Affine scheme: Difference between revisions
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==Definition== | ==Definition== | ||
For a commutative ring <math>A</math>, the set <math>Spec(A)</math> (called the ''prime spectrum of ''<math>A</math>) denotes the set of prime ideals of | For a commutative ring <math>A</math>, the set <math>Spec(A)</math> (called the ''prime spectrum of ''<math>A</math>) denotes the set of prime ideals of ''A''. This set is endowed with a [[Topological pace|topology]] of closed sets, where closed subsets are defined to be of the form | ||
:<math>V(E)=\{p\in Spec(A)| p\supseteq E\}</math> | :<math>V(E)=\{p\in Spec(A)| p\supseteq E\}</math> | ||
for any subset <math>E\subseteq A</math>. This topology of closed sets is called the ''Zariski topology'' on <math>Spec(A)</math>. It is easy to check that <math>V(E)=V\left((E)\right)=V(\sqrt{(E)})</math>, where | for any subset <math>E\subseteq A</math>. This topology of closed sets is called the ''Zariski topology'' on <math>Spec(A)</math>. It is easy to check that <math>V(E)=V\left((E)\right)=V(\sqrt{(E)})</math>, where | ||
<math>(E)</math> is the ideal of <math>A</math> generated by <math>E</math>. | <math>(E)</math> is the ideal of <math>A</math> generated by <math>E</math>. | ||
== | ==The functor V and the Zariski topology== | ||
<math>Spec(A)</math> is quasi-compact and <math>T_0</math>, but is rarely Hausdorff. | The Zariski topology on <math>Spec(A)</math> satisfies some properties: it is quasi-compact and <math>T_0</math>, but is rarely [[Hausdorff space|Hausdorff]]. <math>Spec(A)</math> is not, in general, a [[Noetherian space|Noetherian topological space]] (in fact, it is a Noetherian topological space if and only if <math>A</math> is a [[Noetherian ring]]. | ||
==The Structural Sheaf== | ==The Structural Sheaf== | ||
<math>X=Spec(A)</math> has a natural sheaf of rings, denoted <math>O_X | <math>X=Spec(A)</math> has a natural sheaf of rings, denoted by <math>O_X</math> and called the ''structural sheaf'' of ''X''. The pair <math>(Spec(A),O_X)</math> is called an ''affine [[Scheme|scheme]]''. The important properties of this sheaf are that | ||
# The [[ringed space|stalk]] <math>O_{X,x}</math> is isomorphic to the local ring <math>A_{\mathfrak{p}}</math>, where <math>\mathfrak{p}</math> is the prime ideal corresponding to <math>x\in X</math>. | # The [[ringed space|stalk]] <math>O_{X,x}</math> is isomorphic to the local ring <math>A_{\mathfrak{p}}</math>, where <math>\mathfrak{p}</math> is the prime ideal corresponding to <math>x\in X</math>. | ||
# For all <math>f\in A</math>, <math>\Gamma(D(f),O_X)\simeq A_f</math>, where <math>A_f</math> is the localization of <math>A</math> by the multiplicative set <math>S=\{1,f,f^2,\ldots\}</math>. In particular, <math>\Gamma(X,O_X)\simeq A</math>. | # For all <math>f\in A</math>, <math>\Gamma(D(f),O_X)\simeq A_f</math>, where <math>A_f</math> is the localization of <math>A</math> by the multiplicative set <math>S=\{1,f,f^2,\ldots\}</math>. In particular, <math>\Gamma(X,O_X)\simeq A</math>. | ||
Explicitly, the structural sheaf <math>O_X=</math> may be constructed as follows. To each open set <math>U</math>, associate the set of functions <math>O_X(U):=\{s:U\to \ | Explicitly, the structural sheaf <math>O_X=</math> may be constructed as follows. To each open set <math>U</math>, associate the set of functions <div style="text-align: center;"><math>O_X(U):=\{s:U\to \coprod_{p\in U} A_p|s(p)\in A_p, \text{ and }s\text{ is locally constant}\}</math></div>; that is, <math>s</math> is ''locally constant'' if for every <math>p\in U</math>, there is an open neighborhood <math>V</math> contained in <math>U</math> and elements <math>a,f\in A</math> such that for all <math>q\in V</math>, <math>s(q)=a/f\in A_q</math> (in particular, <math>f</math> is required to not be an element of any <math>q\in V</math>). This description is phrased in a common way of thinking of sheaves, and in fact captures their local nature. One construction of the [[sheafification]] functor makes use of such a perspective. | ||
==The Category of Affine Schemes== | ==The Category of Affine Schemes== | ||
Regarding <math>Spec(\cdot)</math> as a contravariant functor between the [[commutative ring|category of commutative rings]] and the category of affine schemes, one can show that it is in fact an [[anti-equivalence]] of categories. | Regarding <math>Spec(\cdot)</math> as a contravariant functor between the [[commutative ring|category of commutative rings]] and the category of affine schemes, one can show that it is in fact an [[Category of functors|anti-equivalence]] of categories. | ||
==Curves==[[Category:Suggestion Bot Tag]] | |||
==Curves== | |||
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Latest revision as of 06:00, 7 July 2024
Definition
For a commutative ring , the set (called the prime spectrum of ) denotes the set of prime ideals of A. This set is endowed with a topology of closed sets, where closed subsets are defined to be of the form
for any subset . This topology of closed sets is called the Zariski topology on . It is easy to check that , where is the ideal of generated by .
The functor V and the Zariski topology
The Zariski topology on satisfies some properties: it is quasi-compact and , but is rarely Hausdorff. is not, in general, a Noetherian topological space (in fact, it is a Noetherian topological space if and only if is a Noetherian ring.
The Structural Sheaf
has a natural sheaf of rings, denoted by and called the structural sheaf of X. The pair is called an affine scheme. The important properties of this sheaf are that
- The stalk is isomorphic to the local ring , where is the prime ideal corresponding to .
- For all , , where is the localization of by the multiplicative set . In particular, .
Explicitly, the structural sheaf may be constructed as follows. To each open set , associate the set of functions
; that is, is locally constant if for every , there is an open neighborhood contained in and elements such that for all , (in particular, is required to not be an element of any ). This description is phrased in a common way of thinking of sheaves, and in fact captures their local nature. One construction of the sheafification functor makes use of such a perspective.
The Category of Affine Schemes
Regarding as a contravariant functor between the category of commutative rings and the category of affine schemes, one can show that it is in fact an anti-equivalence of categories.
==Curves==