Draft:Complete algebraic curve

Let k be an algebrically closed field. By a function field K over k, we mean a finitely generated field extension of k that is typically not algebraic (i.e., a transcendental extension). The function field of an algebraic variety is a basic example. For a function field of transcendence degree one, the converse holds by the following construction.^[4] Let ${\displaystyle C_{K}}$  denote the set of all discrete valuation rings of ${\displaystyle K/k}$ . We put the topology on ${\displaystyle C_{K}}$  so that the closed subsets are either finite subsets or the whole space. We then make it a locally ringed space by taking ${\displaystyle {\mathcal {O}}(U)}$  to be the intersection ${\displaystyle \cap _{R\in U}R}$ . Then the ${\displaystyle C_{K}}$  for various function fields K of transcendence degree one form a category that is equivalent to the category of smooth projective curves.^[5]

One consequence of the above construction is that a complete smooth curve is projective (since a complete smooth curve of C corresponds to ${\displaystyle C_{K},K=k(C)}$ , which corresponds to a projective smooth curve.)

Let ${\displaystyle C_{0}=V(f)\subset \mathbb {A} ^{2}}$  be a smooth affine curve given by a polynomial f in two variables. The closure ${\displaystyle {\overline {C_{0}}}}$  in ${\displaystyle \mathbb {P} ^{2}}$ , the projective completion of it, may or may not be smooth. The normalization C of ${\displaystyle {\overline {C_{0}}}}$  is smooth and contains ${\displaystyle C_{0}}$  as an open dense subset. Then the curve ${\displaystyle C}$  is called the smooth completion of ${\displaystyle C_{0}}$ .^[6] (Note the smooth completion of ${\displaystyle C_{0}}$  is unique up to isomorphism since two smooth curves are isomorphic if they are birational to each other.)

For example, if ${\displaystyle f=y^{2}-x^{3}+1}$ , then ${\displaystyle {\overline {C_{0}}}}$  is given by ${\displaystyle y^{2}z=x^{3}-z^{3}}$ , which is smooth (by a Jacobian computation). On the other hand, consider ${\displaystyle f=y^{2}-x^{6}+1}$ . Then, by a Jacobian computation, ${\displaystyle {\overline {C_{0}}}}$  is not smooth. In fact, ${\displaystyle C_{0}}$  is an (affine) hyperelliptic curve and a hyperelliptic curve is not a plane curve (since a hyperelliptic curve is never a complete intersection in a projective space).

Over the complex numbers, C is a compact Riemann surface that is classically called the Riemann surface associated to the algebraic function ${\displaystyle y(x)}$  when ${\displaystyle f(x,y(x))\equiv 0}$ .^[6]. Conversely, each compact Riemann surface is of that form;^{[citation needed]} this is known as the Riemann existence theorem.

To give a rational map from a (projective) curve C to a projective space is to give a linear system of divisors V on C, up to the fixed part of the system? (need to be clarified); namely, when B is the base locus (the common zero sets of the nonzero sections in V), there is:

${\displaystyle f:C-B\to \mathbb {P} (V^{*})}$ 

that maps each point ${\displaystyle P}$  in ${\displaystyle C-B}$  to the hyperplane ${\displaystyle \{s\in V|s(P)=0\}}$ . Conversely, given a rational map f from C to a projective space,

In particular, one can take the linear system to be the canonical linear system ${\displaystyle |K|=\mathbb {P} (\Gamma (C,\omega _{C}))}$  and the corresponding map is called the canonical map.

Let ${\displaystyle g}$  be the genus of a smooth curve C. If ${\displaystyle g=0}$ , then ${\displaystyle |K|}$  is empty while if ${\displaystyle g=1}$ , then ${\displaystyle |K|=0}$ . If ${\displaystyle g\geq 2}$ , then the canonical linear system ${\displaystyle |K|}$  can be shown to have no base point and thus determines the morphism ${\displaystyle f:C\to \mathbb {P} ^{g-1}}$ . If the degree of f or equivalently the degree of the linear system is 2, then C is called a hyperelliptic curve.

Max Noether's theorem implies that a non-hyperelliptic curve is projectively normal when it is embedded into a projective space by the canonical divisor.

The classification of a smooth projective curve begins with specifying a genus. For genus zero, there is only one: the projective line ${\displaystyle \mathbb {P} ^{1}}$  (up to isomorphism). A genus-one curve is precisely an elliptic curve and isomorphism classes of elliptic curves are specified by a j-invariant (which is an element of the base field). The classification of genus-2 curves is much more complicated; here is some partial result over an algebraically closed field of characteristic not two:^[7]

• Each genus-two curve X comes with the map ${\displaystyle f:X\to \mathbb {P} ^{1}}$  determined by the canonical divisor; called the canonical map. The canonical map has exactly 6 ramified points of index 2.
• Conversely, given 6 points,

For genus ${\displaystyle \geq 3}$ , the following terminology is used;

• Given a smooth curve C, a divisor D on it and a vector subspace ${\displaystyle V\subset H^{0}(C,{\mathcal {O}}(D))}$ , one says the linear system ${\displaystyle \mathbb {P} (V)}$  is a g^r_d if V has dimension r+1 and D has degree d. One says C has a g^r_d if there is such a linear system.

A stable curve is a connected nodal curve with finite automorphism group.

Let X be a possibly singular curve. Then

${\displaystyle 0\to \mathbb {C} ^{*}\to (\mathbb {C} ^{*})^{r}\to \Gamma (X,{\mathcal {F}})\to \operatorname {Pic} (X)\to \operatorname {Pic} ({\widetilde {X}})\to 0.}$ 

where r is the number of irreducible components of X, ${\displaystyle \pi :{\widetilde {X}}\to X}$  is the normalization and ${\displaystyle {\mathcal {F}}=\pi _{*}{\mathcal {O}}_{\widetilde {X}}/{\mathcal {O}}_{X}}$ . (To get this use the fact ${\displaystyle \operatorname {Pic} (X)=\operatorname {H} ^{1}(X,{\mathcal {O}}_{X}^{*})}$  and ${\displaystyle \operatorname {Pic} ({\widetilde {X}})=\operatorname {H} ^{1}({\widetilde {X}},{\mathcal {O}}_{\widetilde {X}}^{*})=\operatorname {H} ^{1}(X,\pi _{*}{\mathcal {O}}_{\widetilde {X}}^{*}).}$ )

Taking the long exact sequence of the exponential sheaf sequence gives the degree map:

${\displaystyle \deg :\operatorname {Pic} (X)\to \operatorname {H} ^{2}(X;\mathbb {Z} )\simeq \mathbb {Z} ^{r}.}$ 

By definition, the Jacobian variety J(X) of X is the identity component of the kernel of this map. Then the previous exact sequence gives:

${\displaystyle 0\to \mathbb {C} ^{*}\to (\mathbb {C} ^{*})^{r}\to \Gamma ({\widetilde {X}},{\mathcal {F}})\to J(X)\to J({\widetilde {X}})\to 0.}$ 

We next define the dual graph of X; a one-dimensional CW complex defined as follows. (related to whether a curve is of compact type or not)

Let C be a smooth connected curve. Given an integer d, let ${\displaystyle \operatorname {Pic} ^{d}C}$  denote the set of isomorphism classes of line bundles on C of degree d. It can be shown to have a structure of an algebraic variety.

For each integer d > 0, let ${\displaystyle C^{d},C_{d}}$  denote respectively the d-th fold Cartesian and symmetric product of C; by definition, ${\displaystyle C_{d}}$  is the quotient of ${\displaystyle C^{d}}$  by the symmetric group permuting the factors.

Fix a base point ${\displaystyle p_{0}}$  of C. Then there is the map

${\displaystyle u:C_{d}\to J(C)}$ 

given by ${\displaystyle (q_{1},\dots ,q_{d})\mapsto }$ .

The Jacobian of a curve can be generalized to higher-rank vector bundles; a key notion introduced by Mumford that allows for a moduli construction is that of stability.

Let C be a connected smooth curve. A rank-2 vector bundle E on C is said to be stable if for every line subbundle L of E,

${\displaystyle \operatorname {deg} L<{1 \over 2}\operatorname {deg} E}$ .

Given some line bundle L on C, let ${\displaystyle SU_{C}(2,L)}$  denote the set of isomorphism classes of rank-2 stable bundles E on C whose determinants are isomorphic to L.

Given a linear series V on a curve X, the image of it under ${\displaystyle \operatorname {ord} _{p}}$  is a finite set and following the tradition we write it as

${\displaystyle a_{0}(V,p)<a_{1}(V,p)<\cdots <a_{r}(V,p).}$ 

This sequence is called the vanishing sequence. For example, ${\displaystyle a_{0}(V,p)}$  is the multiplicity of a base point p. We think of higher ${\displaystyle a_{i}(V,p)}$  as encoding information about inflection of the Kodaira map ${\displaystyle \varphi _{V}}$ . The ramification sequence is then

${\displaystyle b_{i}(V,p)=a_{i}(V,p)-i.}$ 

Their sum is called the ramification index of p. The global ramification is given by the following formula:

An elliptic curve X over the complex numbers has a uniformization ${\displaystyle \mathbb {C} \to X}$  given by taking the quotient by a lattice.

A relative curve or a curve over a scheme S or a relative curve is a flat morphism of schemes ${\displaystyle X\to S}$  such that each geometric fiber is an algebraic curve; in other words, it is a family of curves parametrized by the base scheme S.

See also Semistable reduction theorem.

This generalizes the classical construction due to Tate (cf. Tate curve)^[8] In Mumford 1972 harvnb error: no target: CITEREFMumford1972 (help), Mumford showed: given a smooth projective curve of genus at least two and has a split degeneration,

• Severi variety (Hilbert scheme)
• Hurwitz scheme

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