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Transcript
Complex projective space
The complex projective space CPn is the most important
compact complex manifold. By definition, CPn is the set of lines in Cn+1 or, equivalently,
CPn := (Cn+1 \{0})/C∗,
where C∗ acts by multiplication on Cn+1 . The points of CPn are written as (z0 , z1 , ..., zn ).
Here, the notation intends to indicate that for λ ∈ C∗ the two points (λz0 , λz1 , ..., λzn ) and
(z0 , z1 , ..., zn ) define the same point in CPn . We denote the equivalent class by [z0 : z1 : ... :
zn ]. Only the origin (0, 0, ..., 0) does not define a point in CPn .
We take the standard open covering of CPn . Let Ui be the open set
Ui := {[z0 : ... : zn ] | zi 6= 0} ⊂ CPn .
Consider the bijective maps
τi :
→ Cn
zi−1 zi+1
z0
zn
[z0 : ... : zn ] 7→
, ..., zi , zi , ..., zi
zi
Ui
For the transition maps
τij = τi ◦ τj−1 : τj (Ui ∩ Uj ) → τi (Ui ∩ Uj )
wj−1 1 wi+1
wi−1 wi+1
w1
wn
(w1 , ..., wn ) 7→
, ..., wi , wi , ..., wi , wi , wi , ..., wi
wi
is biholomorphic. In fact,
τij (w1 , ..., wn ) = τi ◦ τj−1 (w1 , ..., wn )
= τi ([w1 : ... : wj−1 : 1 : wj+1 : ... : wn ])
w1
wi−1
wi+1
wj−1 1 wi+1
wn
= τi
: ... :
:1:
: ... :
:
:
: ... :
wi
wi
wi
wi
wi
wi
wi
wi−1 wi+1
wj−1 1 wi+1
wn
w1
, ...,
,
, ...,
, ,
, ...,
=
wi
wi
wi
wi wi wi
wi
In particular, when n = 1, CP1 = U0 ∪ U1 where
z1
U0 = {[z0 : z1 ] | z0 6= 0} = {[1 : | z0 6= 0} = {[1 : w] | w ∈ C} ≃ S 1 − {∞},
z0
and
U1 = {[z0 : z1 ] | z1 6= 0} = {[
z0
: 1| z1 6= 0} = {[w : 1] | w ∈ C} ≃ S 1 − {0}.
z1
8
Then
τ01 = τ0 ◦ τ1−1 (w) = τ0 ([w : 1]) =
1
−1
, and τ10 = τ01
.
w
(2)
Complex tori We’ll study “genus” g of a compact Riemann surface M, the number
of “holes” of M. When g = 0, M is biholomorphic to CP1 . When g = 2, it is torus.
Geometrically, a torus can be “glued” as follows.
Gluing to construct a torus
Analytically, we let M = C as a topological space and
√
Γ = {g(z) = z + m1 + m2 −1, m1 , m2 ∈ Z}
as a subgroup of Aut(C). We define an equivalence relation: z ∼ ze if and only if √there is
some g ∈ Γ such that g(z) = ze. In other words, z ∼ ze if and only if z − ze = m1 + m2 −1 for
some integers m1 and m2 . We denote by [z] the equivalence class represented by z. Then
from the natural projection
π : M = C → M/Γ = C/ ∼, z 7→ [z],
we get a quotient space M/ ∼ or M/Γ, and we can define a quotient topology on M/Γ.
Namely, Û ⊂ M/Γ is open if and only if π −1 (Û) is open in M. Let
ν = {[U] = U/ ∼: U is open in M such that g(U) ∩ U = ∅ for g 6= Id, g ∈ Γ} .
Then ν forms a basis of the topology of M/Γ. We notice that the map πM → M/Γ is a
covering map.
Now, for any p ∈ M/Γ, p has a neighborhood [Up ] ⊂ ν. Then we have disjoint union
[
π −1 ([Up ]) =
g(Up ) and ,
g∈Γ
9
g(Up )
\
g ′ (Up ) 6= ∅ ⇔ g = g ′ .
Moreover, π|g(Up ) : g(Up ) → [Up ] is a homeomorphism. By regaring (π|g(Up ) )−1 as coordinate
map, it can be verified that the torus T := M/Γ is a complex manifold.
[Example]
example, let
In general, such “gluing process” may not produce a smooth manifold. For
2
g : C2 → C2 , (z1 , z2 ) 7→ (−z1 , −z2 )
(3)
2
be an element in Aut(C ). Then Γ = {g, Id} defines a subgroup. C /Γ is not a smooth
manifold.
In order to make quotient space a smooth manifold, we introduce some notions as follows.
Let M be a complex manifold of dimension n. Write
Aut(M) = {f : M → M, f biholomorphic}.
Then Aut(M) is a group under the composition law, called the automorphism group of M.
Let Γ ⊂ Aut(M) be a subgroup.
(i) Γ is called discrete if ∀p0 ∈ M, Γ(p0 ) = {r(p0 ) : r ∈ Γ} is a discrete subset.
(ii) Γ is said to be fixed point free if for any g ∈ Γ, g 6= id, g has no fixed point.
T
(iii) Γ is called properly discontinuous if for any K1 , K2 ⊂⊂ M, {r ∈ Γ : r(K1 ) K2 6= ∅}
is a finite set of Γ.
Theorem 1.2 8 Let M be a complex manifold and Γ ⊂ Aut(M) be a subgroup. If Γ is fixed
point free and properly discontinuous. M/Γ has a canonical structure of a complex maniofld
induced from that of M.
Going back to (3), when M = C2 and Γ = {g, Id} where g(z) = −z, we see that Γ is not
fixed point free because g(0, 0) = (0, 0) so that g has a fixed point (0, 0). In fact, consider a
Γ-invariant map (i.e., each component function is Γ invariant)
L : C2 → C3 , (z1 , z2 ) 7→ (z12 , z22 , z1 z2 ).
Notice L(z1 , z2 ) = L(e
z1 , ze2 ) if and only if either (z1 , z2 ) = (e
z1 , ze2 ) or (z1 , z2 ) = (−e
z1 , −e
z2 ). It
induces a quotient map
L : C2 /Γ → A = {(z1 , z2 , z3 ) ∈ C3 , z1 z2 = z32 }.
Here C2 /Γ can be identified with A which is a variety on C2 with singularity 0.
8
cf. K.Kodaira, Complex manifolds and deformation of complex structures, Spring-Verlag, 1985, theorem
2.2, p.44
10
2
De Rham Theorem and Dolbeault Theorem
Homology
For a topological space X, it can associates some invariant groups called
“homology groups” Hp (X) in the sense that if f : X → Y is a homeomorphism, it induces
a group isomorphism f∗ : Hp (X) → Hp (Y ), ∀p.
Let X be a topological space. A chain complex C(X) is a sequence of abelian groups or
modules with homomorphisms ∂n : Cn → Cn−1 which we call boundary operators. That is,
∂n+1
∂
∂n−1
∂
∂
∂
n
2
1
0
... −−−→ Cn −→
Cn−1 −−−→ ... −
→
C1 −
→
C0 −
→
0
where 0 denotes the trivial group and Cj = 0 for j < 0. We also require the composition of
any two consecutive boundary operators to be zero. That is, for all n,
This means im(∂n+1 ) ⊆ ker(∂n ).
∂n ◦ ∂n+1 = 0.
Now since each Cn is abelian, im(Cn ) is a normal subgroup of ker(Cn ). We define the
n-th homology group of X with respec to the chain complex C(X) to be the factor group
(or quotient module)
Hn (X) = ker(∂n )/im(∂n+1 )
We also use the notation Zn (X) := ker(∂n ) and Bn (X) := im(∂n+1 ), so
Hn (X) = Zn (X)/Bn (X).
The simplicial homology groups
Simplicial homology and singular homology 9
Hn (X) are defined by using the simplicial chain complex C(X), with C(X)n the free abelian
group generated by the n-simplices of X. Here an n-simplex is an n-dimensional polytope
which is the convex hull of its n + 1 vertices.
1-simplex, 2-simplex, 3-simplex, 4-simplex, and 5-simplex
9
cf., en.wikipedia.org: simplex, simplicial homology.
11
If σn = [p0 , ..., pn ], then
∂n σn :=
n
X
(−1)k [p0 , ..., pk−1 , pk+1, ...pn ].
k=0
We can verify that ∂n+1 ◦ ∂n = 0. For example, if σ = [p0 , p1 , p2 ] is a 2-simplex. ∂2 (σ) =
[p1 , p2 ] − [p0 , p2 ] + [p0 , p1 ] and ∂1 ◦ ∂2 (σ) = [p2 ] − [p1 ] − [p2 ] + [p0 ] + [p1 ] − [p0 ] = 0.
12