Algebraic theorem edit

Let X be a smooth variety of dimension n over a field k. Define the canonical line bundle ${\displaystyle K_{X}}$  to be the bundle of n-forms on X, the top exterior power of the cotangent bundle:

${\displaystyle K_{X}=\Omega _{X}^{n}={\bigwedge }^{n}(T^{*}X).}$ 

Suppose in addition that X is proper (for example, projective) over k. Then Serre duality says: for an algebraic vector bundle E on X and an integer i, there is a natural isomorphism:

${\displaystyle H^{i}(X,E)\cong H^{n-i}(X,K_{X}\otimes E^{\ast })^{\ast }}$ 

of finite-dimensional k-vector spaces. Here ${\displaystyle \otimes }$  denotes the tensor product of vector bundles. It follows that the dimensions of the two cohomology groups are equal:

${\displaystyle h^{i}(X,E)=h^{n-i}(X,K_{X}\otimes E^{\ast }).}$ 

As in Poincaré duality, the isomorphism in Serre duality comes from the cup product in sheaf cohomology. Namely, the composition of the cup product with a natural trace map on ${\displaystyle H^{n}(X,K_{X})}$  is a perfect pairing:

${\displaystyle H^{i}(X,E)\times H^{n-i}(X,K_{X}\otimes E^{\ast })\to H^{n}(X,K_{X})\to k.}$ 

The trace map is the analog for coherent sheaf cohomology of integration in de Rham cohomology.^[1]

Differential-geometric theorem edit

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 ${\displaystyle X}$  equipped with a Riemannian metric, there is a Hodge star operator:

${\displaystyle \star :\Omega ^{p}(X)\to \Omega ^{2n-p}(X),}$ 

where ${\displaystyle \dim _{\mathbb {C} }X=n}$ . Additionally, since ${\displaystyle X}$  is complex, there is a splitting of the complex differential forms into forms of type ${\displaystyle (p,q)}$ . The Hodge star operator (extended complex-linearly to complex-valued differential forms) interacts with this grading as:

${\displaystyle \star :\Omega ^{p,q}(X)\to \Omega ^{n-q,n-p}(X).}$ 

Notice that the holomorphic and anti-holomorphic indices have switched places. There is a conjugation on complex differential forms which interchanges forms of type ${\displaystyle (p,q)}$  and ${\displaystyle (q,p)}$ , and if one defines the conjugate-linear Hodge star operator by ${\displaystyle {\bar {\star }}\omega =\star {\bar {\omega }}}$  then we have:

${\displaystyle {\bar {\star }}:\Omega ^{p,q}(X)\to \Omega ^{n-p,n-q}(X).}$ 

Using the conjugate-linear Hodge star, one may define a Hermitian ${\displaystyle L^{2}}$ -inner product on complex differential forms, by:

${\displaystyle \langle \alpha ,\beta \rangle _{L^{2}}=\int _{X}\alpha \wedge {\bar {\star }}\beta ,}$ 

where now ${\displaystyle \alpha \wedge {\bar {\star }}\beta }$  is an ${\displaystyle (n,n)}$ -form, and in particular a complex-valued ${\displaystyle 2n}$ -form and can therefore be integrated on ${\displaystyle X}$  with respect to its canonical orientation. Furthermore, suppose ${\displaystyle (E,h)}$  is a Hermitian holomorphic vector bundle. Then the Hermitian metric ${\displaystyle h}$  gives a conjugate-linear isomorphism ${\displaystyle E\cong E^{*}}$  between ${\displaystyle E}$  and its dual vector bundle, say ${\displaystyle \tau :E\to E^{*}}$ . Defining ${\displaystyle {\bar {\star }}_{E}(\omega \otimes s)={\bar {\star }}\omega \otimes \tau (s)}$ , one obtains an isomorphism:

${\displaystyle {\bar {\star }}_{E}:\Omega ^{p,q}(X,E)\to \Omega ^{n-p,n-q}(X,E^{*})}$ 

where ${\displaystyle \Omega ^{p,q}(X,E)=\Omega ^{p,q}(X)\otimes \Gamma (E)}$  consists of smooth ${\displaystyle E}$ -valued complex differential forms. Using the pairing between ${\displaystyle E}$  and ${\displaystyle E^{*}}$  given by ${\displaystyle \tau }$  and ${\displaystyle h}$ , one can therefore define a Hermitian ${\displaystyle L^{2}}$ -inner product on such ${\displaystyle E}$ -valued forms by:

${\displaystyle \langle \alpha ,\beta \rangle _{L^{2}}=\int _{X}\alpha \wedge _{h}{\bar {\star }}_{E}\beta ,}$ 

where here ${\displaystyle \wedge _{h}}$  means wedge product of differential forms and using the pairing between ${\displaystyle E}$  and ${\displaystyle E^{*}}$  given by ${\displaystyle h}$ .

The Hodge theorem for Dolbeault cohomology asserts that if we define:

${\displaystyle \Delta _{{\bar {\partial }}_{E}}={\bar {\partial }}_{E}^{*}{\bar {\partial }}_{E}+{\bar {\partial }}_{E}{\bar {\partial }}_{E}^{*}}$ 

where ${\displaystyle {\bar {\partial }}_{E}}$  is the Dolbeault operator of ${\displaystyle E}$  and ${\displaystyle {\bar {\partial }}_{E}^{*}}$  is its formal adjoint with respect to the inner product, then:

${\displaystyle H^{p,q}(X,E)\cong {\mathcal {H}}_{\Delta _{{\bar {\partial }}_{E}}}^{p,q}(X).}$ 

On the left is Dolbeault cohomology, and on the right is the vector space of harmonic ${\displaystyle E}$ -valued differential forms defined by:

${\displaystyle {\mathcal {H}}_{\Delta _{{\bar {\partial }}_{E}}}^{p,q}(X)=\{\alpha \in \Omega ^{p,q}(X,E)\mid \Delta _{{\bar {\partial }}_{E}}(\alpha )=0\}.}$ 

Using this description, the Serre duality theorem can be stated as follows: The isomorphism ${\displaystyle {\bar {\star }}_{E}}$  induces a complex linear isomorphism:

${\displaystyle H^{p,q}(X,E)\cong H^{n-p,n-q}(X,E^{*})^{*}.}$ 

This can be easily proved using the Hodge theory above. Namely, if ${\displaystyle [\alpha ]}$  is a cohomology class in ${\displaystyle H^{p,q}(X,E)}$  with unique harmonic representative ${\displaystyle \alpha \in {\mathcal {H}}_{\Delta _{{\bar {\partial }}_{E}}}^{p,q}(X)}$ , then:

${\displaystyle (\alpha ,{\bar {\star }}_{E}\alpha )=\langle \alpha ,\alpha \rangle _{L^{2}}\geq 0}$ 

with equality if and only if ${\displaystyle \alpha =0}$ . In particular, the complex linear pairing:

${\displaystyle (\alpha ,\beta )=\int _{X}\alpha \wedge _{h}\beta }$ 

between ${\displaystyle {\mathcal {H}}_{\Delta _{{\bar {\partial }}_{E}}}^{p,q}(X)}$  and ${\displaystyle {\mathcal {H}}_{\Delta _{{\bar {\partial }}_{E^{*}}}}^{n-p,n-q}(X)}$  is non-degenerate, and induces the isomorphism in the Serre duality theorem.

The statement of Serre duality in the algebraic setting may be recovered by taking ${\displaystyle p=0}$ , and applying Dolbeault's theorem, which states that:

${\displaystyle H^{p,q}(X,E)\cong H^{q}(X,{\boldsymbol {\Omega }}^{p}\otimes E)}$ 

where on the left is Dolbeault cohomology and on the right sheaf cohomology, where ${\displaystyle {\boldsymbol {\Omega }}^{p}}$  denotes the sheaf of holomorphic ${\displaystyle (p,0)}$ -forms. In particular, we obtain:

${\displaystyle H^{q}(X,E)\cong H^{0,q}(X,E)\cong H^{n,n-q}(X,E^{*})^{*}\cong H^{n-q}(X,K_{X}\otimes E^{*})^{*}}$ 

where we have used that the sheaf of holomorphic ${\displaystyle (n,0)}$ -forms is just the canonical bundle of ${\displaystyle X}$ .

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 ${\displaystyle H^{0}(X,L)}$  and ${\displaystyle H^{1}(X,L)}$ . Serre duality describes the ${\displaystyle H^{1}}$  group in terms of an ${\displaystyle H^{0}}$  group (for a different line bundle).^[3] That is more concrete, since ${\displaystyle H^{0}}$  of a line bundle is simply its space of sections.

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:

${\displaystyle h^{0}(X,L)-h^{1}(X,L)=d-g+1.}$ 

Using Serre duality, this can be restated in more elementary terms:

${\displaystyle h^{0}(X,L)-h^{0}(X,K_{X}\otimes L^{*})=d-g+1.}$ 

The latter statement (expressed in terms of divisors) is in fact the original version of the theorem from the 19th century. This is the main tool used to analyze how a given curve can be embedded into projective space and hence to classify algebraic curves.

Example: Every global section of a line bundle of negative degree is zero. Moreover, the degree of the canonical bundle is ${\displaystyle 2g-2}$ . Therefore, Riemann–Roch implies that for a line bundle L of degree ${\displaystyle d>2g-2}$ , ${\displaystyle h^{0}(X,L)}$  is equal to ${\displaystyle d-g+1}$ . When the genus g is at least 2, it follows by Serre duality that ${\displaystyle h^{1}(X,TX)=h^{0}(X,K_{X}^{\otimes 2})=3g-3}$ . Here ${\displaystyle H^{1}(X,TX)}$  is the first-order deformation space of X. This is the basic calculation needed to show that the moduli space of curves of genus g has dimension ${\displaystyle 3g-3}$ .

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 ${\displaystyle \omega _{X}}$  on X called the dualizing sheaf. (Some authors call this sheaf ${\displaystyle K_{X}}$ .) Suppose in addition that X is proper over k. For a coherent sheaf E on X and an integer i, Serre duality says that there is a natural isomorphism:

${\displaystyle \operatorname {Ext} _{X}^{i}(E,\omega _{X})\cong H^{n-i}(X,E)^{*}}$ 

of finite-dimensional k-vector spaces.^[4] Here the Ext group is taken in the abelian category of ${\displaystyle O_{X}}$ -modules. This includes the previous statement, since ${\displaystyle \operatorname {Ext} _{X}^{i}(E,\omega _{X})}$  is isomorphic to ${\displaystyle H^{i}(X,E^{*}\otimes \omega _{X})}$  when E is a vector bundle.

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, ${\displaystyle \omega _{X}}$  is the canonical line bundle ${\displaystyle K_{X}}$  defined above. More generally, if X is a Cohen–Macaulay subscheme of codimension r in a smooth scheme Y over k, then the dualizing sheaf can be described as an Ext sheaf:^[5]

${\displaystyle \omega _{X}\cong {\mathcal {Ext}}_{O_{Y}}^{r}(O_{X},K_{Y}).}$ 

When X is a local complete intersection of codimension r in a smooth scheme Y, there is a more elementary description: the normal bundle of X in Y is a vector bundle of rank r, and the dualizing sheaf of X is given by:^[6]

${\displaystyle \omega _{X}\cong K_{Y}|_{X}\otimes {\bigwedge }^{r}(N_{X/Y}).}$ 

In this case, X is a Cohen–Macaulay scheme with ${\displaystyle \omega _{X}}$  a line bundle, which says that X is Gorenstein.

Example: Let X be a complete intersection in projective space ${\displaystyle {\mathbf {P} }^{n}}$  over a field k, defined by homogeneous polynomials ${\displaystyle f_{1},\ldots ,f_{r}}$  of degrees ${\displaystyle d_{1},\ldots ,d_{r}}$ . (To say that this is a complete intersection means that X has dimension ${\displaystyle n-r}$ .) There are line bundles O(d) on ${\displaystyle {\mathbf {P} }^{n}}$  for integers d, with the property that homogeneous polynomials of degree d can be viewed as sections of O(d). Then the dualizing sheaf of X is the line bundle:

${\displaystyle \omega _{X}=O(d_{1}+\cdots +d_{r}-n-1)|_{X},}$ 

by the adjunction formula. For example, the dualizing sheaf of a plane curve X of degree d is ${\displaystyle O(d-3)|_{X}}$ .

Complex moduli of Calabi–Yau threefolds edit

In particular, we can compute the number of complex deformations, equal to ${\displaystyle \dim(H^{1}(X,TX))}$  for a quintic threefold in ${\displaystyle \mathbb {P} ^{4}}$ , a Calabi–Yau variety, using Serre duality. Since the Calabi–Yau property ensures ${\displaystyle K_{X}\cong {\mathcal {O}}_{X}}$  Serre duality shows us that ${\displaystyle H^{1}(X,TX)\cong H^{2}(X,{\mathcal {O}}_{X}\otimes \Omega _{X})\cong H^{2}(X,\Omega _{X})}$  showing the number of complex moduli is equal to ${\displaystyle h^{2,1}}$  in the Hodge diamond. Of course, the last statement depends on the Bogomolev–Tian–Todorov theorem which states every deformation on a Calabi–Yau is unobstructed.

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 ${\displaystyle \omega _{X}^{\bullet }}$  of the bounded derived category of coherent sheaves on X, ${\displaystyle D_{\operatorname {coh} }^{b}(X)}$ , called the dualizing complex of X over k. Formally, ${\displaystyle \omega _{X}^{\bullet }}$  is the exceptional inverse image ${\displaystyle f^{!}O_{Y}}$ , where f is the given morphism ${\displaystyle X\to Y=\operatorname {Spec} (k)}$ . When X is Cohen–Macaulay of pure dimension n, ${\displaystyle \omega _{X}^{\bullet }}$  is ${\displaystyle \omega _{X}[n]}$ ; that is, it is the dualizing sheaf discussed above, viewed as a complex in (cohomological) degree −n. In particular, when X is smooth over k, ${\displaystyle \omega _{X}^{\bullet }}$  is the canonical line bundle placed in degree −n.

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:

${\displaystyle \operatorname {Hom} _{X}(E,\omega _{X}^{\bullet })\cong \operatorname {Hom} _{X}(O_{X},E)^{*}}$ 

for any object E in ${\displaystyle D_{\operatorname {coh} }^{b}(X)}$ .^[7]

More generally, for a proper scheme X over k, an object E in ${\displaystyle D_{\operatorname {coh} }^{b}(X)}$ , and F a perfect complex in ${\displaystyle D_{\operatorname {perf} }(X)}$ , one has the elegant statement:

${\displaystyle \operatorname {Hom} _{X}(E,F\otimes \omega _{X}^{\bullet })\cong \operatorname {Hom} _{X}(F,E)^{*}.}$ 

Here the tensor product means the derived tensor product, as is natural in derived categories. (To compare with previous formulations, note that ${\displaystyle \operatorname {Ext} _{X}^{i}(E,\omega _{X})}$  can be viewed as ${\displaystyle \operatorname {Hom} _{X}(E,\omega _{X}[i])}$ .) When X is also smooth over k, every object in ${\displaystyle D_{\operatorname {coh} }^{b}(X)}$  is a perfect complex, and so this duality applies to all E and F in ${\displaystyle D_{\operatorname {coh} }^{b}(X)}$ . The statement above is then summarized by saying that ${\displaystyle F\mapsto F\otimes \omega _{X}^{\bullet }}$  is a Serre functor on ${\displaystyle D_{\operatorname {coh} }^{b}(X)}$  for X smooth and proper over k.^[8]

Serre duality holds more generally for proper algebraic spaces over a field.^[9]

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• The Stacks Project Authors, The Stacks Project