Exercises:Saul - Algebraic Topology - 9
From Maths
Exercises
Exercise 9.7
Show that the cone on the real projective plane, i.e. [ilmath]C(\mathbb{RP}^2)[/ilmath], is not a topological 3-manifold with boundary.
I might have two solutions for this, I accidentally answered the wrong question initially. [ilmath]\newcommand{\crp}{C(\mathbb{RP}^2)} [/ilmath]
Solution 1
- I struggled to focus writing this up, however the idea should be clear, if the presentation isn't up to my usual standard please forgive me. Aditionally:
- [ilmath]\langle G\rangle[/ilmath] means the "normal subgroup generated by [ilmath]G[/ilmath]", fortunately where it is used here [ilmath]G[/ilmath] is trivial, thus is a normal subgroup itself so [ilmath]\langle 0\rangle\eq 0[/ilmath], thus the question of "normal subgroup closure" never pops up in this solution.
Before we start, I want to note that we make heavy use of the fundamental group, and I may write this without a base-point, this is because for a path-connected space the fundamental group based anywhere is isomorphic to any other fundamental group based elsewhere of the space. Please know that I know this.
First we consider [ilmath]\crp[/ilmath] as a topological space and work out some fundamental group isomorphisms.
- Immediately, as any topological cone is contractible space we see:
- [ilmath]\pi_1(\crp)\cong 0[/ilmath] (where [ilmath]0[/ilmath] denotes the trivial group, we do not use [ilmath]1[/ilmath] even though fundamental groups are usually not Abelian)
Let [ilmath]p\in\crp[/ilmath] be the apex of the cone, i.e. the image of [ilmath]\mathbb{RP}^2\times\{1\} [/ilmath] under the the cone's quotient map, some people may identify [ilmath]X\times\{0\} [/ilmath] as the apex, we do not.
Consider [ilmath]\crp-\{p\} [/ilmath], this is easily seen to be homeomorphic to [ilmath]\mathbb{RP}^2\times[0,1)[/ilmath]
- Note that [ilmath]\mathbb{RP}^2\times[0,1)[/ilmath] has [ilmath]\mathbb{RP}^2[/ilmath] as a strong deformation retraction (by slowly "projecting down" along [ilmath][0,1)[/ilmath]), and thus:
- [ilmath]\pi_1(\crp-\{p\})\cong\pi_1(\mathbb{RP}^2)\cong\frac{\mathbb{Z} }{2\mathbb{Z} } [/ilmath]
We summarise:
- [ilmath]\pi_1(\crp)\cong 0[/ilmath] and
- [ilmath]\pi_1(\crp-\{p\})\cong\pi_1(\mathbb{RP}^2)\cong\frac{\mathbb{Z} }{2\mathbb{Z} } [/ilmath]
We now use the "fact" it is a manifold to tackle the claim: [ilmath]\pi_1(\crp)\cong\pi_1(\crp-\{p\})[/ilmath] - this will make use of the Seifert-Van Kampen theorem.
- Let [ilmath]x\in\crp[/ilmath] be an arbitrary point that is not the implicit basepoint for [ilmath]\pi_1[/ilmath]
- suppose that [ilmath]x[/ilmath] is in the interior of the manifold[Note 1], then:
- there exists a homeomorphism: [ilmath]\varphi:U\rightarrow\mathbb{B}^3[/ilmath] which takes an open neighbourhood of [ilmath]x[/ilmath] onto the open unit ball at the origin.
- Suppose WLOG that [ilmath]\varphi(x)\eq 0[/ilmath] (we can do this as if this wasn't the case we can use that translations are homeomorphisms in Euclidean space to get a new chart, [ilmath]\varphi':z\mapsto \varphi(z)-\varphi(x)[/ilmath] instead, this is also a homeomorphism and has the property that [ilmath]\varphi'(x)\eq 0[/ilmath])
- Note that homeomorphic spaces have isomorphic fundamental groups so [ilmath]\pi_1(U)\cong\pi_1(\mathbb{B}^3)[/ilmath]
- Note also given a homeomorphism all subspaces of the domain are homeomorphic to their image under the homeomorphism itself so
- [ilmath]\varphi\big\vert_{U-\{x\} }:(U-\{x\})\rightarrow(\mathbb{B}^3-\{0\})[/ilmath] is a homeomorphism
- We now use the Seifert-Van kampen theorem to see:
- [math]\pi_1(\crp)\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(U)}{\langle \pi_1\big((\crp-\{x\})\cap U\big)\rangle} [/math][Note 2] which by homeomorphic spaces have isomorphic fundamental groups:
- [math]\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(\mathbb{B}^3)}{\langle\pi_1(U-\{x\})\rangle} [/math] (by replacing spaces with homeomorphic ones)
- [math]\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(\mathbb{B}^3)}{\langle\pi_1(\mathbb{B}^3-\{0\})\rangle} [/math] (by replacing spaces with homeomorphic ones)
- [math]\cong\frac{\pi_1(\crp-\{x\})\ast 0}{0} [/math] as [ilmath]\mathbb{B}^3[/ilmath] is clearly contractible, and [ilmath]\mathbb{B}^3-\{0\} [/ilmath] strongly deformation retracts to the 2-sphere which has trivial fundamental group (easily seen as any loop can be "pulled" to its base point in [ilmath]\mathbb{S}^2[/ilmath])
- [ilmath]\cong\pi_1(\crp-\{x\})[/ilmath]
- [math]\pi_1(\crp)\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(U)}{\langle \pi_1\big((\crp-\{x\})\cap U\big)\rangle} [/math][Note 2] which by homeomorphic spaces have isomorphic fundamental groups:
- We conclude:
- [ilmath]\pi_1(\crp)\cong\pi_1(\crp-\{x\})[/ilmath] - provided [ilmath]x[/ilmath] is an interior point of the [ilmath]3[/ilmath]-manifold [ilmath]\crp[/ilmath]
- Suppose WLOG that [ilmath]\varphi(x)\eq 0[/ilmath] (we can do this as if this wasn't the case we can use that translations are homeomorphisms in Euclidean space to get a new chart, [ilmath]\varphi':z\mapsto \varphi(z)-\varphi(x)[/ilmath] instead, this is also a homeomorphism and has the property that [ilmath]\varphi'(x)\eq 0[/ilmath])
- there exists a homeomorphism: [ilmath]\varphi:U\rightarrow\mathbb{B}^3[/ilmath] which takes an open neighbourhood of [ilmath]x[/ilmath] onto the open unit ball at the origin.
- now suppose [ilmath]x\in\partial(\crp)[/ilmath] - that is [ilmath]x[/ilmath] is a boundary point of our 3-manifold with boundary[Note 3]
- We see that there exists a homeomorphism: [ilmath]\varphi:U\rightarrow\mathbb{H}^3[/ilmath] where [ilmath]U[/ilmath] is an open neighbourhood of [ilmath]x[/ilmath] and [ilmath]\mathbb{H}^3[/ilmath] denotes the 3-dimensional half space:
- [ilmath]\mathbb{H}^3:\eq\{(x_1,x_2,x_3)\in\mathbb{R}^3\ \big\vert\ \Vert (x_1,x_2,x_3)\Vert < 1 \wedge x_3\ge 0\} \eq \mathbb{B}^3\cap\{(x_1,x_2,x_3)\in\mathbb{R}^3\ \big\vert\ x_3\ge 0\} [/ilmath]
- Such that [ilmath]\big(\varphi(x)\big)_3\eq 0[/ilmath] (i.e. on the [ilmath]x_3\eq 0[/ilmath] plane in [ilmath]\mathbb{R}^3[/ilmath])
- Again WLOG we can suppose [ilmath]\varphi(x)\eq 0[/ilmath] - for the same reasoning as the previous case[Note 4]
- As before we note that [ilmath](U-\{x\})\cong(\mathbb{H}^3-\{0\})[/ilmath] by the restriction of [ilmath]\varphi[/ilmath] to the left hand side of the [ilmath]\cong[/ilmath]
- We use the Seifert-Van Kapmen theorem again:
- [math]\pi_1(\crp)\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(U)}{\langle \pi_1\big((\crp-\{x\})\cap U\big)\rangle} [/math][Note 5] which by homeomorphic spaces have isomorphic fundamental groups:
- [math]\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(\mathbb{H}^3)}{\langle\pi_1(U-\{x\})\rangle} [/math] (by replacing spaces with homeomorphic ones)
- [math]\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(\mathbb{H}^3)}{\langle\pi_1(\mathbb{H}^3-\{0\})\rangle} [/math] (by replacing spaces with homeomorphic ones)
- [math]\cong\frac{\pi_1(\crp-\{x\})\ast 0}{0} [/math] as [ilmath]\mathbb{H}^3[/ilmath] and [ilmath]\mathbb{H}^3-\{0\} [/ilmath] are both clearly contractible. (To convince yourself of this take the origin for [ilmath]\mathbb{H}^3[/ilmath], you can just "straight-line" pull everything onto it. For [ilmath]\mathbb{H}^3-\{0\} [/ilmath] pick the point [ilmath](0,0,1)[/ilmath] to pull back on, again straight line onto this point)
- [ilmath]\cong\pi_1(\crp-\{x\})[/ilmath]
- [math]\pi_1(\crp)\cong\frac{\pi_1(\crp-\{x\})\ast\pi_1(U)}{\langle \pi_1\big((\crp-\{x\})\cap U\big)\rangle} [/math][Note 5] which by homeomorphic spaces have isomorphic fundamental groups:
- We conclude:
- [ilmath]\pi_1(\crp)\cong\pi_1(\crp-\{x\})[/ilmath] - provided [ilmath]x[/ilmath] is a boundary point of the [ilmath]3[/ilmath]-manifold with boundary[ilmath]\crp[/ilmath]
- Again WLOG we can suppose [ilmath]\varphi(x)\eq 0[/ilmath] - for the same reasoning as the previous case[Note 4]
- We see that there exists a homeomorphism: [ilmath]\varphi:U\rightarrow\mathbb{H}^3[/ilmath] where [ilmath]U[/ilmath] is an open neighbourhood of [ilmath]x[/ilmath] and [ilmath]\mathbb{H}^3[/ilmath] denotes the 3-dimensional half space:
- Thus in either case:
- [ilmath]\pi_1(\crp)\cong\pi_1(\crp-\{x\})[/ilmath]
- suppose that [ilmath]x[/ilmath] is in the interior of the manifold[Note 1], then:
- Since [ilmath]x\in\crp[/ilmath] was arbitrary (and not the implicit base-point) we see [ilmath]\pi_1(\crp)\cong\pi_1(\crp-\{x\})[/ilmath] holds for all [ilmath]x[/ilmath]
- Next we combine everything to see:
- [ilmath]0\cong\pi_1(\crp)\cong \pi_1(\crp-\{p\})\cong\pi_1(\mathbb{RP}^2)\cong\frac{\mathbb{Z} }{2\mathbb{Z} } [/ilmath]
- Thus: [ilmath]0\cong\frac{\mathbb{Z} }{2\mathbb{Z} } [/ilmath] - obviously a contradiction!
- [ilmath]0\cong\pi_1(\crp)\cong \pi_1(\crp-\{p\})\cong\pi_1(\mathbb{RP}^2)\cong\frac{\mathbb{Z} }{2\mathbb{Z} } [/ilmath]
- Thus [ilmath]\crp[/ilmath] cannot be a [ilmath]3[/ilmath]-manifold with boundary
- In fact it cannot be a [ilmath]3[/ilmath]-manifold without boundary either, as per the first half where we assumed [ilmath]x[/ilmath] was a point interior to the manifold.
This completes the proof.
Notes
- ↑ Not to be confused with a topological interior point
- ↑ I take it as obvious that:
- [ilmath]\crp-\{x\} [/ilmath] is an open set in [ilmath]\crp[/ilmath] - clearly the complement is closed!
- [ilmath]U[/ilmath] is open by definition
- ↑ Not to be confused with a topological boundary point
- ↑ Restated:
- we can do this as if this wasn't the case we can use that translations are homeomorphisms in Euclidean space to get a new chart, [ilmath]\varphi':z\mapsto \varphi(z)-\varphi(x)[/ilmath] instead, this is also a homeomorphism and has the property that [ilmath]\varphi'(x)\eq 0[/ilmath]
- ↑ I take it as obvious that:
- [ilmath]\crp-\{x\} [/ilmath] is an open set in [ilmath]\crp[/ilmath] - clearly the complement is closed!
- [ilmath]U[/ilmath] is open by definition
