Coherent duality explained

In mathematics, coherent duality is any of a number of generalisations of Serre duality, applying to coherent sheaves, in algebraic geometry and complex manifold theory, as well as some aspects of commutative algebra that are part of the 'local' theory.

The historical roots of the theory lie in the idea of the adjoint linear system of a linear system of divisors in classical algebraic geometry. This was re-expressed, with the advent of sheaf theory, in a way that made an analogy with Poincaré duality more apparent. Then according to a general principle, Grothendieck's relative point of view, the theory of Jean-Pierre Serre was extended to a proper morphism; Serre duality was recovered as the case of the morphism of a non-singular projective variety (or complete variety) to a point. The resulting theory is now sometimes called Serre–Grothendieck–Verdier duality, and is a basic tool in algebraic geometry. A treatment of this theory, Residues and Duality (1966) by Robin Hartshorne, became a reference. One concrete spin-off was the Grothendieck residue.

To go beyond proper morphisms, as for the versions of Poincaré duality that are not for closed manifolds, requires some version of the compact support concept. This was addressed in SGA2 in terms of local cohomology, and Grothendieck local duality; and subsequently. The Greenlees–May duality, first formulated in 1976 by Ralf Strebel and in 1978 by Eben Matlis, is part of the continuing consideration of this area.

Adjoint functor point of view

While Serre duality uses a line bundle or invertible sheaf as a dualizing sheaf, the general theory (it turns out) cannot be quite so simple. (More precisely, it can, but at the cost of imposing the Gorenstein ring condition.) In a characteristic turn, Grothendieck reformulated general coherent duality as the existence of a right adjoint functor

f^!

, called twisted or exceptional inverse image functor, to a higher direct image with compact support functor

Rf_!

Higher direct images are a sheafified form of sheaf cohomology in this case with proper (compact) support; they are bundled up into a single functor by means of the derived category formulation of homological algebra (introduced with this case in mind). If

is proper, then

Rf_!=Rf_\ast

is a right adjoint to the inverse image functor

f^\ast

. The existence theorem for the twisted inverse image is the name given to the proof of the existence for what would be the counit for the comonad of the sought-for adjunction, namely a natural transformation

Rf_!f^! → id

which is denoted by

Tr_f

(Hartshorne) or

\int_f

(Verdier). It is the aspect of the theory closest to the classical meaning, as the notation suggests, that duality is defined by integration.

To be more precise,

f^!

exists as an exact functor from a derived category of quasi-coherent sheaves on

, to the analogous category on

, whenever

f:X → Y

is a proper or quasi projective morphism of noetherian schemes, of finite Krull dimension.^[1] From this the rest of the theory can be derived: dualizing complexes pull back via

f^!

, the Grothendieck residue symbol, the dualizing sheaf in the Cohen–Macaulay case.

In order to get a statement in more classical language, but still wider than Serre duality, Hartshorne (Algebraic Geometry) uses the Ext functor of sheaves; this is a kind of stepping stone to the derived category.

The classical statement of Grothendieck duality for a projective or proper morphism

f:X → Y

of noetherian schemes of finite dimension, found in Hartshorne (Residues and duality) is the following quasi-isomorphism

Rf_\ast

	\bullet,f
RHom
	X(F

^!G^\bullet)\toRHom_Y(Rf_\astF^\bullet,G^\bullet)

for

F^\bullet

a bounded above complex of

O_X

-modules with quasi-coherent cohomology and

G^\bullet

a bounded below complex of

O_Y

-modules with coherent cohomology. Here the

Hom

's are sheaves of homomorphisms.

Construction of the f^! pseudofunctor using rigid dualizing complexes

Over the years, several approaches for constructing the

f^!

pseudofunctor emerged. One quite recent successful approach is based on the notion of a rigid dualizing complex. This notion was first defined by Van den Bergh in a noncommutative context.^[2] The construction is based on a variant of derived Hochschild cohomology (Shukla cohomology): Let

be a commutative ring, and let

be a commutative

algebra. There is a functor

RHom

	L
A ⊗		A
	k

	L
(A,M ⊗
	k

which takes a cochain complex

to an object

RHom

	L
A ⊗		A
	k

	L
(A,M ⊗
	k

in the derived category over

.^[3] ^[4]

Assuming

is noetherian, a rigid dualizing complex over

relative to

is by definition a pair

(R,\rho)

where

is a dualizing complex over

which has finite flat dimension over

, and where

\rho:R\to

RHom

	L
A ⊗		A
	k

	L
(A,R ⊗
	k

is an isomorphism in the derived category

D(A)

. If such a rigid dualizing complex exists, then it is unique in a strong sense.^[5]

Assuming

is a localization of a finite type

-algebra, existence of a rigid dualizing complex over

relative to

was first proved by Yekutieli and Zhang^[6] assuming

is a regular noetherian ring of finite Krull dimension, and by Avramov, Iyengar and Lipman^[7] assuming

is a Gorenstein ring of finite Krull dimension and

is of finite flat dimension over

is a scheme of finite type over

, one can glue the rigid dualizing complexes that its affine pieces have,^[8] and obtain a rigid dualizing complex

R_X

. Once one establishes a global existence of a rigid dualizing complex, given a map

f:X\toY

of schemes over

, one can define

f^!:=D_X\circLf^*\circD_Y

, where for a scheme

, we set

D_X:=RHom_l{O_X}(-,R_X)

Dualizing Complex Examples

Dualizing Complex for a Projective Variety

The dualizing complex for a projective variety

X\subsetPⁿ

is given by the complex

	\bullet
\omega
	X

RHom
	Pⁿ

(l{O}_X,\omega


	Pⁿ

[+n])

^[9]

Plane Intersecting a Line

Consider the projective variety

X=Proj\left(

	C[x,y,z,w]
	(x)(y,z)

\right)=Proj\left(

	C[x,y,z,w]
	(xy,xz)

\right)

We can compute

RHom
	P³

(l{O}_X,\omega


	P³

[+3])

using a resolution

l{L}^\bullet\tol{O}_X

by locally free sheaves. This is given by the complex

0\tol{O}(-3)\xrightarrow{\begin{bmatrix}z\ -y\end{bmatrix}}l{O}(-2) ⊕ l{O}(-2)\xrightarrow{\begin{bmatrix}xy&xz\end{bmatrix}}l{O}\tol{O}_X\to0

Since

\omega
	P³

\congl{O}(-4)

we have that

	\bullet
\omega
	X

RHom
	P³

(l{L}^\bullet,l{O}(-4)[+3])=

RHom
	P³

(l{L}^{\bullet ⊗}l{O}(4)[-3],l{O})

This is the complex

[l{O}(-4)\xrightarrow{\begin{bmatrix}xy\ xz\end{bmatrix}}l{O}(-2) ⊕ l{O}(-2) \xrightarrow{\begin{bmatrix}z&-y\end{bmatrix}}l{O}(-1)][-3]

Notes

, an elegant and more general approach was found by Amnon Neeman, by using methods from algebraic topology notably Brown representability, see
van den Bergh. Michel. Existence Theorems for Dualizing Complexes over Non-commutative Graded and Filtered Rings. Journal of Algebra. September 1997. 195. 2. 662–679. 10.1006/jabr.1997.7052. free.
Yekutieli . Amnon. The Squaring Operation for Commutative DG Rings. 2016. 1412.4229. Journal of Algebra. 449. 50–107. 10.1016/j.jalgebra.2015.09.038 . free.
Avramov. Luchezar L.. Iyengar. Srikanth B.. Lipman. Joseph. Nayak. Suresh. Reduction of derived Hochschild functors over commutative algebras and schemes. Advances in Mathematics. January 2010. 223. 2. 735–772. 10.1016/j.aim.2009.09.002. free. 0904.4004. 15218584.
Yekutieli. Amnon. Zhang. James J.. Rigid Dualizing Complexes Over Commutative Rings. Algebras and Representation Theory. 31 May 2008. 12. 1. 19–52. 10.1007/s10468-008-9102-9. math/0601654. 13597155.
Yekutieli. Amnon. Zhang. James J.. Rigid Dualizing Complexes Over Commutative Rings. Algebras and Representation Theory. 31 May 2008. 12. 1. 19–52. 10.1007/s10468-008-9102-9. math/0601654. 13597155.
Avramov. Luchezar. Iyengar. Srikanth. Lipman. Joseph. Reflexivity and rigidity for complexes, I: Commutative rings. Algebra & Number Theory. 14 January 2010. 4. 1. 47–86. 10.2140/ant.2010.4.47. 0904.4695. 18255441.
Avramov. Luchezar. Iyengar. Srikanth. Lipman. Joseph. Reflexivity and rigidity for complexes, II: Schemes. Algebra & Number Theory. 10 September 2011. 5. 3. 379–429. 10.2140/ant.2011.5.379. 1001.3450. 21639634.
Web site: Kovacs. Sandor. Singularities of stable varieties. https://web.archive.org/web/20170822172544/https://sites.math.washington.edu/~kovacs/2013/papers/Kovacs__Singularities_of_stable_varieties.pdf. 2017-08-22.

Coherent duality explained

Adjoint functor point of view

Construction of the f! pseudofunctor using rigid dualizing complexes

Dualizing Complex Examples

Dualizing Complex for a Projective Variety

Plane Intersecting a Line

See also

Notes

Construction of the f^! pseudofunctor using rigid dualizing complexes