Mixed Hodge structure

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 ${\displaystyle H^k(X)}$ may have subspaces of different weights, i.e. as a direct sum of Hodge structures

${\displaystyle H^k(X)=\underset{i}{⨁}(H_i,F_i^{\bullet })}$

where each of the Hodge structures have weight ${\displaystyle k_i}$. One of the early hints that such structures should exist comes from the long exact sequence ${\displaystyle \dots \to H^{i-1}(Y)\to H_c^i(U)\to H^i(X)\to \dots }$associated to a pair of smooth projective varieties ${\displaystyle Y\subset X}$. This sequence suggests that the cohomology groups ${\displaystyle H_c^i(U)}$ (for ${\displaystyle U=X-Y}$) should have differing weights coming from both ${\displaystyle H^{i-1}(Y)}$ and ${\displaystyle H^i(X)}$.

Motivation

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.

Definition

A mixed Hodge structure^[1] (MHS) is a triple ${\displaystyle (H_{\mathbb{\mathbb{Z}}},W_{\bullet },F^{\bullet })}$ such that

1. ${\displaystyle H_{\mathbb{\mathbb{Z}}}}$ is a ${\displaystyle \mathbb{\mathbb{Z}}}$-module of finite type
2. ${\displaystyle W_{\bullet }}$ is an increasing ${\displaystyle \mathbb{\mathbb{Z}}}$-filtration on ${\displaystyle H_{\mathbb{\mathbb{Q}}}=H_{\mathbb{\mathbb{Z}}}\otimes \mathbb{\mathbb{Q}}}$, ${\displaystyle \cdots \subset W_0\subset W_1\subset W_2\subset \cdots }$
3. ${\displaystyle F^{\bullet }}$ is a decreasing ${\displaystyle \mathbb{\mathbb{N}}}$-filtration on ${\displaystyle H_{\mathbb{ℂ}}}$, ${\displaystyle H_{\mathbb{ℂ}}=F^0\supset F^1\supset F^2\supset \cdots }$

where the induced filtration of

on the graded pieces

${\displaystyle {\text{Gr}}^{W_{\bullet }}{H}_{\mathbb{\mathbb{Q}}}=\frac{W_k{H}_{\mathbb{\mathbb{Q}}}}{W_{k-1}{H}_{\mathbb{\mathbb{Q}}}}}$

are pure Hodge structures of weight

.

Remark on filtrations

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, ${\displaystyle H^{p,q}}$ where ${\displaystyle q>0}$, don't vary holomorphically. But, the filtrations can vary holomorphically, giving a better defined structure.

Morphisms of mixed Hodge structures

Morphisms of mixed Hodge structures are defined by maps of abelian groups

${\displaystyle f:(H_{\mathbb{\mathbb{Z}}},W_{\bullet },F^{\bullet })\to ({H_{\mathbb{\mathbb{Z}}}}^{\prime },{W_{\bullet }}^{\prime },F{\text{'}}^{\bullet })}$

such that

${\displaystyle f(W_l)\subset W{\text{'}}_l}$

and the induced map of

-vector spaces has the property

${\displaystyle f_{\mathbb{ℂ}}(F^p)\subset F{\text{'}}^p}$

Further definitions and properties

Hodge numbers

The Hodge numbers of a MHS are defined as the dimensions

${\displaystyle h^{p,q}(H_{\mathbb{\mathbb{Z}}})={\dim }_{\mathbb{ℂ}}{\text{Gr}}_{F^{\bullet }}^p{\text{Gr}}_{p+q}^{W_{\bullet }}{H}_{\mathbb{ℂ}}}$

since

is a weight

Hodge structure, and

${\displaystyle {\text{Gr}}_p^{F^{\bullet }}=\frac{F^p}{F^{p+1}}}$

is the

-component of a weight

Hodge structure.

Homological properties

There is an Abelian category^[2] of mixed Hodge structures which has vanishing

-groups whenever the cohomological degree is greater than

: that is, given mixed hodge structures

the groups

${\displaystyle {\mathrm{Ext}}_{MHS}^p((H_{\mathbb{\mathbb{Z}}},W_{\bullet },F^{\bullet }),({H_{\mathbb{\mathbb{Z}}}}^{\prime },{W_{\bullet }}^{\prime },F{\text{'}}^{\bullet }))=0}$

for

^{[2]pg 83}.

Mixed Hodge structures on bi-filtered complexes

Many mixed Hodge structures can be constructed from a bifiltered complex. This includes complements of smooth varieties defined by the complement of a normal crossing variety. Given a complex of sheaves of abelian groups

and filtrations

^[1] of the complex, meaning

${\displaystyle \begin{array}{rl}d(W_i{A}^{\bullet })& \subset W_i{A}^{\bullet }\\ d(F^i{A}^{\bullet })& \subset F^i{A}^{\bullet }\end{array}}$

There is an induced mixed Hodge structure on the hyperhomology groups

${\displaystyle ({\mathbb{ℍ}}^k(X,A^{\bullet }),W_{\bullet },F^{\bullet })}$

from the bi-filtered complex

. Such a bi-filtered complex is called a mixed Hodge complex^[1]: 23

Logarithmic complex

Given a smooth variety

where

is a normal crossing divisor (meaning all intersections of components are complete intersections), there are filtrations on the logarithmic de Rham complex

given by

${\displaystyle \begin{array}{rl}{W}_m{\mathrm{\Omega }}_X^i(\log D)& =\{\begin{array}{ll}{\mathrm{\Omega }}_X^i(\log D)& \text{ if }i\le m\\ {\mathrm{\Omega }}_X^{i-m}\wedge {\mathrm{\Omega }}_X^m(\log D)& \text{ if }0\le m\le i\\ 0& \text{ if }m<0\end{array}\\ F^p{\mathrm{\Omega }}_X^i(\log D)& =\{\begin{array}{ll}{\mathrm{\Omega }}_X^i(\log D)& \text{ if }p\le i\\ 0& \text{ otherwise}\end{array}\end{array}}$

It turns out these filtrations define a natural mixed Hodge structure on the cohomology group

from the mixed Hodge complex defined on the logarithmic complex

.

Smooth compactifications

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

is defined as a smooth variety

and an embedding

such that

is a normal crossing divisor. That is, given compactifications

with boundary divisors

there is an isomorphism of mixed Hodge structure

${\displaystyle ({\mathbb{ℍ}}^k(X,{\mathrm{\Omega }}_X^{\bullet }(\log D)),W_{\bullet },F^{\bullet })\cong ({\mathbb{ℍ}}^k(X^{\prime },{\mathrm{\Omega }}_{X^{\prime }}^{\bullet }(\log D^{\prime })),W_{\bullet },F^{\bullet })}$

showing the mixed Hodge structure is invariant under smooth compactification.^[2]

Example

For example, on a genus

plane curve

logarithmic cohomology of

with the normal crossing divisor

with

can be easily computed^[3] since the terms of the complex

equal to

${\displaystyle {{𝒪}}_C\stackrel{d}{\to }{\mathrm{\Omega }}_C^1(\log D)}$

are both acyclic. Then, the Hypercohomology is just

${\displaystyle \mathrm{\Gamma }({{𝒪}}_{{\mathbb{\mathbb{P}}}^1})\stackrel{d}{\to }\mathrm{\Gamma }({\mathrm{\Omega }}_{{\mathbb{\mathbb{P}}}^1}(\log D))}$

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

${\displaystyle \mathbb{ℂ}\cdot \frac{dx}{x-p_1}\oplus \cdots \oplus \mathbb{ℂ}\frac{dx}{x-p_{k-1}}}$

Then

has a weight

mixed Hodge structure and

has a weight

mixed Hodge structure.

Examples

Complement of a smooth projective variety by a closed subvariety

Given a smooth projective variety

of dimension

and a closed subvariety

there is a long exact sequence in cohomology^[4]pg7-8

${\displaystyle \cdots \to H_c^m(U;\mathbb{\mathbb{Z}})\to H^m(X;\mathbb{\mathbb{Z}})\to H^m(Y;\mathbb{\mathbb{Z}})\to H_c^{m+1}(U;\mathbb{\mathbb{Z}})\to \cdots }$

coming from the distinguished triangle

${\displaystyle \mathbf{R}{j}_{!}{\mathbb{\mathbb{Z}}}_U\to {\mathbb{\mathbb{Z}}}_X\to i_{*}{\mathbb{\mathbb{Z}}}_Y\stackrel{[+1]}{\to }}$

of constructible sheaves. There is another long exact sequence

${\displaystyle \cdots \to H_{2n-m}^{BM}(Y;\mathbb{\mathbb{Z}})(-n)\to H^m(X;\mathbb{\mathbb{Z}})\to H^m(U;\mathbb{\mathbb{Z}})\to H_{2n-m-1}^{BM}(Y;\mathbb{\mathbb{Z}})(-n)\to \cdots }$

from the distinguished triangle

${\displaystyle i_{*}{i}^{!}{\mathbb{\mathbb{Z}}}_X\to {\mathbb{\mathbb{Z}}}_X\to \mathbf{R}{j}_{*}{\mathbb{\mathbb{Z}}}_U\stackrel{[+1]}{\to }}$

whenever

is smooth. Note the homology groups

are called Borel–Moore homology, which are dual to cohomology for general spaces and the

means tensoring with the Tate structure

add weight

to the weight filtration. The smoothness hypothesis is required because Verdier duality implies

, and

whenever

is smooth. Also, the dualizing complex for

has weight

, hence

. Also, the maps from Borel-Moore homology must be twisted by up to weight

is order for it to have a map to

. Also, there is the perfect duality pairing

${\displaystyle H_{2n-m}^{BM}(Y)\times H^m(Y)\to \mathbb{\mathbb{Z}}}$

giving an isomorphism of the two groups.

Algebraic torus

A one dimensional algebraic torus

is isomorphic to the variety

, hence its cohomology groups are isomorphic to

${\displaystyle \begin{array}{rl}{H}^0(\mathbb{𝕋})\oplus H^1(\mathbb{𝕋})& \cong \mathbb{\mathbb{Z}}\oplus \mathbb{\mathbb{Z}}\end{array}}$

The long exact exact sequence then reads

${\displaystyle \begin{array}{cc}& H_2^{BM}(Y)(-1)\to H^0({\mathbb{\mathbb{P}}}^1)\to H^0({\mathbb{𝔾}}_m)\to \\ & H_1^{BM}(Y)(-1)\to H^1({\mathbb{\mathbb{P}}}^1)\to H^1({\mathbb{𝔾}}_m)\to \\ & H_0^{BM}(Y)(-1)\to H^2({\mathbb{\mathbb{P}}}^1)\to H^2({\mathbb{𝔾}}_m)\to 0\end{array}}$

Since

and

this gives the exact sequence

${\displaystyle 0\to H^1({\mathbb{𝔾}}_m)\to H_0^{BM}(Y)(-1)\to H^2({\mathbb{\mathbb{P}}}^1)\to 0}$

since there is a twisting of weights for well-defined maps of mixed Hodge structures, there is the isomorphism

${\displaystyle H^1({\mathbb{𝔾}}_m)\cong \mathbb{\mathbb{Z}}(-1)}$

Quartic K3 surface minus a genus 3 curve

Given a quartic K3 surface

, and a genus 3 curve

defined by the vanishing locus of a generic section of

, hence it is isomorphic to a degree

plane curve, which has genus 3. Then, the Gysin sequence gives the long exact sequence

${\displaystyle \to H^{k-2}(C)\stackrel{{\gamma }_k}{\to }{H}^k(X)\stackrel{i^{*}}{\to }{H}^k(U)\stackrel{R}{\to }{H}^{k-1}(C)\to }$

But, it is a result that the maps

take a Hodge class of type

to a Hodge class of type

.^[5] The Hodge structures for both the K3 surface and the curve are well-known, and can be computed using the Jacobian ideal. In the case of the curve there are two zero maps

${\displaystyle {\gamma }_3:H^{1,0}(C)\to H^{2,1}(X)=0}$ ${\displaystyle {\gamma }_3:H^{0,1}(C)\to H^{1,2}(X)=0}$

hence

contains the weight one pieces

. Because

has dimension

, but the Leftschetz class

is killed off by the map

${\displaystyle {\gamma }_2:H^0(C)\to H^2(X)}$

sending the

class in

to the

class in

. Then the primitive cohomology group

is the weight 2 piece of

. Therefore,

${\displaystyle \begin{array}{rl}{\text{Gr}}_2^{W_{\bullet }}{H}^2(U)& =H_{\text{prim}}^2(X)\\ {\text{Gr}}_1^{W_{\bullet }}{H}^2(U)& =H^1(C)\\ {\text{Gr}}_k^{W_{\bullet }}{H}^2(U)& =0& k\ne 1,2\end{array}}$

The induced filtrations on these graded pieces are the Hodge filtrations coming from each cohomology group.

See also

• Motive (algebraic geometry)
• Jacobian ideal
• Milnor fiber
• Mixed Hodge module

References

• Filippini, Sara Angela; Ruddat, Helge; Thompson, Alan (2015). "An Introduction to Hodge Structures". Calabi-Yau Varieties: Arithmetic, Geometry and Physics. Fields Institute Monographs. Vol. 34. pp. 83–130. arXiv:1412.8499. doi:10.1007/978-1-4939-2830-9_4. ISBN 978-1-4939-2829-3. S2CID 119696589.

Examples

• A Naive Guide to Mixed Hodge Theory
• Introduction to Limit Mixed Hodge Structures
• Deligne’s Mixed Hodge Structure for Projective Varieties with only Normal Crossing Singularities

In Mirror Symmetry

• Local B-Model and Mixed Hodge Structure