In algebraic geometry, a branch of mathematics, Serre duality is a duality for the coherent sheaf cohomology of algebraic varieties, proved by Jean-Pierre Serre. The basic version applies to vector bundles on a smooth projective variety, but Alexander Grothendieck found wide generalizations, for example to singular varieties. On an n-dimensional variety, the theorem says that a cohomology group
Hi
Hn-i
The Serre duality theorem is also true in complex geometry more generally, for compact complex manifolds that are not necessarily projective complex algebraic varieties. In this setting, the Serre duality theorem is an application of Hodge theory for Dolbeault cohomology, and may be seen as a result in the theory of elliptic operators.
These two different interpretations of Serre duality coincide for non-singular projective complex algebraic varieties, by an application of Dolbeault's theorem relating sheaf cohomology to Dolbeault cohomology.
Let X be a smooth variety of dimension n over a field k. Define the canonical line bundle
KX
| n(T | |
| K | |
| X={wedge} |
*X).
Hi(X,E)\congHn-i(X,KX ⊗ E\ast)\ast
⊗
hi(X,E)=hn-i(X,KX ⊗ E\ast).
| n(X,K | |
| H | |
| X) |
Hi(X,E) x Hn-i(X,KX ⊗ E\ast)\to
| n(X,K | |
| H | |
| X)\to |
k.
Serre also proved the same duality statement for X a compact complex manifold and E a holomorphic vector bundle.[2] Here, the Serre duality theorem is a consequence of Hodge theory. Namely, on a compact complex manifold
X
\star:\Omegap(X)\to\Omega2n-p(X),
where
\dimCX=n
X
(p,q)
\star:\Omegap,q(X)\to\Omegan-q,n-p(X).
Notice that the holomorphic and anti-holomorphic indices have switched places. There is a conjugation on complex differential forms which interchanges forms of type
(p,q)
(q,p)
\bar{\star}\omega=\star\bar{\omega}
\bar{\star}:\Omegap,q(X)\to\Omegan-p,n-q(X).
L2
\langle\alpha,\beta
| \rangle | |
| L2 |
=\intX\alpha\wedge\bar{\star}\beta,
where now
\alpha\wedge\bar{\star}\beta
(n,n)
2n
X
(E,h)
h
E\congE*
E
\tau:E\toE*
\bar{\star}E(\omega ⊗ s)=\bar{\star}\omega ⊗ \tau(s)
\bar{\star}E:\Omegap,q(X,E)\to\Omegan-p,n-q(X,E*)
where
\Omegap,q(X,E)=\Omegap,q(X) ⊗ \Gamma(E)
E
E
E*
\tau
h
L2
E
\langle\alpha,\beta
| \rangle | |
| L2 |
=\intX\alpha\wedgeh\bar{\star}E\beta,
where here
\wedgeh
E
E*
h
The Hodge theorem for Dolbeault cohomology asserts that if we define:
\Delta\bar{\partialE}=
| * | |
| \bar{\partial} | |
| E |
\bar{\partial}E+\bar{\partial}E
| * | |
| \bar{\partial} | |
| E |
where
\bar{\partial}E
E
| * | |
| \bar{\partial} | |
| E |
Hp,q(X,E)\cong
| p,q | |
| l{H} | |
| \Delta\bar{\partialE |
On the left is Dolbeault cohomology, and on the right is the vector space of harmonic
E
| p,q | |
| l{H} | |
| \Delta\bar{\partialE |
\bar{\star}E
Hp,q(X,E)\congHn-p,n-q(X,E*)*.
This can be easily proved using the Hodge theory above. Namely, if
[\alpha]
Hp,q(X,E)
\alpha\in
| p,q | |
| l{H} | |
| \Delta\bar{\partialE |
(\alpha,\bar{\star}E\alpha)=\langle\alpha,\alpha
| \rangle | |
| L2 |
\ge0
with equality if and only if
\alpha=0
(\alpha,\beta)=\intX\alpha\wedgeh\beta
between
| p,q | |
| l{H} | |
| \Delta\bar{\partialE |
| n-p,n-q | |||||||||||
| l{H} | |||||||||||
|
The statement of Serre duality in the algebraic setting may be recovered by taking
p=0
Hp,q(X,E)\congHq(X,\boldsymbol{\Omega}p ⊗ E)
where on the left is Dolbeault cohomology and on the right sheaf cohomology, where
\boldsymbol{\Omega}p
(p,0)
Hq(X,E)\congH0,q(X,E)\congHn,n-q(X,E*)*\congHn-q(X,KX ⊗ E*)*
where we have used that the sheaf of holomorphic
(n,0)
X
A fundamental application of Serre duality is to algebraic curves. (Over the complex numbers, it is equivalent to consider compact Riemann surfaces.) For a line bundle L on a smooth projective curve X over a field k, the only possibly nonzero cohomology groups are
H0(X,L)
H1(X,L)
H1
H0
H0
Serre duality is especially relevant to the Riemann–Roch theorem for curves. For a line bundle L of degree d on a curve X of genus g, the Riemann–Roch theorem says that:
h0(X,L)-h1(X,L)=d-g+1.
h0(X,L)-h
| 0(X,K | |
| X ⊗ |
L*)=d-g+1.
Example: Every global section of a line bundle of negative degree is zero. Moreover, the degree of the canonical bundle is
2g-2
d>2g-2
h0(X,L)
d-g+1
h1(X,TX)=h
| ⊗ 2 | |
| X |
)=3g-3
H1(X,TX)
3g-3
Another formulation of Serre duality holds for all coherent sheaves, not just vector bundles. As a first step in generalizing Serre duality, Grothendieck showed that this version works for schemes with mild singularities, Cohen–Macaulay schemes, not just smooth schemes.
Namely, for a Cohen–Macaulay scheme X of pure dimension n over a field k, Grothendieck defined a coherent sheaf
\omegaX
KX
| i | |
| \operatorname{Ext} | |
| X(E,\omega |
X)\congHn-i(X,E)*
OX
| i | |
| \operatorname{Ext} | |
| X(E,\omega |
X)
Hi(X,E* ⊗ \omegaX)
In order to use this result, one has to determine the dualizing sheaf explicitly, at least in special cases. When X is smooth over k,
\omegaX
KX
| r | |
| \omega | |
| OY |
(OX,KY).
\omegaX\congKY|X ⊗
| r(N | |
| {wedge} | |
| X/Y |
).
\omegaX
Example: Let X be a complete intersection in projective space
{P}n
f1,\ldots,fr
d1,\ldots,dr
n-r
{P}n
\omegaX=O(d1+ … +dr-n-1)|X,
by the adjunction formula. For example, the dualizing sheaf of a plane curve X of degree d is
O(d-3)|X
In particular, we can compute the number of complex deformations, equal to
\dim(H1(X,TX))
P4
KX\congl{O}X
H1(X,TX)\congH2(X,l{O}X ⊗ \OmegaX)\congH2(X,\OmegaX)
h2,1
See main article: Coherent duality. Grothendieck's theory of coherent duality is a broad generalization of Serre duality, using the language of derived categories. For any scheme X of finite type over a field k, there is an object
| \bullet | |
| \omega | |
| X |
| b | |
| D | |
| \operatorname{coh |
| \bullet | |
| \omega | |
| X |
| !O | |
| f | |
| Y |
X\toY=\operatorname{Spec}(k)
| \bullet | |
| \omega | |
| X |
\omegaX[n]
| \bullet | |
| \omega | |
| X |
Using the dualizing complex, Serre duality generalizes to any proper scheme X over k. Namely, there is a natural isomorphism of finite-dimensional k-vector spaces:
\operatorname{Hom}X(E,\omega
| \bullet | |
| X |
)\cong\operatorname{Hom}X(O
| * | |
| X,E) |
| b | |
| D | |
| \operatorname{coh |
More generally, for a proper scheme X over k, an object E in
| b | |
| D | |
| \operatorname{coh |
D\operatorname{perf
\operatorname{Hom}X(E,F ⊗
| \bullet | |
| \omega | |
| X |
| *. | |
| )\cong\operatorname{Hom} | |
| X(F,E) |
| i | |
| \operatorname{Ext} | |
| X(E,\omega |
X)
\operatorname{Hom}X(E,\omegaX[i])
| b | |
| D | |
| \operatorname{coh |
| b | |
| D | |
| \operatorname{coh |
F\mapstoF ⊗
| \bullet | |
| \omega | |
| X |
| b | |
| D | |
| \operatorname{coh |
Serre duality holds more generally for proper algebraic spaces over a field.[9]