small progress

2019-06-24 21:58:03 -05:00 · 2019-06-24 21:58:03 -05:00 · 2606bba015
commit 2606bba015
parent 00d5474731
21 changed files with 3565 additions and 188 deletions
--- a/images/genus_2_bordism.pdf
+++ b/images/genus_2_bordism.pdf
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--- a/images/genus_bordism_proof.pdf
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@ -51,7 +55,8 @@
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--- a/images/torus_alpha_beta.pdf_tex
+++ b/images/torus_alpha_beta.pdf_tex
@ -50,10 +50,10 @@
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--- a/lec_2.tex
+++ b/lec_2.tex
@ -277,5 +277,5 @@ H_1(M) \cong \mathbb{Z} \Longrightarrow \lambda \in \ker ( \pi_1(S^1 \times S^1)
 \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 $H_1(M)$. 
+$[\mu]$ represents the generator of $H_1(S^3\setminus K, \mathbb{Z})$. 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
@ -1,4 +1,4 @@
-\subsection{Algebraic knot}
+\subsection{Algebraic knots}
 \noindent
 Suppose $F: \mathbb{C}^2 \rightarrow \mathbb{C}$ is a polynomial and $F(0) = 0$. Let take small small sphere $S^3$ around zero. This sphere intersect set of roots of $F$ (zero set of $F$) transversally and by the implicit function theorem the intersection is a manifold. 
 The dimension of sphere is $3$ and $F^{-1}(0)$ has codimension $2$. 
@ -31,7 +31,7 @@ algebraic link (in older books on knot theory there is another notion of algebra
 \begin{example}
 Let $p$ and $q$ be coprime numbers such that $p<q$ and $p,q>1$. \\
 Zero is an isolated singular point ($\bigtriangledown F(0) = 0$). $F$ is quasi - homogeneous polynomial, so the isotopy class of the link doesn't depend on the choice of a sphere. 
-Consider $S^3 = \{ (z, w) \in \mathbb{C} : \max( \vert z \vert, \vert w \vert ) = \varepsilon$.
+Consider $S^3 = \{ (z, w) \in \mathbb{C} : \max( \vert z \vert, \vert w \vert )\} = \varepsilon$.
 The intersection
 $F^{-1}(0) \cap S^3$ is a torus $T(p, q)$.
 \\???????????????????
@ -128,9 +128,9 @@ $g_3(K_1 \# K_2) = g_3(K_1) + g_3(K_2)$.
 \fontsize{12}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
-\resizebox{1\textwidth}{!}{\input{images/satellite.pdf_tex}}
+\resizebox{1\textwidth}{!}{\input{images/satellite.pdf_tex}}}
-}
+\caption{Whitehead double  satellite knot.\\ 
-\caption{Whitehead double  satellite knot. Its pattern knot embedded non-trivially in an unknotted solid torus $T$ (e.i. $K \not\subset S^3\subset T$) and pattern in a companion knot.}
+The pattern knot embedded non-trivially in an unknotted solid torus $T$ (e.i. $K \not\subset S^3\subset T$) on the left and the pattern in a companion knot - trefoil - on the right.}
 \label{fig:sattelite}
 \end{figure}
 \noindent
--- a/lec_4.tex
+++ b/lec_4.tex
@ -65,7 +65,7 @@ Remark: $K \sim K^{\prime} \Leftrightarrow K \# -K^{\prime}$ is slice.
 \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.}
+\caption{$Y = F \cup \Sigma$ is a smooth closed surface.}
 \label{fig:closed_surface}
 \end{figure}
 \noindent
--- a/lec_5.tex
+++ b/lec_5.tex
@ -1,15 +1,14 @@
 \subsection{Slice knots and metabolic form}
 \begin{theorem}
 \label{the:sign_slice}
 If $K$ is slice, 
 then $\sigma_K(t)
 = \sign ( (1 - t)S +(1 - \bar{t})S^T)$ 
 is zero except possibly of finitely many points and $\sigma_K(-1) = \sign(S + S^T) \neq 0$.
 \end{theorem}
 \begin{proof}
 \noindent
 We will use the following lemma.
 \begin{lemma}
 \label{lem:metabolic}
-If $V$ is a Hermitian matrix ($\bar{V} = V^T$), $V$ is of size  $2n \times 2n$ and 
+If $V$ is a Hermitian matrix ($\bar{V} = V^T$), $V$ is of size  $2n \times 2n$, 
 $
 V = \begin{pmatrix}
 0 & A \\
@ -25,11 +24,16 @@ $\begin{pmatrix}
 \end{pmatrix}$ with half-dimensional null-space. 
 \end{definition}
 \noindent
-In other words: non-degenerate metabolic hermitian form has vanishing signature.\\
+Theorem \ref{the:sign_slice} can be also express as follow:
-We note that $\det(S + S^T) \neq 0$. Hence $\det ( (1 - t) S + (1 - \bar{t})S^T)$ is not identically zero on $S^1$, so it is non-zero except possibly at finitely many points. We apply the Lemma \ref{lem:metabolic}. \\
+non-degenerate metabolic hermitian form has vanishing signature.
-Let $t \in S^1 \setminus \{1\}$. Then:
+\begin{proof}
 \noindent
 We note that $\det(S + S^T) \neq 0$. Hence $\det ( (1 - t) S + (1 - \bar{t})S^T)$ is not identically zero on $S^1$, so it is non-zero except possibly at finitely many points. We apply the Lemma \ref{lem:metabolic}. 
 \\
 Let $t \in S^1 \setminus \{1\}$. 
 Then:
 \begin{align*}
-&\det((1 - t) S + (1 - \bar{t}) S^T) = 
+\det((1 - t) S + (1 - \bar{t}) S^T) =& 
 \det((1 - t) S + (t\bar{t} - \bar{t}) S^T) =\\
 &\det((1 - t) (S - \bar{t} - S^T))  =
 \det((1 -t)(S - \bar{t} S^T)).
@ -37,71 +41,118 @@ Let $t \in S^1 \setminus \{1\}$. Then:
 As $\det (S + S^T) \neq 0$, so $S - \bar{t}S^T \neq 0$.  
 \end{proof}
 \begin{corollary}
-If $K \sim K^\prime$ then for all but finitely many $t \in S^1 \setminus \{1\}: \sigma_K(t) = \sigma_{K^\prime}(t)$.
+If $K \sim K^\prime$ then for all but finitely many $t \in S^1 \setminus \{1\}: \sigma_K(t) = -\sigma_{K^\prime}(t)$.
 \end{corollary}
 \begin{proof}
 If $ K  \sim K^\prime$ then $K \# K^\prime$ is slice. 
 \[
 \sigma_{-K^\prime}(t) = -\sigma_{K^\prime}(t)
 \]
-\\??????????????\\
+The signature gives a homomorphism from the concordance group to $\mathbb{Z}$.
 The signature give a homomorphism from the concordance group to $\mathbb{Z}$.\\
 ??????????????????\\
 Remark: if $t \in S^1$ is not algebraic over $\mathbb{Z}$, then $\sigma_K(t) \neq 0$
-(we can is the argument that $\mathscr{C} \longrightarrow \mathbb{Z}$ as well). 
+(we can use the argument that $\mathscr{C} \longrightarrow \mathbb{Z}$ as well). 
 \end{proof}
 \subsection{Four genus}
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
-\resizebox{0.5\textwidth}{!}{\input{images/genus_2_bordism.pdf_tex}}
+\resizebox{0.7\textwidth}{!}{\input{images/genus_2_bordism.pdf_tex}}
 }
-\caption{$K$ and $K^\prime$ are connected by a genus $g$ surface of genus.}\label{fig:genus_2_bordism}
+\caption{$K$ and $K^\prime$ are connected by a genus $g$ surface.}\label{fig:genus_2_bordism}
 \end{figure}
-???????????????????????\\
+
 \begin{proposition}[Kawauchi inequality]
 If there exists a genus $g$ surface as in Figure \ref{fig:genus_2_bordism}
-then for almost all $t \in S^1 \setminus \{1\}$ we have $\vert \sigma_K(t) - \sigma_{K^\prime}(t) \vert \leq 2 g$. 
+then for almost all 
 $t \in S^1 \setminus \{1\}$ we have 
 $\vert 
 \sigma_K(t) - \sigma_{K^\prime}(t) 
 \vert \leq 2 g$. 
 \end{proposition}
 % Kawauchi  Chapter 12 ???
 % Borodzik 2010 Morse theory for plane algebraic curves
 \begin{lemma}
 If $K$ bounds a genus $g$ surface $X \in B^4$ and $S$ is a Seifert form then ${S \in M_{2n \times 2n}}$ has a block structure $\begin{pmatrix}
 0 & A\\
 B & C
 \end{pmatrix}$, where $0$ is $(n - g) \times (n - g)$ submatrix.
 \end{lemma}
-??????????????????????\\
+
-\begin{align*}
+\begin{proof}
-\dim H_1(Z)  = 2 n\\
+\begin{figure}[h]
-\dim H_1 (Y) = 2 n + 2 g\\
+\fontsize{20}{10}\selectfont
-\dim (\ker (H_1, Y) \longrightarrow H_1(\Omega)) = n + g\\
+\centering{
-Y = X \sum \Sigma
+\def\svgwidth{\linewidth}
-\end{align*}
+\resizebox{0.5\textwidth}{!}{\input{images/genus_bordism_zeros.pdf_tex}}
 }
 \caption{There exists a $3$ - manifold $\Omega$ such that $\partial \Omega = X \cup \Sigma$.}\label{fig:omega_in_B_4}
 \end{figure}
 \noindent
-If $\alpha, \beta \in \ker(H_1(\Sigma \longrightarrow H_1(\Omega))$, then ${\Lk(\alpha, \beta^+) = 0}$. 
+Let $K$ be a knot and $\Sigma$ its Seifert surface as in Figure  \ref{fig:omega_in_B_4}.
 There exists a $3$ - submanifold 
 $\Omega$ such that 
 $\partial \Omega = Y = X \cup \Sigma$ 
 (by Thom-Pontryagin construction).
 If $\alpha, \beta \in \ker (H_1(\Sigma) \longrightarrow H_1(\Omega))$, 
 then ${\Lk(\alpha, \beta^+) = 0}$. Now we have to determine the size of the kernel. We know that 
 ${\dim H_1(\Sigma)  = 2 n}$. When we glue $\Sigma$ (genus $n$) and $X$ (genus $g$) along a circle we get a surface of genus $n + g$. Therefore $\dim H_1 (Y) = 2 n + 2 g$. Then:
 \[
 \dim (\ker (H_1(Y) \longrightarrow H_1(\Omega)) = n + g.
 \]
 So we have $H_1(W)$ of dimension
 $2 n + 2 g$ 
 - the image of $H_1(Y)$ 
 with a subspace
 corresponding to the image of $H_1(\Sigma)$ with dimension $2 n$ and a subspace corresponding to the kernel  
 of $H_1(Y) \longrightarrow H_1(\Omega)$ of size $n + g$. 
 We consider minimal possible intersection of this subspaces that corresponds to the kernel of the composition $H_1(\Sigma) \longrightarrow H_1(Y) \longrightarrow H_1(\Omega)$. As the first map is injective, elements of the kernel of the composition have to be in the kernel of the second map. 
 So we can calculate: 
 \[
 \dim \ker (H_1(\Sigma) \longrightarrow H_1(\Omega)) = 2 n + n + g -2 n - 2 g = n - g.
 \]
 \end{proof}
 \begin{corollary}
-If $t$ is nota ???? of $\det $ ????
+If $t$ is not a root of 
-then $\vert \sigma_K(t) \vert \leq 2g$.\\
+$\det S S^T - $ \\
 ????????????????\\
 then 
 $\vert \sigma_K(t) \vert \leq 2g$.
 \end{corollary}
-\noindent
+\begin{fact}
-If there exists cobordism of genus $g$ between $K$ and $K^\prime$ like shown in Figure \ref{fig:genus_2_bordism}, then $K \# -K^\prime$ bounds a surface of genus $g$ in $B^4$.
+If there exists cobordism of genus $g$ between $K$ and $K^\prime$ like shown in Figure \ref{fig:proof_for_bound_disk}, then $K \# -K^\prime$ bounds a surface of genus $g$ in $B^4$.
 \end{fact}
 \begin{figure}[H]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.7\textwidth}{!}{\input{images/genus_bordism_proof.pdf_tex}}
 }
 \caption{If $K$ and $K^\prime$ are connected by a genus $g$ surface, then $K \# -K^\prime$ bounds a genus $g$ surface.}\label{fig:proof_for_bound_disk}
 \end{figure}
 \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 $\partial \Sigma = K$. 
 \end{definition}
 \noindent
-Remark: $3$ - genus is additive under taking connected sum, but $4$ - genus is not.
+Remarks: 
 \begin{enumerate}[label={(\arabic*)}]
 \item
 $3$ - genus is additive under taking connected sum, but $4$ - genus is not,
 \item
 for any knot $K$ we have $g_4(K) \leq g_3(K)$.
 \end{enumerate}
 \begin{example}
 \begin{itemize}
 \item Let $K = T(2, 3)$. $\sigma(K) = -2$, therefore $T(2, 3)$ isn't a slice knot. 
-\item Let $K$ be a trefoil and $K^\prime$ a mirror of a trefoil. $g_4(K^\prime) = 1$, but $g_(K \# K^\prime) = 0$.
+\item Let $K$ be a trefoil and $K^\prime$ a mirror of a trefoil. $g_4(K^\prime) = 1$, but $g_4(K \# K^\prime) = 0$, so we see that $4$-genus isn't additive,
 \\?????????????????????\\
 \item
-?????????????\\
+the equality: 
 The equality: 
 \[
 g_4(T(p, q) ) = \frac{1}{2} (p - 1) (g -1)
 \]
-was conjecture in the '70 and proved by  P. Kronheimer and T. Mrówka.
+was conjecture in the '70 and proved by  P. Kronheimer and T. Mrówka (1994).
 %  OZSVATH-SZABO AND RASMUSSEN
 \end{itemize}
 \end{example}
 \begin{proposition}
@ -142,4 +193,15 @@ 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: $A^T = A: (a, b) = \bar{(a, b)}$.
+A form is meant as hermitian with respect to this involution: $A^T = A: (a, b) = \bar{(a, b)}$.
 \\
 ????????????????????????????
 \\
 \begin{theorem}[Levine '68]
 \[
 W(\mathbb{Z}[t^{\pm 1}) 
 \longrightarrow \mathbb{Z}_2^\infty \oplus 
 \mathbb{Z}_4^\infty \oplus
 \mathbb{Z} 
 \]
 \end{theorem}
--- a/lec_6.tex
+++ b/lec_6.tex
@ -0,0 +1,147 @@
 $X$ is a closed orientable four-manifold. Assume $\pi_1(X) = 0$ (it is not needed to define the intersection form). In particular $H_1(X) = 0$. 
 $H_2$ is free (exercise). 
 \begin{align*}
 H_2(X, \mathbb{Z}) \xrightarrow{\text{Poincar\'e duality}} H^2(X, \mathbb{Z} ) \xrightarrow{\text{evaluation}}\Hom(H_2(X, \mathbb{Z}), \mathbb{Z})
 \end{align*}
 Intersection form: 
 $H_2(X, \mathbb{Z}) \times 
 H_2(X, \mathbb{Z}) \longrightarrow \mathbb{Z}$ is symmetric and non singular. 
 \\
 Let $A$ and $B$ be closed, oriented surfaces in $X$. 
 \\
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.5\textwidth}{!}{\input{images/intersection_form_A_B.pdf_tex}}
 }
 \caption{$T_X A + T_X B = T_X X$
 }\label{fig:torus_alpha_beta}
 \end{figure}
 ???????????????????????
 \begin{align*}
 x \in A \cap B\\
 T_XA \oplus T_X B = T_X X\\
 \{\epsilon_1, \dots , \epsilon_n \} = A \cap C\\
 A \cdot B = \sum^n_{i=1} \epsilon_i
 \end{align*}
 \begin{proposition}
 Intersection form $A \cdot B$ doesn't depend of choice of $A$ and $B$ in their homology classes: 
 \[
 [A], [B] \in H_2(X, \mathbb{Z}). 
 \]
 \end{proposition}
 \noindent
 \\
 If $M$ is an $m$ - dimensional close, connected and orientable manifold, then $H_m(M, \mathbb{Z})$ and the orientation if $M$ determined a cycle $[M] \in H_m(M, \mathbb{Z})$, called the fundamental cycle. 
 \begin{example}
 If $\omega$ is an $m$ - form then: 
 \[
 \int_M \omega = [\omega]([M]), \quad [\omega] \in H^m_\Omega(M), \ [M] \in H_m(M).
 \]
 \end{example}
 ????????????????????????????????????????????????
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.8\textwidth}{!}{\input{images/torus_alpha_beta.pdf_tex}}
 }
 \caption{$\beta$ cross $3$ times the disk bounded by $\alpha$. 
 $T_X \alpha + T_X \beta = T_X \Sigma$
 }\label{fig:torus_alpha_beta}
 \end{figure}
 \begin{example}
 ?????????????????????????\\
 Let $X = S^2 \times S^2$. 
 We know that:
 \begin{align*}
 &H_2(S^2, \mathbb{Z}) =\mathbb{Z}\\
 &H_1(S^2, \mathbb{Z}) = 0\\
 &H_0(S^2, \mathbb{Z}) =\mathbb{Z}
 \end{align*}
 We can construct a long exact sequence for a pair:
 \begin{align*}
 &H_2(\partial X) \to H_2(X)
 \to H_2(X, \partial X) \to \\
 \to &H_1(\partial X) \to H_1(X) \to H_1(X, \partial X) \to
 \end{align*}
 ????????????????????\\
 Simple case $H_1(\partial X)$ \\????????????\\
 is torsion.
 $H_2(\partial X)$ is torsion free (by universal coefficient theorem),\\
 ???????????????????????\\
 therefore it is $0$. 
 \\?????????????????????\\
 We know that $b_1(X) = b_2(X)$. Therefore by Poincar\'e duality:
 \begin{align*}
 b_1(X) = 
 \dim_{\mathbb{Q}} H_1(X, \mathbb{Q})
 \overset{\mathrm{PD}}{=}
 \dim_{\mathbb{Q}} H^2(X, \mathbb{Q}) =
 \dim_{\mathbb{Q}} H_2(X, \mathbb{Q}) = b_2(X)
 \end{align*}
 ???????????????????????????????\\
 $H_2(X, \mathbb{Z})$ is torsion free and 
 $H_2(X_1, \mathbb{Q}) = 0$, therefore $H_2(X, \mathbb{Z}) = 0$. 
 The map 
 $H_2(X, \mathbb{Z}) \longrightarrow H_2(X, \partial X, \mathbb{Z})$ is a monomorphism. \\??????????\\ (because it is an isomorphism after tensoring by $\mathbb{Q}$.
 \\
 Suppose $\alpha_1, \dots, \alpha_n$ is a basis of $H_2(X, \mathbb{Z})$.
 Let $A$ be the intersection matrix in this basis. Then:
 \begin{enumerate}
 \item 
 A has integer coefficients,
 \item
 $\det A \neq 0$,
 \item 
 $\vert \det A \vert =
 \vert H_1 (\partial X, \mathbb{Z}) \vert = 
 \vert \coker H_2(X) \longrightarrow H_2(X, \partial X) \vert$.
 \end{enumerate}
 \end{example}
 ???????????????????\\
 If $CVC^T = W$, then for 
 $\binom{a}{b} = C^{-1} \binom{1}{0}$ we have $\binom{a}{b} $ \\
 ????????????????\\
 $\omega \binom{a}{b} = \binom{1}{0} u \binom{1}{0} = 1$.
 \begin{theorem}[Whitehead]
 Any non-degenerate form 
 \[
 A : \mathbb{Z}^4 \times \mathbb{Z}^4 \longrightarrow \mathbb{Z}
 \]
 can be realized as an intersection form of a simple connected $4$-dimensional manifold.
 \end{theorem}
 ??????????????????????????
 \begin{theorem}[Donaldson, 1982]
 If $A$ is an even definite intersection form of a smooth $4$-manifold then it is diagonalizable over $\mathbb{Z}$.
 \end{theorem}
 ??????????????????????????
 ??????????????????????????
 ??????????????????????????
 ??????????????????????????
 \begin{definition}
 even define 
 \end{definition}
 Suppose $X$ us $4$ -manifold with a boundary such that $H_1(X) = 0$. 
 %$A \cdot B$  gives the pairing as ??
 \begin{proof}
 Obviously:
 \[H_1(\partial X, \mathbb{Z}) = \coker H_2(X) \longrightarrow H_2(X, \partial X) = \quot{H_2(X, \partial X)}{H_2(X)}.
 \]
 Let $A$ be an $n \times n$ matrix. $A$ determines a \\
 ??????????????/\\
 \begin{align*}
 \mathbb{Z}^n \longrightarrow \Hom (\mathbb{Z}^n, \mathbb{Z})\\
 a \mapsto (b \mapsto b^T A a)\\
 \vert \coker A \vert = \vert \det A \vert
 \end{align*}
 all homomorphisms $b = (b_1, \dots, b_n) $???????\\?????????\\
 \end{proof}
--- a/lectures_on_knot_theory.tex
+++ b/lectures_on_knot_theory.tex
@ -8,6 +8,7 @@
 \usepackage[english]{babel}
 \usepackage{caption}
 \usepackage{comment}
 \usepackage{csquotes}
@ -23,6 +24,7 @@
 \usepackage{mathtools}
 \usepackage{pict2e}
 \usepackage[section]{placeins}
 \usepackage[pdf]{pstricks}
 \usepackage{tikz}
@ -84,9 +86,9 @@
 \DeclareMathOperator{\Hom}{Hom}
 \DeclareMathOperator{\rank}{rank}
 \DeclareMathOperator{\coker}{coker}
 \DeclareMathOperator{\ord}{ord}
 \DeclareMathOperator{\mytop}{top}
 \DeclareMathOperator{\Gl}{GL}
 \DeclareMathOperator{\Sl}{SL}
 \DeclareMathOperator{\Lk}{lk}
@ -126,80 +128,18 @@
 %add Hurewicz theorem?
-\section{\hfill\DTMdate{2019-03-11}}
+\section{Examples of knot classes
 \hfill\DTMdate{2019-03-11}}
 \input{lec_3.tex}
 \section{Concordance group \hfill\DTMdate{2019-03-18}}
 \input{lec_4.tex}
-
+\section{Genus $g$ cobordism \hfill\DTMdate{2019-03-25}}
 \section{\hfill\DTMdate{2019-03-25}}
 \input{lec_5.tex}
 \section{\hfill\DTMdate{2019-04-08}}
-%
+\input{lec_6.tex}
 %
 $X$ is a closed orientable four-manifold. Assume $\pi_1(X) = 0$ (it is not needed to define the intersection form). In particular $H_1(X) = 0$. 
 $H_2$ is free (exercise). 
 \begin{align*}
 H_2(X, \mathbb{Z}) \xrightarrow{\text{Poincar\'e duality}} H^2(X, \mathbb{Z} ) \xrightarrow{\text{evaluation}}\Hom(H_2(X, \mathbb{Z}), \mathbb{Z})
 \end{align*}
 Intersection form: 
 $H_2(X, \mathbb{Z}) \times 
 H_2(X, \mathbb{Z}) \longrightarrow \mathbb{Z}$ - symmetric, non singular. 
 \\
 Let $A$ and $B$ be closed, oriented surfaces in $X$. 
 \begin{proposition}
 $A \cdot B$ doesn't depend of choice of $A$ and $B$ in their homology classes: 
 \[
 [A], [B] \in H_2(X, \mathbb{Z}). 
 \]
 \end{proposition}
 \noindent
 \\
 If $M$ is an $m$ - dimensional close, connected and orientable manifold, then $H_m(M, \mathbb{Z})$ and the orientation if $M$ determined a cycle $[M] \in H_m(M, \mathbb{Z})$, called the fundamental cycle. 
 \begin{example}
 If $\omega$ is an $m$ - form then: 
 \[
 \int_M \omega = [\omega]([M]), \quad [\omega] \in H^m_\Omega(M), \ [M] \in H_m(M).
 \]
 \end{example}
 ????????????????????????????????????????????????
 \begin{figure}[h]
 \fontsize{20}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
 \resizebox{0.8\textwidth}{!}{\input{images/torus_alpha_beta.pdf_tex}}
 }
 \caption{$\beta$ cross $3$ times the disk bounded by $\alpha$. 
 $T_X \alpha + T_X \beta = T_Z \Sigma$
 }\label{fig:torus_alpha_beta}
 \end{figure}
 \begin{theorem}
 Any non-degenerate form 
 \[
 A : \mathbb{Z}^n \times \mathbb{Z}^n \longrightarrow \mathbb{Z}
 \]
 can be realized as an intersection form of a simple connected $4$-dimensional manifold.
 \end{theorem}
 ??????????????????????????
 \begin{theorem}[Donaldson, 1982]
 If $A$ is an even defined intersection form of a smooth $4$-manifold then it is diagonalizable over $\mathbb{Z}$.
 \end{theorem}
 ??????????????????????????
 ??????????????????????????
 ??????????????????????????
 ??????????????????????????
 \begin{definition}
 even define 
 \end{definition}
 Suppose $X$ us $4$ -manifold with a boundary such that $H_1(X) = 0$. 
 %$A \cdot B$  gives the pairing as ??
 \section{\hfill\DTMdate{2019-04-15}}
 \begin{theorem}
@ -341,14 +281,17 @@ a &\mapsto (a, \_) H_2(M, \mathbb{Z})
 \end{align*}
 has coker precisely $H_1(Y, \mathbb{Z})$. 
 \\???????????????\\
-Let $K \subset S^3$  be a knot, \\
+Let $K \subset S^3$  be a knot, $X = S^3 \setminus K$  a knot complement and
-$X = S^3 \setminus K$ - a knot complement,  \\
+$\widetilde{X} \xrightarrow{\enspace \rho \enspace} X$  an infinite cyclic cover (universal abelian cover). By Hurewicz theorem we know that:
 $\widetilde{X} \xrightarrow{\enspace \rho \enspace} X$ - an infinite cyclic cover (universal abelian cover).
 \begin{align*}
 \pi_1(X) \longrightarrow \quot{\pi_1(X)}{[\pi_1(X), \pi_1(X)]} = H_1(X, \mathbb{Z} ) \cong \mathbb{Z}
 \end{align*}
 ????????????????????????????????????????????????????????????????????????\\
 ????????????????????????????????????????????????????????????????????????\\
 ????????????????????????????????????????????????????????????????????????\\
 ????????????????????????????????????????????????????????????????????????\\
 $C_{*}(\widetilde{X})$ has a structure of a $\mathbb{Z}[t, t^{-1}] \cong  \mathbb{Z}[\mathbb{Z}]$ module. \\
-$H_1(\widetilde{X}, \mathbb{Z}[t, t^{-1}])$ - Alexander module, \\
+Let $H_1(\widetilde{X}, \mathbb{Z}[t, t^{-1}])$ be the Alexander module of the knot $K$ with an intersection form: 
 \begin{align*}
 H_1(\widetilde{X}, \mathbb{Z}[t, t^{-1}]) \times
 H_1(\widetilde{X}, \mathbb{Z}[t, t^{-1}]) \longrightarrow \quot{\mathbb{Q}}{\mathbb{Z}[t, t^{-1}]}
@ -365,27 +308,31 @@ H_1(\widetilde{X}, \mathbb{Z}[t, t^{-1}]) \longrightarrow \quot{\mathbb{Q}}{\mat
 \begin{align*}
 H_1(\widetilde{X}, \mathbb{Z}[t, t^{-1}]) \times
 H_1(\widetilde{X}, \mathbb{Z}[t, t^{-1}]) &\longrightarrow \quot{\mathbb{Q}}{\mathbb{Z}[t, t^{-1}]}\\
-(\alpha, \beta) &\mapsto \alpha^{-1}(t -1)(tV - V^T)^{-1}\beta
+(\alpha, \beta) \quad &\mapsto \alpha^{-1}(t -1)(tV - V^T)^{-1}\beta
 \end{align*}
 \end{fact}
 \noindent
-Note that $\mathbb{Z}$ is not PID. Therefore we don't have primer decomposition of this moduli.  We can simplify this problem by replacing $\mathbb{Z}$ by $\mathbb{R}$. We lose some date by doing this transition. 
+Note that $\mathbb{Z}$ is not PID. 
 Therefore we don't have primary decomposition of this module.  
 We can simplify this problem by replacing $\mathbb{Z}$ by $\mathbb{R}$. We lose some date by doing this transition, but we can 
 \begin{align*}
-&\xi \in S^1 \setminus \{ \pm 1\} 
+\xi \in S^1 \setminus \{ \pm 1\} 
-\quad
+&\quad
 p_{\xi} = 
 (t - \xi)(t - \xi^{-1}) t^{-1}
 \\
-&\xi \in \mathbb{R} \setminus \{ \pm 1\}
+\xi \in \mathbb{R} \setminus \{ \pm 1\}
-\quad
+&\quad
 q_{\xi} = (t - \xi)(t - \xi^{-1}) t^{-1}
 \\
-&
+\xi \notin \mathbb{R} \cup S^1 
-\xi \notin \mathbb{R} \cup S^1 \quad
+&\quad
-q_{\xi} = (t - \xi)(t - \overbar{\xi})(t - \xi^{-1})(t - \overbar{\xi}^{-1}) t^{-2}\\
+q_{\xi} = (t - \xi)(t - \overbar{\xi})(t - \xi^{-1})
-&
+(t - \overbar{\xi}^{-1}) t^{-2}
-\Lambda = \mathbb{R}[t, t^{-1}]\\
+\end{align*}
-&\text{Then: } H_1(\widetilde{X}, \Lambda) \cong  \bigoplus_{\substack{\xi \in S^1 \setminus \{\pm 1 \}\\ k\geq 0}}
+Let $\Lambda = \mathbb{R}[t, t^{-1}]$. Then: 
 \begin{align*}
 H_1(\widetilde{X}, \Lambda) \cong  \bigoplus_{\substack{\xi \in S^1 \setminus \{\pm 1 \}\\ k\geq 0}}
 ( \quot{\Lambda}{p_{\xi}^k })^{n_k, \xi}
 \oplus
 \bigoplus_{\substack{\xi \notin S^1 \\ l\geq 0}}
@ -557,7 +504,9 @@ $2 \sum\limits_{k_i \text{ odd}} \epsilon_i$. The peak of the signature function
 ....
 \begin{definition}
-A square hermitian matrix $A$ of size $n$.  
+A square hermitian matrix $A$ of size $n$ with coefficients in \\
 the Blanchfield pairing if:
 $H_1(\bar{X}$
 \end{definition}
 field of fractions