Riemann-Roch theorem

In algebraic geometry the Riemann-Roch theorem states that if ${\displaystyle C}$ is a smooth algebraic curve, and ${\displaystyle {\mathcal {L}}}$ is an invertible sheaf on ${\displaystyle C}$ then the the following properties hold:

• The Euler characteristic of ${\displaystyle {\mathcal {L}}}$ is given by ${\displaystyle h^{0}({\mathcal {L}})-h^{1}({\mathcal {L}})=deg({\mathcal {L}})-(g-1)}$
• There is a canonical isomorphism ${\displaystyle H^{0}(L)(K_{C}\otimes {\mathcal {L}}^{\vee })\cong H^{1}({\mathcal {L}})}$

Some examples and applications

The examples we give arise from considering complete linear systems on curves.

• Any curve ${\displaystyle C}$ of genus 0 is isomorphic to the projective line: Indeed if p is a point on the curve then ${\displaystyle h^{0}(p)-0=1-(0-1)=2}$; hence the map ${\displaystyle C\to \mathbb {P} H^{0}(O_{C}(p))}$ is a degree 1 map, or an isomorphism.
• Any curve of genus 1 is a double cover of a projective line: Indeed if p is a point on the curve then ${\displaystyle h^{0}(2p)-0=2-(1-1)=2}$; hence the map ${\displaystyle C\to \mathbb {P} H^{0}(O_{C}(2p))}$ is a degree 2 map.
• Any curve of genus 2 is a double cover of a projective line: Indeed the degree of the canonical class ${\displaystyle K_{C}}$ is ${\displaystyle 2g-2}$ and therefore ${\displaystyle h^{0}(K_{C})-h^{0}(O_{C})=2-(2-1)=1}$; since ${\displaystyle h^{0}(O_{C})=1}$ the map ${\displaystyle C\to \mathbb {P} H^{0}(K_{C})}$ is a degree 2 map.
• The Riemann-Hurwitz formula.

Geometric Riemann-Roch

Some linear systems on a smooth cannonicaly embedded genus 3 curve

From the statement of the theorem one sees that an effective divisor ${\displaystyle D}$ of degree ${\displaystyle d}$ on a curve ${\displaystyle C}$ satisfies ${\displaystyle h^{0}(D)>d-(g-1)}$ if and only if there is an effective divisor ${\displaystyle D'}$ such that ${\displaystyle D+D'\sim K_{C}}$ in ${\displaystyle Pic(C)}$. In this case there is a natural isomorphism

${\displaystyle \{[H]\in |K_{C}|,H\cdot C=D'\}\cong \mathbb {P} H^{0}(D)}$, where we identify ${\displaystyle C}$ with it's image in the dual canonical system ${\displaystyle |K_{C}|^{*}}$.

As an example we consider effective divisors of degrees ${\displaystyle 2,3}$ on a non hyperelliptic curve ${\displaystyle C}$ of genus 3. The degree of the canonical class is ${\displaystyle 2{\mbox{genus}}(c)-2=4}$, whereas ${\displaystyle h^{0}(K_{C})=2{\mbox{genus}}(C)-2-({\mbox{genus}}(C)-1)+h^{0}(0)=g}$. Hence the canonical image of ${\displaystyle C}$ is a smooth plane quartic. We now idenitfy ${\displaystyle C}$ with it's image in the dual canonical system. Let ${\displaystyle p,q}$ be two points on ${\displaystyle C}$ then there are exactly two points ${\displaystyle r,s}$ such that ${\displaystyle C\cap {\overline {pq}}=\{p,q,r,s\}}$, where we intersect with multiplicities, and if ${\displaystyle p=q}$ we consider the tangent line ${\displaystyle T_{p}C}$ instead of the line ${\displaystyle {\overline {pq}}}$. Hence there is a natural isomorphism between ${\displaystyle \mathbb {P} h^{0}(O_{C}(p+q))}$ and the unique point in ${\displaystyle |K_{C}|}$ representing the line ${\displaystyle {\overline {pq}}}$. There is also a natural ismorphism between ${\displaystyle \mathbb {P} (O_{C}(p+q+r))}$ and the points in ${\displaystyle |K_{C}|}$ representing lines through the points ${\displaystyle s}$.

Generalizations

The generalizations of th Riemann-Roch theorem come in two flavors: One direction views Riemann Roch theorem as a tool to study any linear system on a any curve. Clifford's theorem gives a better bound on the dimension of special linear systems on curve. If the assumption on the curve is relaxed to be a generic curve, then the Brill-Noether Theorem and the Petri Theorem give good descriptions of the geometry of the linear system.

Another direction of generalization, with more far-reaching consequences, is to view Riemann roch as a tool to compute the Euler characteristic of a vector bundle on a Variety. The first generalizations in this direction go back to the beginning of the 20th century with Riemann-Roch for surfaces and Noether's formula on surfaces. The next step, taken during the 1960s, is the Hirzebruch-Riemann-Roch theorem, which analyze the Euler characteristic of the canonical bundle of an arbitrary. The final step in the algebro-geometric setting is the Grothendieck-Riemann-Roch theorem, which analyzes the behaviour of the Euler characteristic of vector bundles under pullbacks; e.g. the Riemann-Roch theorem can be deduced from the Grothendieck-Riemann Roch theorem by projecting a curve to a point. In the analytic setting Grothendieck Riemann Roch had one more generalization: the Atiya-Singer index theorem.

Proofs

• The sheaf theoretic proof: Using modern tools, the theorem is an immediate consequence of Serre's duality, and the fact that if ${\displaystyle D,D'}$ are divisors on ${\displaystyle C}$ then ${\displaystyle \chi (O_{C}(D+D'))=\chi (O_{C}(D))+\chi (O_{C}(D'))}$.
• The analytic proof was chronologically the first one given - one analyzes the relation between meromorphic functions on ${\displaystyle C}$ with prescribed poles, and holomorphic differentials on ${\displaystyle C}$ with prescribed zeros over the same points (see Griffiths and Harris).
• The Italian proof follows from immersing the curve in the projective plane, and from explicit work with the adjunction formula (see ACGH)
• Weil's algebraic proof over function fields. (see Rosen)

References

• E. Arabarello M. Cornalba P. Griffiths and J. Harris
• P. Grifiths and J. Harris Principles of Algebraic geometry Chapter 2.3
• M. Rosen Number theory in Function Fields Chapter 6
• W. Fulton Intersection Theory