second lecture allmost done

2019-06-15 13:13:24 +02:00 · 2019-06-15 13:13:24 +02:00 · d2fdbc4b4c
commit d2fdbc4b4c
parent bcf43402a6
12 changed files with 1769 additions and 366 deletions
--- a/images/milnor_singular.pdf
+++ b/images/milnor_singular.pdf
--- a/images/milnor_singular.pdf_tex
+++ b/images/milnor_singular.pdf_tex
@ -0,0 +1,60 @@
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--- a/images/torus_lambda.pdf
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@ -0,0 +1,59 @@
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 %% in the preamble, and then including the image with
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--- a/images/torus_lambda.svg
+++ b/images/torus_lambda.svg
--- a/lec_1.tex
+++ b/lec_1.tex
@ -70,7 +70,7 @@ Borromean link:
 A link diagram $D_{\pi}$ is a picture over projection $\pi$ of a link $L$ in $\mathbb{R}^3$($S^3$) to $\mathbb{R}^2$ ($S^2$) such that:
 \begin{enumerate}[label={(\arabic*)}]
 \item 
-${D_{\pi}}_{\big|L}$ is non degenerate: \includegraphics[width=0.05\textwidth]{LinkDiagram1.png},
+$D_{\pi |_L}$ is non degenerate: \includegraphics[width=0.05\textwidth]{LinkDiagram1.png},
 \item the double points are not degenerate: \includegraphics[width=0.03\textwidth]{LinkDiagram2.png},
 \item there are no triple point:  \includegraphics[width=0.05\textwidth]{LinkDiagram3.png}.
 \end{enumerate}
@ -139,6 +139,7 @@ Note: the obtained surface isn't unique and in general doesn't need to be connec
 \end{figure}
 \begin{theorem}[Seifert]
 \label{theo:Seifert}
 Every link in $S^3$ bounds a surface $\Sigma$ that is compact, connected and orientable. Such a surface is called a Seifert surface.
 \end{theorem}
 %
@ -168,13 +169,13 @@ Remark: there are knots that admit non isotopic Seifert surfaces of minimal genu
 Suppose $\alpha$ and $\beta$ are two simple closed curves in $\mathbb{R}^3$. 
 On a diagram $L$ consider all crossings between $\alpha$ and $\beta$. Let $N_+$ be the number of positive crossings, $N_-$ - negative. Then the linking number: $\Lk(\alpha, \beta) = \frac{1}{2}(N_+ - N_-)$.
 \end{definition}
-\hfill
+\begin{definition}
-\\
+\label{def:lk_via_homo}
 Let $\alpha$ and $\beta$ be two disjoint simple cross curves in $S^3$. 
 Let $\nu(\beta)$ be a tubular neighbourhood of $\beta$.  The linking number can be interpreted via first homology group, where $\Lk(\alpha, \beta)$ is equal to evaluation of $\alpha$  as element of first homology group of the complement of $\beta$: 
 \[
 \alpha \in H_1(S^3 \setminus \nu(\beta), \mathbb{Z}) \cong \mathbb{Z}.\]
-
+\end{definition}
 \begin{example}
 \begin{itemize}
--- a/lec_2.tex
+++ b/lec_2.tex
@ -0,0 +1,269 @@
 \subsection{Existence of Seifert surface - second proof}
 %\begin{theorem}
 %For any knot $K \subset S^3$ there exists a connected, compact and orientable surface $\Sigma(K)$ such that $\partial \Sigma(K) = K$
 %\end{theorem}
 \begin{proof}(Theorem \ref{theo:Seifert})\\
 Let $K \in S^3$ be a knot and $N = \nu(K)$ be its tubular neighbourhood. Because $K$ and $N$ are homotopy equivalent, we get:
 \begin{align*}
 H^1(S^3 \setminus N ) \cong H^1(S^3 \setminus K).
 \end{align*}
 Let us consider a long exact sequence of cohomology of a pair $(S^3, S^3 \setminus N)$  with integer coefficients:
 \begin{center}
 \begin{tikzcd}
 [
    column sep=0cm, fill=none, 
    row sep=small,
    ar symbol/.style =%
        {draw=none,"\textstyle#1" description,sloped},
         isomorphic/.style = {ar symbol={\cong}},
 ]
 &\mathbb{Z}
 \\
 & H^0(S^3) \ar[u,isomorphic]  \to 
 &H^0(S^3 \setminus N) \to 
 \\
 \to H^1(S^3, S^3 \setminus N) \to
 & H^1(S^3) \to
 & H^1(S^3\setminus N)  \to
 \\
 & 0  \ar[u,isomorphic]&
 \\
 \to H^2(S^3, S^3 \setminus N) \to
 & H^2(S^3) \ar[u,isomorphic] \to
 & H^2(S^3\setminus N) \to
 \\
 \to H^3(S^3, S^3\setminus N)\to
 & H^3(S) \to
 & 0
 \\
 &  \mathbb{Z} \ar[u,isomorphic] &\\
 \end{tikzcd}
 \end{center}
 \begin{align*}
 N \cong & D^2 \times S^1\\
 \partial N \cong & S^1 \times S^1\\
 H^1(N, \partial N) \cong & \mathbb{Z} \oplus \mathbb{Z}
 \end{align*}
 \begin{align*}
 H^* (S^3, S^3 \setminus N) &\cong H^* (N, \partial N)\\
 \\
 H^	1 (S^3\setminus N) &\cong H^1(S^3\setminus K) \cong \mathbb{Z}
 \end{align*}
 \begin{equation*}
 \begin{tikzcd}[row sep=huge]
 H^1(S^3 \setminus K) \arrow[r,] \arrow[d,"\widetilde{\Theta}"] & 
 H^1(N \setminus K) \arrow[d,"\Theta"] \\ 
 {[S^3 \setminus K, S^1]} \arrow[r,]&  
 {[N \setminus K, S^1]}
 \end{tikzcd}
 \end{equation*}
 \noindent
 $\Sigma = \widetilde{\Theta}^{-1}(X)$ is a surface, such that $\partial \Sigma = K$, so it is a Seifert surface. 
 %
 % 
 % Thom isomorphism, 
 \end{proof}
 \subsection{Alexander polynomial}
 \begin{definition}
 Let $S$ be a Seifert matrix for a knot $K$. The Alexander polynomial $\Delta_K(t)$ is a Laurent polynomial:
 \[ 
 \Delta_K(t) := \det (tS - S^T)  \in 
 \mathbb{Z}[t, t^{-1}] \cong \mathbb{Z}[\mathbb{Z}]
 \]
 \end{definition}
 \begin{theorem}
 $\Delta_K(t)$ is well defined up to multiplication by $\pm t^k$, for $k \in \mathbb{Z}$.
 \end{theorem}
 \begin{proof}
 We need to show that $\Delta_K(t)$ doesn't depend on $S$-equivalence relation.
 \begin{enumerate}[label={(\arabic*)}]
 \item Suppose $S\prime = CSC^T$, $C \in \Gl(n, \mathbb{Z})$ (matrices invertible over $\mathbb{Z}$). Then $\det C = 1$ and:
 \begin{align*}
 &\det(tS\prime - S\prime^T) =
 \det(tCSC^T - (CSC^T)^T) =\\
 &\det(tCSC^T - CS^TC^T) = 
 \det C(tS - S^T)C^T = 
 \det(tS - S^T)
 \end{align*}
 \item
 Let \\
 $ A := t
 \begin{pmatrix}
    \begin{array}{c|c}
           S &  
           \begin{matrix}
                 \ast & 0  \\
                 \sdots & \sdots\\
                 \ast & 0
           \end{matrix} \\
    \hline
           \begin{matrix}
                \ast & \dots & \ast\\
                0      & \dots & 0
           \end{matrix}
           &
           \begin{matrix}
               0 & 0\\
               1 & 0
           \end{matrix}
    \end{array}
 \end{pmatrix}
 -
 \begin{pmatrix}
    \begin{array}{c|c}
           S^T &  
           \begin{matrix}
                 \ast & 0  \\
                 \sdots & \sdots\\
                 \ast & 0
           \end{matrix} \\
    \hline
           \begin{matrix}
                \ast & \dots & \ast\\
                0      & \dots & 0
           \end{matrix}
           &
           \begin{matrix}
               0 & 1\\
               0 & 0
           \end{matrix}
    \end{array}
 \end{pmatrix}
 =
 \begin{pmatrix}
    \begin{array}{c|c}
           tS - S^T &  
           \begin{matrix}
                 \ast & 0  \\
                 \sdots & \sdots\\
                 \ast & 0
           \end{matrix} \\
    \hline
           \begin{matrix}
                \ast & \dots & \ast\\
                0      & \dots & 0
           \end{matrix}
           &
           \begin{matrix}
               0 & -1\\
               t & 0
           \end{matrix}
    \end{array}
 \end{pmatrix}
 $
 \\
 \\
 Using the Laplace expansion we get $\det A = \pm t \det(tS - S^T)$. 
 \end{enumerate} 
 \end{proof}
 %
 %
 %
 \begin{example}
 If $K$ is a trefoil then we can take
 $S = \begin{pmatrix}
 -1 & -1 \\
 0 & -1
 \end{pmatrix}$. Then
 \[
 \Delta_K(t) = \det 
 \begin{pmatrix}
 -t + 1 & -t\\
 1 & -t +1
 \end{pmatrix}
 = (t -1)^2 + t = t^2 - t +1 \ne 1
 \Rightarrow \text{trefoil is not trivial.}
 \]
 \end{example}
 \begin{fact}
 $\Delta_K(t)$ is symmetric.
 \end{fact}
 \begin{proof}
 Let $S$ be an $n \times n$ matrix. 
 \begin{align*}
 &\Delta_K(t^{-1}) = \det (t^{-1}S - S^T) = (-t)^{-n} \det(tS^T - S) = \\
 &(-t)^{-n} \det (tS - S^T) = (-t)^{-n} \Delta_K(t)
 \end{align*}
 If $K$ is a knot, then $n$ is necessarily even, and so $\Delta_K(t^{-1}) = t^{-n} \Delta_K(t)$.
 \end{proof}
 \begin{lemma}
 \begin{align*}
 \frac{1}{2} \deg \Delta_K(t) \leq g_3(K),
 \text{ where } deg (a_n t^n + \dots + a_1 t^l )= k - l.
 \end{align*}
 \end{lemma}
 \begin{proof}
 If $\Sigma$ is a genus $g$ - Seifert surface for $K$ then $H_1(\Sigma) = \mathbb{Z}^{2g}$, so $S$ is an $2g \times 2g$ matrix. Therefore $\det (tS - S^T)$ is a polynomial of degree at most $2g$.
 \end{proof}
 \begin{example}
 There are not trivial knots with Alexander polynomial equal $1$, for example: 
 \includegraphics[width=0.3\textwidth]{11n34.png}
 $\Delta_{11n34} \equiv 1$.
 \end{example}
 \subsection{Decomposition of $3$-sphere}
 We know that $3$ - sphere can be obtained by gluing two solid tori:
 $S^3 = \partial D^4 = \partial (D^2 \times D^2) =  (D^2 \times S^1) \cup (S^1 \times D^2)$. So the complement of solid torus in $S^3$ is another solid torus.\\
 Analytically it can be describes as follow. 
 Take $(z_1, z_2) \in \mathbb{C}$ such  that $max(\mid z_1 \mid, \mid z_2\mid) = 1
 $. Define following sets: $S_1 = \{ (z_1, z_2) \in S^3: \mid z_1 \mid = 0\} \cong S^1 \times D^2 $ and $S_2 = \{(z_1, z_2) \in S ^3: \mid z_2 \mid = 1 \} \cong  D^2 \times S^1$. The intersection $S_1 \cap S_2 = \{(z_1, z_2): \mid z_1 \mid = \mid z_2 \mid = 1 \} \cong S^1 \times S^1$
 \begin{figure}[h]
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.3\textwidth}{!}{\includegraphics[width=0.3\textwidth]{sphere_as_torus.png}}
 \caption{The complement of solid torus in $S^3$ is another solid torus.}
 \label{fig:sphere_as_tori}
 }
 \end{figure}
 \subsection{Dehn lemma and sphere theorem}
 %removing one disk from surface doesn't change $H_1$ (only $H_2$)
 %
 %
 %
 \begin{lemma}[Dehn]
 Let $M$ be a $3$-manifold and $D^2 \overset{f} \rightarrow M^3$ be a map of a disk such that $f\big|_{\partial D^2}$ is an embedding. Then there exists an embedding 
 ${D^2 \overset{g}\longhookrightarrow M}$ such that: 
 \[
 g\big|_{\partial D^2} = f\big|_{\partial D^2.}
 \]
 \end{lemma}
 \noindent
 Remark: Dehn lemma doesn't hold for dimension four.\\
 Let $M$ be connected, compact three manifold with boundary. 
 Suppose $\pi_1(\partial M) \longrightarrow \pi_1(M)$ has non-trivial kernel. Then there exists a map $f: (D^2, \partial D^2) \longrightarrow (M, \partial M)$ such that $f\big|_{\partial D^2}$ is non-trivial loop in $\partial M$.
 \begin{theorem}[Sphere theorem]
 Suppose $\pi_1(M) \ne 0$. Then there exists an embedding $f: S^2 \hookrightarrow M$ that is homotopy non-trivial. 
 \end{theorem}
 \begin{problem}
 Prove that $S^3 \ K$ is Eilenberg–MacLane space of type $K(\pi, 1)$. 
 \end{problem}
 \begin{corollary}
 Suppose $K \subset S^3$ and $\pi_1(S^3 \setminus K)$ is infinite cyclic ($\mathbb{Z})$. Then $K$ is trivial. 
 \end{corollary}
 \begin{proof}
 Let $N$ be a tubular neighbourhood of a knot $K$ and $M = S^3 \setminus N$ its complement. Then $\partial M = S^1 \times S^1$. Let $f : \pi_1(\partial M ) \longrightarrow \pi_1(M)$. 
 If $\pi_1(M)$ is infinite cyclic group then the map $f$ is non-trivial. Suppose ${\lambda \in \ker (\pi_1(S^1 \times S^1) \longrightarrow \pi_1(M)}$.  There is a map $g: (D^2, \partial D^2) \longrightarrow (M, \partial M)$ such that $g(\partial D^2) = \lambda$. By Dehn's lemma there exists an embedding ${h: (D^2, \partial D^2) \longhookrightarrow (M, \partial M)}$ such that 
 $h\big|_{\partial D^2} = f \big|_{\partial D^2}$ and  $h(\partial D^2) = \lambda$.
 Let $\Sigma$ be a union of the annulus and the image of $\partial D^2$. 
 \\???? $g_3$?\\
 If $g(\Sigma) = 0$, then $K$ is trivial. \\
 Now we should proof that: 
 \[
 H_1(M) \cong \mathbb{Z} \Longrightarrow \lambda \in \ker ( \pi_1(S^1 \times S^1) \longrightarrow \pi_1(M)).
 \]
 \begin{figure}[h]
 \fontsize{40}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.4\textwidth}{!}{\input{images/torus_lambda.pdf_tex}}
 }
 \caption{$\mu$ is a meridian and $\lambda$ is a longitude.}
 \label{fig:meridian_and_longitude}
 \end{figure}
 Choose a meridian $\mu$ such that $\Lk (\mu, K) = 1$.  Recall the definition of linking number via homology group (Definition \ref{def:lk_via_homo}).
 $[\mu]$ represents the generator of $H_1(S^3\setminus K, \mathbb{X})$. From definition of $\lambda$ we know that $\lambda$ is trivial in $H_1(M)$ ($\Lk(\lambda, K) =0$, therefore $[\lambda]$ was trivial in $pi_1(M)$). If $K$ is non-trivial then $\lambda$ is non-trivial in $\pi_1(M)$, but it is trivial in $H_1(M)$. 
 \end{proof}
--- a/lec_3.tex
+++ b/lec_3.tex
--- a/lec_4.tex
+++ b/lec_4.tex
@ -0,0 +1,116 @@
 \begin{definition}
 Two knots $K$ and $K^{\prime}$ are called (smoothly) concordant if there exists an annulus $A$ that is smoothly embedded in ${S^3 \times [0, 1]}$ such that 
 \[
 \partial A = K^{\prime} \times \{1\} \; \sqcup \; K \times \{0\}.
 \]
 \end{definition}
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.8\textwidth}{!}{\input{images/concordance.pdf_tex}}
 }
 \end{figure}
 \begin{definition}
 A knot $K$ is called (smoothly) slice if $K$ is smoothly concordant to an unknot. \\
 Put differently: a knot $K$ is smoothly slice if and only if $K$ bounds a smoothly embedded disk in $B^4$.
 \end{definition}
 \noindent
 Let $m(K)$ denote a mirror image of a knot $K$. 
 \begin{fact}
 For any $K$, $K \# m(K)$ is slice.
 \end{fact}
 \begin{fact}
 Concordance is an equivalence relation.
 \end{fact}
 \begin{fact}\label{fact:concordance_connected}
 If $K_1 \sim {K_1}^{\prime}$ and $K_2 \sim {K_2}^{\prime}$, then
 $K_1 \# K_2 \sim {K_1}^{\prime} \# {K_2}^{\prime}$.
 \begin{figure}[h]
 \fontsize{10}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{1\textwidth}{!}{\input{images/concordance_sum.pdf_tex}}
 }
 \caption{Sketch for Fact \ref{fact:concordance_connected}.}
 \label{fig:concordance_sum}
 \end{figure}
 \end{fact}
 \begin{fact}
 $K \# m(K) \sim $ the unknot.
 \end{fact}
 \noindent
 \begin{theorem}
 Let $\mathscr{C}$ denote a set of all equivalent classes for knots and $\{0\}$ denote class of all knots concordant to a trivial knot. 
 $\mathscr{C}$ is a group under taking connected sums. The neutral element in the group is $\{0\}$ and the inverse element of an element $\{K\} \in \mathscr{C}$ is $-\{K\} = \{mK\}$.
 \end{theorem}
 \begin{fact}
 The figure eight knot is a torsion element in $\mathscr{C}$ ($2K \sim $ the unknot).
 \end{fact}
 \begin{problem}[open]
 Are there in concordance group torsion elements that are not $2$ torsion elements?
 \end{problem}
 \noindent
 Remark: $K \sim K^{\prime} \Leftrightarrow K \# -K^{\prime}$ is slice.
 \\
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.5\textwidth}{!}{\input{images/ball_4_pushed_seifert.pdf_tex}}
 }
 \caption{$Y = F \cup \Sigma$ is a smooth close surface.}
 \label{fig:closed_surface}
 \end{figure}
 \noindent
 \\
 Pontryagin-Thom construction tells us that there exists a compact three - manifold $\Omega \subset B^4$ such that $\partial \Omega = Y$.
 Suppose $\Sigma$ is a Seifert surface and $V$ a Seifert form defined on $\Sigma$: ${(\alpha, \beta) \mapsto \Lk(\alpha, \beta^+)}$. Suppose $\alpha, \beta \in H_1(\Sigma, \mathbb{Z})$, i.e. there are cycles and
 $\alpha, \beta \in \ker (H_1(\Sigma, \mathbb{Z}) \longrightarrow H_1(\Omega, \mathbb{Z}))$. Then there are two cycles $A, B \in \Omega$ such that $\partial A = \alpha$ and $\partial B = \beta$. 
 Let $B^+$ be a push off of $B$ in the positive normal direction such that 
 $\partial B^+ = \beta^+$.
 Then 
 $\Lk(\alpha, \beta^+) = A \cdot B^+$. But $A$ and $B$ are disjoint, so $\Lk(\alpha, \beta^+) = 0$. Then the Seifert form is zero. 
 \\
 ????????????????? 
 \\
 Let us consider following maps:
 \[
 \Sigma \overset{\phi} \longhookrightarrow Y \overset{\psi} \longhookrightarrow \Omega.
 \]
 Let $\phi_*$ and $\psi_*$ be induced maps on the homology group. If an element $\gamma \in \ker (H_1(\Sigma, \mathbb{Z}) \longrightarrow H_1(\Omega, \mathbb{Z}))$, then $\gamma \in \ker \phi_*$ or $\gamma \in \ker \psi_*$.
 %
 \\
 ????????????\\
 %
 %
 \begin{proposition}
 \[
 \dim \ker (H_1(Y, \mathbb{Z}) \longrightarrow H_1(\Omega, \mathbb{Z})) = \frac{1}{2} b_1(Y),
 \]
 where $b_1$ is first Betti number.
 \end{proposition}
 \begin{proof}
 \begin{align*}
 & 0 \to  H_3(\Omega) \to H_3(\Omega, Y) \to 
 \\ 
 \to & H_2(Y) \to H_2(\Omega) \to H_2(\Omega, Y) \to \\
 \to & H_1(Y) \to \H_1(\Omega) \to H_1(\Omega, Y) \to \\
 \to & H_0(Y) \to H_0(\Omega) \to 0
 \end{align*}
 \end{proof}
 \begin{figure}[h]
 \fontsize{10}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.5\textwidth}{!}{\input{images/ball_4_alpha_beta.pdf_tex}}
 }
 %\caption{Sketch for Fact %%\label{fig:concordance_m}
 \end{figure}
--- a/lectures_on_knot_theory.pdf
+++ b/lectures_on_knot_theory.pdf
--- a/lectures_on_knot_theory.tex
+++ b/lectures_on_knot_theory.tex
@ -90,8 +90,11 @@
 \DeclareMathOperator{\Lk}{lk}
 \DeclareMathOperator{\pt}{\{pt\}}
-
+\titleformat{\subsection}{%
-\titleformat{\section}{\normalfont \fontsize{12}{15} \bfseries}{%
+     \normalfont \fontsize{12}{15}\bfseries}{%
     }{.0ex plus .2ex}{} 
 \titleformat{\section}{%
     \normalfont \fontsize{13}{15} \bfseries}{%
     Lecture\ \thesection}%
     {2.3ex plus .2ex}{} 
 \titlespacing*{\section}
@ -114,249 +117,12 @@
 \section{Basic definitions \hfill\DTMdate{2019-02-25}}
 \input{lec_1.tex}
-\section{\hfill\DTMdate{2019-03-04}}
+\section{Alexander polynomial \hfill\DTMdate{2019-03-04}}
-\begin{theorem}
+\input{lec_2.tex}
-For any knot $K \subset S^3$ there exists a connected, compact and orientable surface $\Sigma(K)$ such that $\partial \Sigma(K) = K$
+%add Hurewicz theorem?
 \end{theorem}
 \begin{proof}("joke")\\
 Let $K \in S^3$ be a knot and $N = \nu(K)$ be its tubular neighbourhood. Because $K$ and $N$ are homotopy equivalent, we get:
 \begin{align*}
 H^1(S^3 \setminus N ) \cong H^1(S^3 \setminus K).
 \end{align*}
 Let us consider a long exact sequence of cohomology of a pair $(S^3, S^3 \setminus N)$  with integer coefficients:
 \begin{center}
 \begin{tikzcd}
 [
    column sep=0cm, fill=none, 
    row sep=small,
    ar symbol/.style =%
        {draw=none,"\textstyle#1" description,sloped},
         isomorphic/.style = {ar symbol={\cong}},
 ]
 &\mathbb{Z}
 \\
 & H^0(S^3) \ar[u,isomorphic]  \to 
 &H^0(S^3 \setminus N) \to 
 \\
 \to H^1(S^3, S^3 \setminus N) \to
 & H^1(S^3) \to
 & H^1(S^3\setminus N)  \to
 \\
 & 0  \ar[u,isomorphic]&
 \\
 \to H^2(S^3, S^3 \setminus N) \to
 & H^2(S^3) \ar[u,isomorphic] \to
 & H^2(S^3\setminus N) \to
 \\
 \to H^3(S^3, S^3\setminus N)\to
 & H^3(S) \to
 & 0
 \\
 &  \mathbb{Z} \ar[u,isomorphic] &\\
 \end{tikzcd}
 \end{center}
 \begin{align*}
 N \cong & D^2 \times S^1\\
 \partial N \cong & S^1 \times S^1\\
 H^1(N, \partial N) \cong & \mathbb{Z} \oplus \mathbb{Z}
 \end{align*}
 \begin{align*}
 H^* (S^3, S^3 \setminus N) &\cong H^* (N, \partial N)\\
 \\
 H^	1 (S^3\setminus N) &\cong H^1(S^3\setminus K) \cong \mathbb{Z}
 \end{align*}
 \begin{equation*}
 \begin{tikzcd}[row sep=huge]
 H^1(S^3 \setminus K) \arrow[r,] \arrow[d,"\widetilde{\Theta}"] & 
 H^1(N \setminus K) \arrow[d,"\Theta"] \\ 
 {[S^3 \setminus K, S^1]} \arrow[r,]&  
 {[N \setminus K, S^1]}
 \end{tikzcd}
 \end{equation*}
 \noindent
 $\Sigma = \widetilde{\Theta}^{-1}(X)$ is a surface, such that $\partial \Sigma = K$, so it is a Seifert surface. 
 %
 % 
 % Thom isomorphism, 
 \end{proof}
 \begin{definition}
 Let $S$ be a Seifert matrix for a knot $K$. The Alexander polynomial $\Delta_K(t)$ is a Laurent polynomial:
 \[ 
 \Delta_K(t) := \det (tS - S^T)  \in 
 \mathbb{Z}[t, t^{-1}] \cong \mathbb{Z}[\mathbb{Z}]
 \]
 \end{definition}
 \begin{theorem}
 $\Delta_K(t)$ is well defined up to multiplication by $\pm t^k$, for $k \in \mathbb{Z}$.
 \end{theorem}
 \begin{proof}
 We need to show that $\Delta_K(t)$ doesn't depend on $S$-equivalence relation.
 \begin{enumerate}[label={(\arabic*)}]
 \item Suppose $S\prime = CSC^T$, $C \in \Gl(n, \mathbb{Z})$ (matrices invertible over $\mathbb{Z}$). Then $\det C = 1$ and:
 \begin{align*}
 &\det(tS\prime - S\prime^T) =
 \det(tCSC^T - (CSC^T)^T) =\\
 &\det(tCSC^T - CS^TC^T) = 
 \det C(tS - S^T)C^T = 
 \det(tS - S^T)
 \end{align*}
 \item
 Let \\
 $ A := t
 \begin{pmatrix}
    \begin{array}{c|c}
           S &  
           \begin{matrix}
                 \ast & 0  \\
                 \sdots & \sdots\\
                 \ast & 0
           \end{matrix} \\
    \hline
           \begin{matrix}
                \ast & \dots & \ast\\
                0      & \dots & 0
           \end{matrix}
           &
           \begin{matrix}
               0 & 0\\
               1 & 0
           \end{matrix}
    \end{array}
 \end{pmatrix}
 -
 \begin{pmatrix}
    \begin{array}{c|c}
           S^T &  
           \begin{matrix}
                 \ast & 0  \\
                 \sdots & \sdots\\
                 \ast & 0
           \end{matrix} \\
    \hline
           \begin{matrix}
                \ast & \dots & \ast\\
                0      & \dots & 0
           \end{matrix}
           &
           \begin{matrix}
               0 & 1\\
               0 & 0
           \end{matrix}
    \end{array}
 \end{pmatrix}
 =
 \begin{pmatrix}
    \begin{array}{c|c}
           tS - S^T &  
           \begin{matrix}
                 \ast & 0  \\
                 \sdots & \sdots\\
                 \ast & 0
           \end{matrix} \\
    \hline
           \begin{matrix}
                \ast & \dots & \ast\\
                0      & \dots & 0
           \end{matrix}
           &
           \begin{matrix}
               0 & -1\\
               t & 0
           \end{matrix}
    \end{array}
 \end{pmatrix}
 $
 \\
 \\
 Using the Laplace expansion we get $\det A = \pm t \det(tS - S^T)$. 
 \end{enumerate} 
 \end{proof}
 %
 %
 %
 \begin{example}
 If $K$ is a trefoil then we can take
 $S = \begin{pmatrix}
 -1 & -1 \\
 0 & -1
 \end{pmatrix}$. Then
 \[
 \Delta_K(t) = \det 
 \begin{pmatrix}
 -t + 1 & -t\\
 1 & -t +1
 \end{pmatrix}
 = (t -1)^2 + t = t^2 - t +1 \ne 1
 \Rightarrow \text{trefoil is not trivial.}
 \]
 \end{example}
 \begin{fact}
 $\Delta_K(t)$ is symmetric.
 \end{fact}
 \begin{proof}
 Let $S$ be an $n \times n$ matrix. 
 \begin{align*}
 &\Delta_K(t^{-1}) = \det (t^{-1}S - S^T) = (-t)^{-n} \det(tS^T - S) = \\
 &(-t)^{-n} \det (tS - S^T) = (-t)^{-n} \Delta_K(t)
 \end{align*}
 If $K$ is a knot, then $n$ is necessarily even, and so $\Delta_K(t^{-1}) = t^{-n} \Delta_K(t)$.
 \end{proof}
 \begin{lemma}
 \begin{align*}
 \frac{1}{2} \deg \Delta_K(t) \leq g_3(K),
 \text{ where } deg (a_n t^n + \dots + a_1 t^l )= k - l.
 \end{align*}
 \end{lemma}
 \begin{proof}
 If $\Sigma$ is a genus $g$ - Seifert surface for $K$ then $H_1(\Sigma) = \mathbb{Z}^{2g}$, so $S$ is an $2g \times 2g$ matrix. Therefore $\det (tS - S^T)$ is a polynomial of degree at most $2g$.
 \end{proof}
 \begin{example}
 There are not trivial knots with Alexander polynomial equal $1$, for example: 
 \includegraphics[width=0.3\textwidth]{11n34.png}
 $\Delta_{11n34} \equiv 1$.
 \end{example}
 %removing one disk from surface doesn't change $H_1$ (only $H_2$)
 %
 %
 %
 \begin{lemma}[Dehn]
 Let $M$ be a $3$-manifold and $D^2 \overset{f} \rightarrow M^3$ be a map of a disk such that $f_{\big|\partial D^2}$ is an embedding. Then there exists an embedding 
 ${D^2 \overset{g}\longhookrightarrow M}$ such that: 
 \[
 g_{\big| \partial D^2} = f_{\big| \partial D^2.}
 \]
 \end{lemma}
 \noindent
 Remark: Dehn lemma doesn't hold for dimension four.\\
 Let $M$ be connected, compact three manifold with boundary. 
 Suppose $\pi_1(\partial M) \longrightarrow \pi_1(M)$ has non-trivial kernel. Then there exists a map $f: (D^2, \partial D^2) \longrightarrow (M, \partial M)$ such that $f\big| \partial D^2$ is non-trivial loop in $\partial M$
 \begin{theorem}[Sphere theorem]
 Suppose $\pi_1(M) \ne 0$. Then there exists an embedding $f: S^2 \hookrightarrow M$ that is homotopy non-trivial. 
 \end{theorem}
 \begin{problem}
 Prove that $S^3 \ K$ is Eilenberg–MacLane space of type $K(\pi, 1)$. 
 \end{problem}
 \begin{corollary}
 Suppose $K \subset S^3$ and $\pi_1(S^3 \setminus K)$ is infinite cyclic ($\mathbb{Z})$. Then $K$ is trivial. 
 \end{corollary}
 \subsection*{Construction}
 We know that $3$ - sphere can be obtained by gluing two solid tori:
 $S^3 = (D^2 \times S^1) \cup (S^1 \times D^2)$. So the complement of solid torus in $S^3$ is another solid torus.\\
 Take $(z_1, z_2) \in \mathbb{C}$ such  that $max(\mid z_1 \mid, \mid z_2, \mid) = 1
 $
 \begin{figure}[h]
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.3\textwidth}{!}{\includegraphics[width=0.3\textwidth]{sphere_as_torus.png}}
 \caption{The complement of solid torus in $S^3$ is another solid torus.}
 \label{fig:sphere_as_tori}
 }
 \end{figure}
 \section{\hfill\DTMdate{2019-03-11}}
 \input{lec_3.tex}
 \begin{example}
 \begin{align*}
@ -364,6 +130,15 @@ $
 &F(0) = 0
 \end{align*}
 \end{example}
 \begin{figure}[h]
 \fontsize{40}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.2\textwidth}{!}{\input{images/milnor_singular.pdf_tex}}
 }
 %\caption{$\mu$ is a meridian and $\lambda$ is a longitude.}
 \label{fig:milnor_singular}
 \end{figure}
 ????????????
 \\
 \noindent
@ -392,125 +167,16 @@ Figure 8 knot is negative amphichiral.
 %
 %
 %
 \begin{definition}
 A link $L$ is fibered if there exists a map ${\phi: S^3\setminus L \longleftarrow S^1}$ which is locally trivial fibration. 
 \end{definition}
 \section{Concordance group \hfill\DTMdate{2019-03-18}}
-\begin{definition}
+\input{lec_4.tex}
 Two knots $K$ and $K^{\prime}$ are called (smoothly) concordant if there exists an annulus $A$ that is smoothly embedded in ${S^3 \times [0, 1]}$ such that 
 \[
 \partial A = K^{\prime} \times \{1\} \; \sqcup \; K \times \{0\}.
 \]
 \end{definition}
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.8\textwidth}{!}{\input{images/concordance.pdf_tex}}
 }
 \end{figure}
 \begin{definition}
 A knot $K$ is called (smoothly) slice if $K$ is smoothly concordant to an unknot. \\
 Put differently: a knot $K$ is smoothly slice if and only if $K$ bounds a smoothly embedded disk in $B^4$.
 \end{definition}
 \noindent
 Let $m(K)$ denote a mirror image of a knot $K$. 
 \begin{fact}
 For any $K$, $K \# m(K)$ is slice.
 \end{fact}
 \begin{fact}
 Concordance is an equivalence relation.
 \end{fact}
 \begin{fact}\label{fakt:concordance_connected}
 If $K_1 \sim {K_1}^{\prime}$ and $K_2 \sim {K_2}^{\prime}$, then
 $K_1 \# K_2 \sim {K_1}^{\prime} \# {K_2}^{\prime}$.
 \begin{figure}[h]
 \fontsize{10}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{1\textwidth}{!}{\input{images/concordance_sum.pdf_tex}}
 }
 \caption{Sketch for Fakt \ref{fakt:concordance_connected}.}
 \label{fig:concordance_sum}
 \end{figure}
 \end{fact}
 \begin{fact}
 $K \# m(K) \sim $ the unknot.
 \end{fact}
 \noindent
 \begin{theorem}
 Let $\mathscr{C}$ denote a set of all equivalent classes for knots and $\{0\}$ denote class of all knots concordant to a trivial knot. 
 $\mathscr{C}$ is a group under taking connected sums. The neutral element in the group is $\{0\}$ and the inverse element of an element $\{K\} \in \mathscr{C}$ is $-\{K\} = \{mK\}$.
 \end{theorem}
 \begin{fact}
 The figure eight knot is a torsion element in $\mathscr{C}$ ($2K \sim $ the unknot).
 \end{fact}
 \begin{problem}[open]
 Are there in concordance group torsion elements that are not $2$ torsion elements?
 \end{problem}
 \noindent
 Remark: $K \sim K^{\prime} \Leftrightarrow K \# -K^{\prime}$ is slice.
 \\
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.5\textwidth}{!}{\input{images/ball_4_pushed_seifert.pdf_tex}}
 }
 \caption{$Y = F \cup \Sigma$ is a smooth close surface.}
 \label{fig:closed_surface}
 \end{figure}
 \noindent
 \\
 Pontryagin-Thom construction tells us that there exists a compact three - manifold $\Omega \subset B^4$ such that $\partial \Omega = Y$.
 Suppose $\Sigma$ is a Seifert surface and $V$ a Seifert form defined on $\Sigma$: ${(\alpha, \beta) \mapsto \Lk(\alpha, \beta^+)}$. Suppose $\alpha, \beta \in H_1(\Sigma, \mathbb{Z})$, i.e. there are cycles and
 $\alpha, \beta \in \ker (H_1(\Sigma, \mathbb{Z}) \longrightarrow H_1(\Omega, \mathbb{Z}))$. Then there are two cycles $A, B \in \Omega$ such that $\partial A = \alpha$ and $\partial B = \beta$. 
 Let $B^+$ be a push off of $B$ in the positive normal direction such that 
 $\partial B^+ = \beta^+$.
 Then 
 $\Lk(\alpha, \beta^+) = A \cdot B^+$. But $A$ and $B$ are disjoint, so $\Lk(\alpha, \beta^+) = 0$. Then the Seifert form is zero. 
 \\
 ????????????????? 
 \\
 Let us consider following maps:
 \[
 \Sigma \overset{\phi} \longhookrightarrow Y \overset{\psi} \longhookrightarrow \Omega.
 \]
 Let $\phi_*$ and $\psi_*$ be induced maps on the homology group. If an element $\gamma \in \ker (H_1(\Sigma, \mathbb{Z}) \longrightarrow H_1(\Omega, \mathbb{Z}))$, then $\gamma \in \ker \phi_*$ or $\gamma \in \ker \psi_*$.
 %
 \\
 ????????????\\
 %
 %
 \begin{proposition}
 \[
 \dim \ker (H_1(Y, \mathbb{Z}) \longrightarrow H_1(\Omega, \mathbb{Z})) = \frac{1}{2} b_1(Y),
 \]
 where $b_1$ is first Betti number.
 \end{proposition}
 \begin{proof}
 \begin{align*}
 & 0 \to  H_3(\Omega) \to H_3(\Omega, Y) \to 
 \\ 
 \to & H_2(Y) \to H_2(\Omega) \to H_2(\Omega, Y) \to \\
 \to & H_1(Y) \to \H_1(\Omega) \to H_1(\Omega, Y) \to \\
 \to & H_0(Y) \to H_0(\Omega) \to 0
 \end{align*}
 \end{proof}
 \begin{figure}[h]
 \fontsize{10}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.5\textwidth}{!}{\input{images/ball_4_alpha_beta.pdf_tex}}
 }
 %\caption{Sketch for Fakt %%\label{fig:concordance_m}
 \end{figure}
 \section{\hfill\DTMdate{2019-03-25}}
 \begin{definition}
 The (smooth) four genus $g_4(K)$ is the minimal genus of the surface $\Sigma \in B^4$ such that $\Sigma$ is compact, orientable and $\partial \Sigma = K$. 
@ -587,10 +253,6 @@ has a subspace of dimension $g_{\Sigma}$ on which it is zero:
 \section{\hfill\DTMdate{2019-03-11}}
 \begin{definition}
 A link $L$ is fibered if there exists a map ${\phi: S^3\setminus L \longleftarrow S^1}$ which is locally trivial fibration. 
 \end{definition}
 \section{\hfill\DTMdate{2019-04-15}}