0708-1300/Class notes for Tuesday, March 25

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Typed Notes

The notes below are by the students and for the students. Hopefully they are useful, but they come with no guarantee of any kind.

First Hour

Definition

We define the CW chain complex via:

${\displaystyle C_{n}^{CW}(K):=<K_{n}>}$

and the boundary maps via ${\displaystyle \partial :C_{n}^{CW}\rightarrow C_{n-1}^{CW}}$ by ${\displaystyle \partial \sigma =\sum _{\tau \in K_{n-1}}[\tau :\sigma ]\tau }$

where ${\displaystyle [\tau :\sigma ]}$ is roughly the number of times that ${\displaystyle \partial \sigma }$ covers ${\displaystyle \tau }$.

Let's make this precise.

For ${\displaystyle f_{\sigma }:D_{\sigma }^{n}\rightarrow K}$ (not quite an embedding) this restricts to a map ${\displaystyle f_{\partial \sigma }:S_{\sigma }^{n}\rightarrow K}$. Given ${\displaystyle \tau \in K_{m}}$ let ${\displaystyle p_{\tau }:K^{n}\rightarrow S^{n}=B^{n}\cup \{\infty \}}$ such that ${\displaystyle int(D_{\tau }^{n})\mapsto B^{n}}$ and the rest maps to the point ${\displaystyle \infty }$.

Example:

If you just have the segment consisting of two endpoints and the line connecting them, and call this ${\displaystyle \tau }$, then ${\displaystyle p_{\tau }}$ takes the two end points to ${\displaystyle \infty }$ and the rest (the open interval) gets mapped to ${\displaystyle B^{1}}$. Hence, we get a circle.

We thus can now formally define ${\displaystyle [\tau :\sigma ]=deg(p_{\tau }\circ f_{\partial \sigma }:S^{n-1}\rightarrow S^{n-1})}$

Theorem

${\displaystyle (C_{*}^{CW},\partial )}$ is a chain complex; ${\displaystyle \partial ^{2}=0}$ and ${\displaystyle H_{*}^{CW}(K)=H_{*}(K)}$

Examples:

1) ${\displaystyle S^{n}=\{\infty \}\cup D^{n}}$ for n>1

${\displaystyle f_{\partial \sigma }:S^{n-1}\rightarrow \infty }$

Hence ${\displaystyle C_{n}^{CW}=<\sigma >,C_{0}^{CW}=<\infty >}$ and all the rest are zero. Hence, ${\displaystyle H_{p}(S^{n})=\mathbb {Z} }$ for p = 0 or n and is zero otherwise.

2) Consider the torus thought of as a square with the usual identifications and ${\displaystyle \sigma }$ is the interior. Hence, ${\displaystyle C_{0}^{CW}=\{p\},C_{1}^{CW}}$ is generated by the figure 8 with one loop labeled a and the other labeled b, and ${\displaystyle C_{2}^{CW}}$ is generated by the entire torus.

Ie we get ${\displaystyle \mathbb {Z} \rightarrow \mathbb {Z} ^{2}\rightarrow \mathbb {Z} }$

Now, ${\displaystyle \partial a=[p:a]p}$

but ${\displaystyle \partial }$ a takes the two endpoints of a (both p) and maps them to p. Neither point is mapped to ${\displaystyle \infty }$. Hence, ${\displaystyle deg\partial a:S^{0}\rightarrow S^{0}=0}$

Note: This ought to be checked from the definition of degree but was just stated in class

Now, ${\displaystyle [\sigma :a]}$ = the degree of the map that takes the square to the figure 8...and hence is ${\displaystyle \pm 1\mp 1=0}$.

Hence the boundary map is zero at all places, so ${\displaystyle H_{n}(\mathbb {T} ^{2})=\mathbb {Z} }$ if n = 0 or 2, ${\displaystyle \mathbb {Z} ^{2}}$ if n = 1 and is zero otherwise.

3) Consider the Klein bottle thought of as a square with the usual identifications. Under ${\displaystyle p_{b}\circ f_{\partial \sigma }}$ takes this to a circle with side labled b.

I.e., ${\displaystyle <\sigma >\mapsto <a,b>\mapsto ^{0}<p>}$

${\displaystyle \partial \sigma =[a:\sigma ]a+b:\sigma b=0_{a}+2b}$

Where the sign may be negative. Or more eloquantly put: "2b or -2b, that is the question"

The kernal of ${\displaystyle <a,b>\rightarrow <p>}$ is everything, so the homology is ${\displaystyle H_{1}(K)=<a,b>/2b=0\cong \mathbb {Z} \oplus \mathbb {Z} /2}$, ${\displaystyle H_{0}(K)=\mathbb {Z} }$ and ${\displaystyle H_{2}(K)=0}$.

4) ${\displaystyle \Sigma _{g}}$ the "g holed torus" or "surface of genus g" is formed by the normal diagram with edges identified in sets of 4 such as ${\displaystyle aba^{-1}b^{-1}}$

So, get ${\displaystyle <\sigma >\rightarrow ^{0}<a_{1},\cdots ,a_{g},b_{1},\cdots ,b_{g}>\rightarrow ^{0}<p>}$

Therefore, ${\displaystyle H_{p}=\mathbb {Z} }$ if p = 2 or 0, ${\displaystyle \mathbb {Z} ^{2g}}$ if p = 1 and zero elsewhere.

5) ${\displaystyle \mathbb {R} P^{n}=D^{n}\cup \mathbb {R} P^{n-1}=D^{n}\cup D^{n-1}\cup \cdots \cup D^{0}}$

So, ${\displaystyle C_{*}^{CW}(\mathbb {R} P^{n})is<D^{n}>\rightarrow <D^{n-1}>\rightarrow \cdots \rightarrow <D^{0}>}$

The boundary map alternates between 0 and 2 where it is 2 for ${\displaystyle <D^{i}>\rightarrow <D^{i-1}>}$ if i is even and 0 if it is odd.

Hence the homology alternates between ${\displaystyle \mathbb {Z} /2}$ for odd p and 0 for even p.

Second Hour

${\displaystyle \mathbb {C} P^{n}:\{[z_{0},\cdots ,z_{n}]:z_{i}\in \mathbb {C} \ not\ all\ zero\}=\mathbb {C} ^{n+1}/z\sim \alpha z}$ for ${\displaystyle z\in \mathbb {C} ^{n+1}}$, ${\displaystyle \alpha \in \mathbb {C} -\{0\}}$

${\displaystyle \mathbb {C} P^{n}=\{[z_{0},\cdots ,z_{n}]:z_{n}\neq 0\}\cup \{[\ldots ,0]\}=\{[z_{0},\cdots ,z_{n-1},1]\}\cup \mathbb {C} P^{n-1}}$ =${\displaystyle \mathbb {C} ^{n}\cup \mathbb {C} P^{n-1}=\mathbb {R} ^{2n}\cup \mathbb {C} P^{n-1}=B^{2n}\cup \mathbb {C} P^{n-1}}$

I.e., ${\displaystyle \mathbb {C} P^{n}=D^{2n}\cup D^{2n-1}\cup \cdots }$

So, ${\displaystyle C_{*}^{CW}(\mathbb {C} P^{n})}$ alternates between 0 (for odd p) and ${\displaystyle \mathbb {Z} }$ for even p and thus as this also as the homology. (and clearly trivial greater than p)