Hirzebruch–Riemann–Roch theorem

The Hirzebruch–Riemann–Roch theorem applies to any holomorphic vector bundle E on a compact complex manifold X, to calculate the holomorphic Euler characteristic of E in sheaf cohomology, namely the alternating sum

${\displaystyle \chi (X,E)=\sum _{i=0}^{\dim _{\mathbb {C} }X}(-1)^{i}\dim _{\mathbb {C} }H^{i}(X,E)}$

of the dimensions as complex vector spaces.

Hirzebruch's theorem states that χ(X, E) is computable in terms of the Chern classes C_j(E) of E, and the Todd polynomials T_j in the Chern classes of the holomorphic tangent bundle of X. These all lie in the cohomology ring of X; by use of the fundamental class (or, in other words, integration over X) we can obtain numbers from classes in ${\displaystyle H^{2n}(X).}$ The Hirzebruch formula asserts that

${\displaystyle \chi (X,E)=\sum \operatorname {ch} _{n-j}(E){\frac {T_{j}}{j!}}}$

taken over all relevant j (so 0 ≤ j ≤ n), using the Chern character ch(E) in cohomology. In other words, the cross products are formed in the cohomology ring of all the 'matching' degrees that add up to 2n, where to 'massage' the C_j(E) a formal manipulation is done, setting

${\displaystyle \operatorname {ch} (E)=\sum \exp(x_{i})}$

and the total Chern class

${\displaystyle C(E)=\sum C_{j}(E)=\prod (1+x_{i}).}$

Formulated differently the theorem gives the equality

${\displaystyle \chi (X,E)=\int _{X}\operatorname {ch} (E)\operatorname {td} (X)}$

where td(X) is the Todd class of the tangent bundle of X.

Significant special cases are when E is a complex line bundle, and when X is an algebraic surface (Noether's formula). Weil's Riemann–Roch theorem for vector bundles on curves, and the Riemann–Roch theorem for algebraic surfaces (see below), are included in its scope. The formula also expresses in a precise way the vague notion that the Todd classes are in some sense reciprocals of characteristic classes.

For curves, the Hirzebruch–Riemann–Roch theorem is essentially the classical Riemann–Roch theorem. To see this, recall that for each divisor D on a curve there is an invertible sheaf O(D) (which corresponds to a line bundle) such that the linear system of D is more or less the space of sections of O(D). For curves the Todd class is ${\displaystyle 1+c_{1}(T(X))/2,}$ and the Chern character of a sheaf O(D) is just 1+c₁(O(D)), so the Hirzebruch–Riemann–Roch theorem states that

${\displaystyle h^{0}({\mathcal {O}}(D))-h^{1}({\mathcal {O}}(D))=c_{1}({\mathcal {O}}(D))+c_{1}(T(X))/2\ \ \ }$ (integrated over X).

But h⁰(O(D)) is just l(D), the dimension of the linear system of D, and by Serre duality h¹(O(D)) = h⁰(O(K − D)) = l(K − D) where K is the canonical divisor. Moreover, c₁(O(D)) integrated over X is the degree of D, and c₁(T(X)) integrated over X is the Euler class 2 − 2g of the curve X, where g is the genus. So we get the classical Riemann Roch theorem

${\displaystyle \ell (D)-\ell (K-D)={\text{deg}}(D)+1-g.}$

For vector bundles V, the Chern character is rank(V) + c₁(V), so we get Weil's Riemann Roch theorem for vector bundles over curves:

${\displaystyle h^{0}(V)-h^{1}(V)=c_{1}(V)+\operatorname {rank} (V)(1-g).}$

For surfaces, the Hirzebruch–Riemann–Roch theorem is essentially the Riemann–Roch theorem for surfaces

${\displaystyle \chi (D)=\chi ({\mathcal {O}})+((D.D)-(D.K))/2.}$

combined with the Noether formula.

If we want, we can use Serre duality to express h²(O(D)) as h⁰(O(K − D)), but unlike the case of curves there is in general no easy way to write the h¹(O(D)) term in a form not involving sheaf cohomology (although in practice it often vanishes).

Let D be an ample Cartier divisor on an irreducible projective variety X of dimension n. Then

${\displaystyle h^{0}\left(X,{\mathcal {O}}_{X}(mD)\right)={\frac {(D^{n})}{n!}}.m^{n}+O(m^{n-1}).}$

More generally, if ${\displaystyle {\mathcal {F}}}$ is any coherent sheaf on X then

${\displaystyle h^{0}\left(X,{\mathcal {F}}\otimes {\mathcal {O}}_{X}(mD)\right)=\operatorname {rank} ({\mathcal {F}}){\frac {(D^{n})}{n!}}.m^{n}+O(m^{n-1}).}$

• Grothendieck–Riemann–Roch theorem - contains many computations and examples
• Hilbert polynomial - HRR can be used to compute Hilbert polynomials

• Friedrich Hirzebruch,Topological Methods in Algebraic Geometry ISBN 3-540-58663-6

• The Hirzebruch-Riemann-Roch Theorem