In algebraic geometry, a mixed Hodge structure is an algebraic structure containing information about the cohomology of general algebraic varieties. It is a generalization of a Hodge structure, which is used to study smooth projective varieties.
In mixed Hodge theory, where the decomposition of a cohomology group
Hk(X)
Hk(X)=oplusi(Hi,
| \bullet) | |
| F | |
| i |
ki
...\toHi-1(Y)\to
| i | |
| H | |
| c(U) |
\toHi(X)\to...
Y\subsetX
| i | |
| H | |
| c(U) |
U=X-Y
Hi-1(Y)
Hi(X)
Originally, Hodge structures were introduced as a tool for keeping track of abstract Hodge decompositions on the cohomology groups of smooth projective algebraic varieties. These structures gave geometers new tools for studying algebraic curves, such as the Torelli theorem, Abelian varieties, and the cohomology of smooth projective varieties. One of the chief results for computing Hodge structures is an explicit decomposition of the cohomology groups of smooth hypersurfaces using the relation between the Jacobian ideal and the Hodge decomposition of a smooth projective hypersurface through Griffith's residue theorem. Porting this language to smooth non-projective varieties and singular varieties requires the concept of mixed Hodge structures.
A mixed Hodge structure[1] (MHS) is a triple
(HZ,W\bullet,F\bullet)
HZ
Z
W\bullet
Z
HQ=HZ ⊗ Q
… \subsetW0\subsetW1\subsetW2\subset …
F\bullet
N
HC
HC=F0\supsetF1\supsetF2\supset …
where the induced filtration of
F\bullet
are pure Hodge structures of weight
W\bullet Gr HQ=
WkHQ Wk-1HQ
k
Note that similar to Hodge structures, mixed Hodge structures use a filtration instead of a direct sum decomposition since the cohomology groups with anti-holomorphic terms,
Hp,q
q>0
Morphisms of mixed Hodge structures are defined by maps of abelian groups
such thatf:(HZ,W\bullet,F\bullet)\to(HZ',W\bullet',F'\bullet)
and the induced map off(Wl)\subsetW'l
C
p) f C(F \subsetF'p
The Hodge numbers of a MHS are defined as the dimensions
sincehp,q(HZ)=\dimCGr
W\bullet p+q HC
| W\bullet | |
| Gr | |
| p+q |
HC
(p+q)
is the
F\bullet Gr p =
Fp Fp+1
(p,q)
(p+q)
There is an Abelian category of mixed Hodge structures which has vanishing
Ext
1
(HZ,W\bullet,F\bullet),(HZ',W\bullet',F'\bullet)
for
p((H \operatorname{Ext} Z,W \bullet,F\bullet),(HZ',W\bullet',F'\bullet))=0
p\geq2
A\bullet
W\bullet,F\bullet
There is an induced mixed Hodge structure on the hyperhomology groups
\bullet) \begin{align} d(W iA &\subset
\bullet W iA \\ d(FiA\bullet)&\subsetFiA\bullet \end{align}
from the bi-filtered complex(Hk(X,A\bullet),W\bullet,F\bullet)
(A\bullet,W\bullet,F\bullet)
Given a smooth variety
U\subsetX
D=X-U
| \bullet(log | |
| \Omega | |
| X |
D)
It turns out these filtrations define a natural mixed Hodge structure on the cohomology group
i \begin{align} W X(log D)&=
i(log \begin{cases} \Omega X D)&ifi\leqm
i-m \\ \Omega X \wedge
m(log \Omega X D)&if0\leqm\leqi\\ 0&ifm<0 \end{cases}\\[6pt] Fp\Omega
i X(log D)&=
i(log \begin{cases} \Omega X D)&ifp\leqi\\ 0&otherwise \end{cases} \end{align}
Hn(U,C)
| \bullet(log | |
| \Omega | |
| X |
D)
The above construction of the logarithmic complex extends to every smooth variety; and the mixed Hodge structure is isomorphic under any such compactificaiton. Note a smooth compactification of a smooth variety
U
X
U\hookrightarrowX
D=X-U
U\subsetX,X'
D=X-U,D'=X'-U
showing the mixed Hodge structure is invariant under smooth compactification.
\bullet(log (H X D)),W\bullet,F\bullet) \cong(H
\bullet(log X' D')),W\bullet,F\bullet)
For example, on a genus
0
C
C
\{p1,\ldots,pk\}
k\geq1
| \bullet(log | |
| \Omega | |
| C |
D)
are both acyclic. Then, the Hypercohomology is justl{O}C\xrightarrow{d}
1(log \Omega C D)
the first vector space are just the constant sections, hence the differential is the zero map. The second is the vector space is isomorphic to the vector space spanned by
\Gamma(l{O} P1 )\xrightarrow{d}
\Gamma(\Omega P1 (logD))
ThenC ⋅
dx x-p1 ⊕ … ⊕ C
dx x-pk-1
| 1(log | |
| H | |
| C |
D))
2
| 1(log | |
| H | |
| C |
D))
0
Given a smooth projective variety
X
n
Y\subsetX
coming from the distinguished triangle… \to
m H c(U;Z) \toHm(X;Z)\toHm(Y;Z)\to
m+1 H c(U;Z) \to …
of constructible sheaves. There is another long exact sequenceRj!ZU\toZX\toi*ZY\xrightarrow{[+1]}
from the distinguished triangle… \to
BM H 2n-m (Y;Z)(-n)\toHm(X;Z)\toHm(U;Z) \to
BM H 2n-m-1 (Y;Z)(-n)\to …
whenever
!Z i X \toZX\toRj*ZU\xrightarrow{[+1]}
X
| BM | |
| H | |
| k(X) |
(n)
Z(1) ⊗
-2n
| !D | |
| i | |
| X |
=DY
DX\congZX[2n]
X
X
n
DX\congZX[2n](n)
(n)
Hm(X)
giving an isomorphism of the two groups.
BM H 2n-m (Y) x Hm(Y)\toZ
A one dimensional algebraic torus
T
P1-\{0,infty\}
The long exact exact sequence then reads\begin{align} H0(T) ⊕ H1(T)&\congZ ⊕ Z \end{align}
Since
BM \begin{matrix} &H 2 (Y)(-1)\toH0(P1)\to
0(G H m) \to
BM \\ &H 1 (Y)(-1)\toH1(P1)\to
1(G H m) \to
BM \\ &H 0 (Y)(-1)\toH2(P1)\to
2(G H m) \to0 \end{matrix}
H1(P1)=0
| 2(G | |
| H | |
| m) |
=0
since there is a twisting of weights for well-defined maps of mixed Hodge structures, there is the isomorphism0\to
1(G H m) \to
BM H 0 (Y)(-1)\toH2(P1)\to0
1(G H m) \congZ(-1)
X
i:C\hookrightarrowX
l{O}X(1)
4
But, it is a result that the maps\toHk-2(C)\xrightarrow{\gammak}Hk(X)\xrightarrow{i*}Hk(U)\xrightarrow{R}Hk-1(C)\to
\gammak
(p,q)
(p+1,q+1)
hence
1,0 \gamma 3:H (C)\toH2,1(X)=0
0,1 \gamma 3:H (C)\toH1,2(X)=0
H2(U)
H1,0(C) ⊕ H0,1(C)
H2(X)=
| 2 | |
| H | |
| prim(X) ⊕ |
C ⋅ L
22
L
sending the
0(C) \gamma 2:H \toH2(X)
(0,0)
H0(C)
(1,1)
H2(X)
| 2 | |
| H | |
| prim(X) |
H2(U)
The induced filtrations on these graded pieces are the Hodge filtrations coming from each cohomology group.
W\bullet \begin{align} Gr 2 H2(U)&=
2 H prim(X)\\ Gr
W\bullet 1 H2(U)&=H1(C)
W\bullet \\ Gr k H2(U)&=0&k ≠ 1,2 \end{align}