Relative effective Cartier divisor

In algebraic geometry, a relative effective Cartier divisor is roughly a family of effective Cartier divisors. Precisely, an effective Cartier divisor in a scheme X over a ring R is a closed subscheme D of X that (1) is flat over R and (2) the ideal sheaf ${\displaystyle I(D)}$ of D is locally free of rank one (i.e., invertible sheaf). Equivalently, a closed subscheme D of X is an effective Cartier divisor if there is an open affine cover ${\displaystyle U_i=\mathrm{Spec}{A}_i}$ of X and nonzerodivisors ${\displaystyle f_i\in A_i}$ such that the intersection ${\displaystyle D\cap U_i}$ is given by the equation ${\displaystyle f_i=0}$ (called local equations) and ${\displaystyle A/f_{i}A}$ is flat over R and such that they are compatible.

Let L be a line bundle on X and s a section of it such that ${\displaystyle s:{𝒪}_X\hookrightarrow L}$ (in other words, s is a ${\displaystyle {𝒪}_X(U)}$-regular element for any open subset U.)

Choose some open cover ${\displaystyle \{U_i\}}$ of X such that ${\displaystyle L{|}_{U_i}\simeq {𝒪}_X{|}_{U_i}}$. For each i, through the isomorphisms, the restriction ${\displaystyle s{|}_{U_i}}$ corresponds to a nonzerodivisor ${\displaystyle f_i}$ of ${\displaystyle {𝒪}_X(U_i)}$. Now, define the closed subscheme ${\displaystyle \{s=0\}}$ of X (called the zero-locus of the section s) by

${\displaystyle \{s=0\}\cap U_i=\{f_i=0\},}$

where the right-hand side means the closed subscheme of ${\displaystyle U_i}$ given by the ideal sheaf generated by ${\displaystyle f_i}$. This is well-defined (i.e., they agree on the overlaps) since ${\displaystyle f_i/f_j{|}_{U_i\cap U_j}}$ is a unit element. For the same reason, the closed subscheme ${\displaystyle \{s=0\}}$ is independent of the choice of local trivializations.

Equivalently, the zero locus of s can be constructed as a fiber of a morphism; namely, viewing L as the total space of it, the section s is a X-morphism of L: a morphism ${\displaystyle s:X\to L}$ such that s followed by ${\displaystyle L\to X}$ is the identity. Then ${\displaystyle \{s=0\}}$ may be constructed as the fiber product of s and the zero-section embedding ${\displaystyle s_0:X\to L}$.

Finally, when ${\displaystyle \{s=0\}}$ is flat over the base scheme S, it is an effective Cartier divisor on X over S. Furthermore, this construction exhausts all effective Cartier divisors on X as follows. Let D be an effective Cartier divisor and ${\displaystyle I(D)}$ denote the ideal sheaf of D. Because of locally-freeness, taking ${\displaystyle I(D{)}^{-1}{\otimes }_{{𝒪}_X}-}$ of ${\displaystyle 0\to I(D)\to {𝒪}_X\to {𝒪}_D\to 0}$ gives the exact sequence

${\displaystyle 0\to {𝒪}_X\to I(D{)}^{-1}\to I(D{)}^{-1}\otimes {𝒪}_D\to 0}$

In particular, 1 in ${\displaystyle \Gamma (X,{𝒪}_X)}$ can be identified with a section in ${\displaystyle \Gamma (X,I(D{)}^{-1})}$, which we denote by ${\displaystyle s_D}$.

Now we can repeat the early argument with ${\displaystyle L=I(D{)}^{-1}}$. Since D is an effective Cartier divisor, D is locally of the form ${\displaystyle \{f=0\}}$ on ${\displaystyle U=\mathrm{Spec}(A)}$ for some nonzerodivisor f in A. The trivialization ${\displaystyle L{|}_U=A{f}^{-1}\stackrel{\sim }{\to }A}$ is given by multiplication by f; in particular, 1 corresponds to f. Hence, the zero-locus of ${\displaystyle s_D}$ is D.

• If D and D' are effective Cartier divisors, then the sum ${\displaystyle D+D^{\prime }}$ is the effective Cartier divisor defined locally as ${\displaystyle fg=0}$ if f, g give local equations for D and D' .
• If D is an effective Cartier divisor and ${\displaystyle R\to R^{\prime }}$ is a ring homomorphism, then ${\displaystyle D{\times }_R{R}^{\prime }}$ is an effective Cartier divisor in ${\displaystyle X{\times }_R{R}^{\prime }}$.
• If D is an effective Cartier divisor and ${\displaystyle f:X^{\prime }\to X}$ a flat morphism over R, then ${\displaystyle D^{\prime }=D{\times }_X{X}^{\prime }}$ is an effective Cartier divisor in X' with the ideal sheaf ${\displaystyle I(D^{\prime })=f^{\ast }(I(D))}$.

From now on suppose X is a smooth curve (still over R). Let D be an effective Cartier divisor in X and assume it is proper over R (which is immediate if X is proper.) Then ${\displaystyle \Gamma (D,{𝒪}_D)}$ is a locally free R-module of finite rank. This rank is called the degree of D and is denoted by ${\displaystyle \mathrm{deg}D}$. It is a locally constant function on ${\displaystyle \mathrm{Spec}R}$. If D and D' are proper effective Cartier divisors, then ${\displaystyle D+D^{\prime }}$ is proper over R and ${\displaystyle \mathrm{deg}(D+D^{\prime })=\mathrm{deg}(D)+\mathrm{deg}(D^{\prime })}$. Let ${\displaystyle f:X^{\prime }\to X}$ be a finite flat morphism. Then ${\displaystyle \mathrm{deg}(f^{\ast }D)=\mathrm{deg}(f)\mathrm{deg}(D)}$.^[1] On the other hand, a base change does not change degree: ${\displaystyle \mathrm{deg}(D{\times }_R{R}^{\prime })=\mathrm{deg}(D)}$.^[2]

A closed subscheme D of X is finite, flat and of finite presentation if and only if it is an effective Cartier divisor that is proper over R.^[3]

Given an effective Cartier divisor D, there are two equivalent ways to associate Weil divisor ${\displaystyle [D]}$ to it.

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