# Riemann–Roch theorem

In

mathematics , specifically incomplex analysis andalgebraic geometry , the**Riemann–Roch theorem**is an important tool in the computation of the dimension of the space ofmeromorphic function s with prescribed zeroes and allowed poles. It relates the complex analysis of a connectedcompact Riemann surface with the surface's purely topological genus "g", in a way that can be carried over into purely algebraic settings.Initially proved as

**Riemann's inequality**, the theorem reached its definitive form for Riemann surfaces after work of Riemann's short-lived studentGustav Roch in the1850 s. It was later generalized toalgebraic curve s, to higher-dimensional varieties and beyond.**Some data**We start with a connected compact Riemann surface of genus "g", and a fixed point "P" on it. We may look at functions having a pole only at "P". There is an increasing sequence of

vector space s: functions with no poles(i.e., constant functions), functions allowed at most a simple pole at "P", functions allowed at most a double pole at "P", a triple pole, ... These spaces are all finite dimensional. In case "g" = 0 we can see that the sequence of dimensions starts:1, 2, 3, ...:

this can be read off from the theory of

partial fraction s. Conversely if this sequence starts:1, 2, ...

then "g" must be zero (the so-called

Riemann sphere ).In the theory of

elliptic function s it is shown that for "g" = 1 this sequence is:1, 1, 2, 3, 4, 5 ... ;

and this characterises the case "g" = 1. For "g" > 2 there is no set initial segment; but we can say what the "tail" of the sequence must be. We can also see why "g" = 2 is somewhat special.

The reason that the results take the form they do goes back to the formulation ("Roch's part") of the theorem: as a difference of two such dimensions. When one of those can be set to zero, we get an exact formula, which is linear in the genus and the "degree" (i.e. number of "degrees of freedom"). Already the examples given allow a reconstruction in the shape

:"dimension" − "correction" = "degree" − "g" + 1.

For "g" = 1 the correction is 1 for degree 0; and otherwise 0. The full theorem explains the correction as the dimension associated to a further, 'complementary' space of functions.

**Statement of the theorem**In now-accepted notation, the statement of Riemann–Roch for a compact Riemann surface of genus "g" is

:"l"("D") − "l"("K" − "D") = "deg"("D") − "g" + 1.

This applies to all "divisors" "D", elements of the

free abelian group on the points of the surface. Equivalently, a divisor is a finite linear combination of points of the surface with integer coefficients.We define the divisor of a meromorphic function "f" as

:$(f):=sum\_\{z\_\; u\; in\; R(f)\}\; s\_\; u\; z\_\; u$

where "R"("f") is the set of all zeroes and poles of "f", and "s

_{ν}" is given by:$s\_\; u\; :=egin\{cases\}\; a\; ext\{if\; \}\; z\_\; u\; ext\{\; is\; a\; zero\; of\; order\; \}a\; \backslash \; -a\; ext\{if\; \}\; z\_\; u\; ext\{\; is\; a\; pole\; of\; order\; \}a.\; end\{cases\}$

We define the divisor of a meromorphic

1-form similarly. A divisor of a global meromorphic function is called a principal divisor. Two divisors that differ by a principal divisor are calledlinearly equivalent . A divisor of a global meromorphic 1-form is called thecanonical divisor (usually denoted "K"). Any two meromorphic 1-forms will yield linearly equivalent divisors, so the canonical divisor is uniquely determined up to linear equivalence (hence "the" canonical divisor).The symbol "deg"("D") denotes the "degree" of the divisor "D", i.e. the sum of the coefficients occurring in "D". It can be shown that the divisor of a global meromorphic function always has degree 0, so the degree of the divisor depends only on the linear equivalence class.

The number "l"(D) is the quantity that is of primary interest: the dimension (over

**C**) of the vector space of meromorphic functions "g" on the surface, such that all the coefficients of ("g") + "D" are non-negative. Intuitively, we can think of this as being all meromorphic functions whose poles at every point are no worse than the corresponding coefficient in "D"; if the coefficient in "D" at "z" is negative, then we require that "g" has a zero of at least thatmultiplicity at "z" – if the coefficient in "D" is positive, "g" can have a pole of at most that order. The vector spaces for linearly equivalent divisors are naturally isomorphic through multiplication with the global meromorphic function (which is well-defined up to a scalar).Even if we don't know anything about "K", we know at least that the

**index of speciality**[*Stichtenoth p.22*] [*Mukai pp.295-297*] (the "correction" referred to above):"l"("K" − "D") ≥ 0,

so

:"l"(D) ≥ "deg"("D") − "g" + 1

which is

**Riemann's inequality**mentioned earlier.The theorem above is correct for all compact connected Riemann surfaces. The formula also holds for all non-singular projective algebraic curves over an

algebraically closed field "k". Here "l"("D") denotes the dimension (over "k") of the space ofrational function s on the curve whose poles at every point are not worse than the corresponding coefficient in "D".To relate this to our example above, we need some information about "K": for "g" = 1 we can take "K" = 0, while for "g" = 0 we can take "K" = −2"P" (any "P"). In general K has degree 2"g" − 2. As long as "D" has degree at least 2"g" − 1 we can be sure that the correction term is 0.

Going back therefore to the case "g" = 2 we see that the sequence mentioned above is

:1, 1, ?, 2, 3, ... .

It is shown from this that the ? term of degree 2 is either 1 or 2, of course depending on the point. It can be proven that in any genus 2 curve there are exactly six points whose sequences are 1, 1, 2, 2, ... and the rest of the points have the generic sequence 1, 1, 1, 2, ... In particular, a genus 2 curve is a

hyperelliptic curve . For "g" > 2 it is always true that at most points the sequence starts with "g+1" ones and there are finitely many points with other sequences (seeWeierstrass point s).**A long road of generalisation**The

**Riemann–Roch theorem for curves**was proved for Riemann surfaces by Riemann and Roch in the 1850s and for algebraic curves byF. K. Schmidt in 1929. It is foundational in the sense that the subsequent theory for curves tries to refine the information it yields (for example in theBrill–Noether theory ).There are versions in higher dimensions (for the appropriate notion of divisor, or

line bundle ). Their general formulation depends on splitting the theorem into two parts. One, which would now be calledSerre duality , interprets the "l"("K" − "D") term as a dimension of a firstsheaf cohomology group; with "l"("D") the dimension of a zeroth cohomology group, or space of sections, the left-hand side of the theorem becomes anEuler characteristic , and the right-hand side a computation of it as a "degree" corrected according to the topology of the Riemann surface.In

algebraic geometry of dimension two such a formula was found by the geometers of the Italian school; aRiemann–Roch theorem for algebraic surfaces was proved (there are several versions, with the first possibly being due toMax Noether ). So matters rested before about 1950.An "n"-dimensional generalisation, the

Hirzebruch–Riemann–Roch theorem , was found and proved byFriedrich Hirzebruch , as an application ofcharacteristic class es inalgebraic topology ; he was much influenced by the work ofKunihiko Kodaira . At about the same timeJean-Pierre Serre was giving the general form of Serre duality, as we now know it.Alexander Grothendieck proved a far-reaching generalization in1957 , now known as theGrothendieck–Riemann–Roch theorem . His work reinterprets Riemann–Roch not as a theorem about a variety, but about a morphism between two varieties. (The folk-history suggests Grothendieck had a result somewhat earlier; it was written up finally by Serre andArmand Borel .)Finally a general version was found in

algebraic topology , too. These developments were essentially all carried out between 1950 and 1960. After that theAtiyah–Singer index theorem opened another route to generalization.What results is that the Euler characteristic (of a

coherent sheaf ) is something reasonably computable as a "left-hand side ". If one is interested, as is usually the case, in just one summand within the alternating sum, further arguments such asvanishing theorem s must be brought to bear.**Notes****References***

*, see pages 208–219 for the proof in the complex situation. Note that Jost uses slightly different notation.

* | year=1977, contains the statement for curves over an algebraically closed field. See section IV.1.

* | year=1995. A good general modern reference.

*

*

* [*http://www.math.ucdavis.edu/~kapovich/ Misha Kapovich*] , [*http://www.math.ucdavis.edu/%7Ekapovich/RS/RiemannRoch.pdf "The Riemann–Roch Theorem*] (lecture note) an elementary introduction

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