
|
||||
\subsection*{Surgery}
|
||||
%Rolfsen, geometric group theory, Diffeomorpphism of a torus, Mapping class group
|
||||
Recall that $H_1(S^1 \times S^1, \mathbb{Z}) = \mathbb{Z}^3$. As generators for $H_1$ we can set ${\alpha = [S^1 \times \pt]}$ and ${\beta=[\pt \times S^1]}$. Suppose ${\phi: S^1 \times S^1 \longrightarrow S^1 \times S^1}$ is a diffeomorphism.
|
||||
Consider an induced map on homology group:
|
||||
Recall that $H_1(S^1 \times S^1, \mathbb{Z}) = \mathbb{Z}^2$. As generators for $H_1$ we can set ${\alpha = [S^1 \times \pt]}$ and ${\beta=[\pt \times S^1]}$. Suppose ${\phi: S^1 \times S^1 \longrightarrow S^1 \times S^1}$ is a diffeomorphism.
|
||||
Consider an induced map on the homology group:
|
||||
\begin{align*}
|
||||
H_1(S^1 \times S^1, \mathbb{Z}) \ni \phi_* (\alpha) &= p\alpha + q \beta, \quad p, q \in \mathbb{Z},\\
|
||||
\phi_*(\beta) &= r \alpha + s \beta, \quad r, s \in \mathbb{Z}, \\
|
||||
@ -541,11 +575,10 @@ H_1(S^1 \times S^1, \mathbb{Z}) \ni \phi_* (\alpha) &= p\alpha + q \beta, \quad
|
||||
\begin{pmatrix}
|
||||
p & q\\
|
||||
r & s
|
||||
\end{pmatrix}
|
||||
\end{pmatrix}.
|
||||
\end{align*}
|
||||
As $\phi_*$ is diffeomorphis, it must be invertible over $\mathbb{Z}$. Then for a direction preserving diffeomorphism we have $\det \phi_* = 1$. Therefore $\phi_* \in \Sl(2, \mathbb{Z})$.
|
||||
\end{theorem}
|
||||
|
||||
\vspace{10cm}
|
||||
\begin{theorem}
|
||||
Every such a matrix can be realized as a torus.
|
||||
@ -564,6 +597,15 @@ S^1 \times \pt &\longrightarrow \pt \times S^1 \\
|
||||
\item
|
||||
\end{enumerate}
|
||||
\end{proof}
|
||||
\begin{figure}[h]
|
||||
\fontsize{20}{10}\selectfont
|
||||
\centering{
|
||||
\def\svgwidth{\linewidth}
|
||||
\resizebox{0.5\textwidth}{!}{\input{images/dehn_twist.pdf_tex}}
|
||||
\caption{Dehn twist.}
|
||||
\label{fig:dehn_twist}
|
||||
}
|
||||
\end{figure}
|
||||
|
||||
|
||||
|
||||
|
Loading…
Reference in New Issue
Block a user