Zariski topology

In classical algebraic geometry (that is, the part of algebraic geometry in which one does not use schemes, which were introduced by Grothendieck around 1960), the Zariski topology is defined on algebraic varieties. The Zariski topology, defined on the points of the variety, is the topology such that the closed sets are the algebraic subsets of the variety. As the most elementary algebraic varieties are affine and projective varieties, it is useful to make this definition more explicit in both cases. We assume that we are working over a fixed, algebraically closed field k (in classical algebraic geometry, k is usually the field of complex numbers). Affine varieties First, we define the topology on the affine space {{nowrap|\mathbb{A}^n,}} formed by the of elements of k. The topology is defined by specifying its closed sets, rather than its open sets, and these are taken simply to be all the algebraic sets in {{nowrap|\mathbb{A}^n.}} That is, the closed sets are those of the form V(S) = \{x \in \mathbb{A}^n \mid f(x) = 0, \quad \forall f \in S\} where S is any set of polynomials in n variables over It is a straightforward verification to show that: • V(S) = V((S)), where (S) is the ideal generated by the elements of • For any two ideals of polynomials I, J, we have • • It follows that finite unions and arbitrary intersections of the sets V(S) are also of this form, so that these sets form the closed sets of a topology. Writing the sets {{nowrap|D(f) = \mathbb{A}^n \setminus V(f)}} are open sets, known as the principal (or distinguished) open sets, that form a base for the topology. This is the Zariski topology on {{nowrap|\mathbb{A}^n.}} If X is an affine algebraic set (irreducible or not) then the Zariski topology on it is defined simply to be the subspace topology induced by its inclusion into some {{nowrap|\mathbb{A}^n.}} Equivalently, it can be checked that: • The elements of the affine coordinate ring A(X) = k[x_1, \dots, x_n]/I(X) act as functions on X just as the elements of k[x_1, \dots, x_n] act as functions on {{nowrap|\mathbb{A}^n;}} here, I(X) is the ideal of all polynomials vanishing on • For any set of polynomials S, let T be the set of their images in Then the subset of X V'(T) = \{x \in X \mid f(x) = 0, \quad \forall f \in T\} (these notations are not standard) is equal to the intersection with X of This establishes that the above equation, clearly a generalization of the definition of the closed sets in \mathbb{A}^n above, defines the Zariski topology on any affine variety. Projective varieties Recall that n-dimensional projective space \mathbb{P}^n is defined to be the set of equivalence classes of non-zero points in \mathbb{A}^{n + 1} by identifying two points that differ by a scalar multiple in k. The elements of the polynomial ring k[x_0, \dots, x_n] are not generally functions on \mathbb{P}^n because any point has many representatives that yield different values in a polynomial; however, for homogeneous polynomials the condition of having zero or nonzero value on any given projective point is well-defined since the scalar multiple factors out of the polynomial. Therefore, if S is any set of homogeneous polynomials we may reasonably speak of V(S) = \{x \in \mathbb{P}^n \mid f(x) = 0, \quad \forall f \in S\}. The same facts as above may be established for these sets, except that the word "ideal" must be replaced by the phrase "homogeneous ideal", so that the V(S), for sets S of homogeneous polynomials, define a topology on \mathbb{P}^n. As above the complements of these sets are denoted D(S), or, if confusion is likely to result, D'(S). The projective Zariski topology is defined for projective algebraic sets just as the affine one is defined for affine algebraic sets, by taking the subspace topology. Similarly, it may be shown that this topology is defined intrinsically by sets of elements of the projective coordinate ring, by the same formula as above. Properties An important property of Zariski topologies is that they have a base consisting of simple elements, namely the for individual polynomials (or for projective varieties, homogeneous polynomials) That these form a base follows from the formula for the intersection of two Zariski-closed sets given above (apply it repeatedly to the principal ideals generated by the generators of ). The open sets in this base are called distinguished or basic open sets. The importance of this property results in particular from its use in the definition of an affine scheme. By Hilbert's basis theorem and the fact that Noetherian rings are closed under quotients, every affine or projective coordinate ring is Noetherian. As a consequence, affine or projective spaces with the Zariski topology are Noetherian topological spaces, which implies that any closed subset of these spaces is compact. However, except for finite algebraic sets, no algebraic set is ever a Hausdorff space. In the old topological literature "compact" was taken to include the Hausdorff property, and this convention is still honored in algebraic geometry; therefore compactness in the modern sense is called "quasicompactness" in algebraic geometry. However, since every point is the zero set of the polynomials points are closed and so every variety satisfies the T_1 axiom. Every regular map of varieties is continuous in the Zariski topology. In fact, the Zariski topology is the weakest topology (with the fewest open sets) in which this is true and in which points are closed. This is easily verified by noting that the Zariski-closed sets are simply the intersections of the inverse images of by the polynomial functions, considered as regular maps into {{nowrap|\mathbb{A}^1.}} ==Spectrum of a ring==

In modern algebraic geometry, an algebraic variety is often represented by its associated scheme, which is a topological space (equipped with additional structures) that is locally homeomorphic to the spectrum of a ring. The spectrum of a commutative ring A, denoted {{nowrap|\operatorname{Spec} A,}} is the set of the prime ideals of equipped with the Zariski topology, for which the closed sets are the sets V(I) = \{\mathfrak{p} \in \operatorname{Spec} A \mid \mathfrak{p} \supseteq I\}. where I is an ideal. Again writing the distinguished open sets (or principal or basic open sets) of {{nowrap|\operatorname{Spec} A}} are the sets {{nowrap|D(f) = (\operatorname{Spec} A) \setminus V(f)}} for elements These sets form a base for the Zariski topology. To see the connection with the classical picture, note that for any set S of polynomials (over an algebraically closed field), it follows from Hilbert's Nullstellensatz that the points of (in the old sense) are exactly the tuples such that the ideal generated by the polynomials contains moreover, these are maximal ideals and by the "weak" Nullstellensatz, an ideal of any affine coordinate ring is maximal if and only if it is of this form. Thus, is "the same as" the maximal ideals containing To be slightly more explicit, let {{nowrap|\operatorname{Spm} A}} be the maximal spectrum of a commutative ring the set of its maximal ideals, and let k be an algebraically closed field. If I is an ideal, then under the classical definition of there are one-to-one correspondences V(I) \leftrightarrow \{\mathfrak{m} \in \operatorname{Spm} k[x_1, \dots, x_n] \mid \mathfrak{m} \supseteq I\} \leftrightarrow \operatorname{Spm} k[x_1, \dots, x_n]/I given by a \leftrightarrow (x_1 - a_1, \dots, x_n - a_n) \leftrightarrow (\overline{x_1} - a_1, \dots, \overline{x_n} - a_n) for where \overline{x_i} are the images of x_i under the natural projection If I is a radical ideal, then is the coordinate ring of which could be regarded as the ring of polynomial functions the global regular functions on Grothendieck's innovation in defining Spec for general commutative rings was to replace maximal ideals with all prime ideals; in this formulation, it is natural to simply generalize the correspondence between the closed set in affine space and the subset of the maximal spectrum of the polynomial ring that contains I to the definition of a closed set in the (prime) spectrum of a ring in the general commutative case. In another approach, we first observe that we can reinterpret a polynomial (k again algebraically closed) as a function \operatorname{ev}_f \colon \operatorname{Spm} k[x_1, \dots, x_n] \to k[x_1, \dots, x_n]/\mathfrak{m} \cong k mapping \mathfrak{m} \mapsto f \bmod \mathfrak{m} = f(a), where is the point to which \mathfrak{m} corresponds via the weak Nullstellensatz. In other words, we map the ideal to f evaluated at We can then regard an element of the polynomial ring as a function on the maximal ideals of the polynomial ring. Moreover, we observe that \operatorname{ev}_f(\mathfrak{m}) = 0 \iff f \in \mathfrak{m}, or, generalizing to an ideal {{nowrap|\operatorname{ev}_f(\mathfrak{m}) = 0, \quad \forall f \in I \iff \mathfrak{m} \supseteq I.}} We can thus view {{nowrap|\{\mathfrak{m} \in \operatorname{Spm} k[x_1, \dots, x_n] \mid \mathfrak{m} \supseteq I\}}} as the common set of "points" on which all the "functions" (more precisely, {{nowrap|\{\operatorname{ev}_f\}_{f \in I}}}) vanish. Generalizing this approach to arbitrary commutative rings, another way to interpret the modern definition (perhaps more similar to the original) is to realize that the elements of A can actually be thought of as functions on its prime ideals, {{nowrap|\operatorname{Spec} A.}} Simply, any prime ideal \mathfrak{p} has a corresponding residue field, which is the field of fractions of the quotient {{nowrap|A/\mathfrak{p},}} and any element of A has an image in this residue field. Furthermore, the elements that are actually in \mathfrak{p} are precisely those whose image vanishes at {{nowrap|\mathfrak{p}.}} So if we think of the map, associated to any element \alpha of \operatorname{ev}_{\alpha} \colon \bigl(\mathfrak{p} \in \operatorname{Spec} A \bigr) \mapsto \left(\frac{\alpha \bmod \mathfrak{p}}{1} \in \operatorname{Frac}(A/\mathfrak{p})\right) ("evaluation of "), which assigns to each prime ideal \mathfrak{p} the image of \alpha in the residue field of {{nowrap|\mathfrak{p},}} as a function on {{nowrap|\operatorname{Spec} A,}} whose values, admittedly, may lie in different fields at different points, then we have \operatorname{ev}_{\alpha}(\mathfrak{p}) = 0 \iff \alpha \in \mathfrak{p}. More generally, for any ideal {{nowrap|\operatorname{ev}_{\alpha}(\mathfrak{p}) = 0, \quad \forall \alpha \in I \iff \mathfrak{p} \supseteq I,}} so {{nowrap|V(I) = \{\mathfrak{p} \in \operatorname{Spec} A \mid \mathfrak{p} \supseteq I\}}} is the common set of "points" on which all the "functions" vanish, which is formally analogous to the classical definition. In fact, as noted above, they agree in the sense that when A is the ring of polynomials over some algebraically closed field the maximal ideals of A are identified with of elements of their residue fields are just and the "evaluation" maps are actually evaluation of polynomials at the corresponding For this special case, the classical definition is essentially the modern definition with only maximal ideals considered, and the interpretation of the modern definition as "zero sets of functions" agrees with the classical definition where they both make sense. Just as Spec replaces affine varieties, the Proj construction replaces projective varieties in modern algebraic geometry. Just as in the classical case, to move from the affine to the projective definition we need only replace "ideal" by "homogeneous ideal", though there is a complication involving the "irrelevant maximal ideal", which is discussed in the cited article. Examples • Spec the spectrum of a field k is the topological space with one element. • Spec {{nowrap|\mathbb{Z},}} the spectrum of the integers has a closed point for every prime number p corresponding to the maximal ideal {{nowrap|(p) \subseteq \mathbb{Z},}} and one non-closed generic point (i.e., whose closure is the whole space) corresponding to the zero ideal So the closed subsets of Spec \mathbb{Z} are precisely the whole space and the finite unions of closed points. • Spec the spectrum of the polynomial ring over a field such a polynomial ring is known to be a principal ideal domain and the irreducible polynomials are the prime elements of If k is algebraically closed, for example the field of complex numbers, a non-constant polynomial is irreducible if and only if it is linear, of the form for some element a of So, the spectrum consists of one closed point for every element a of k and a generic point, corresponding to the zero ideal, and the set of the closed points is homeomorphic with the affine line k equipped with its Zariski topology. Because of this homeomorphism, some authors use the term affine line for the spectrum of If k is not algebraically closed, for example the field of the real numbers, the picture becomes more complicated because of the existence of non-linear irreducible polynomials. In this case, the spectrum consists of one closed point for each monic irreducible polynomial, and a generic point corresponding to the zero ideal. For example, the spectrum of \mathbb{R}[t] consists of the closed points for a in {{nowrap|\mathbb{R},}} the closed points where are in \mathbb{R} and with negative discriminant and finally a generic point For any field, the closed subsets of Spec k[t] are finite unions of closed points, and the whole space. Further properties The most dramatic change in the topology from the classical picture to the new is that points are no longer necessarily closed; by expanding the definition, Grothendieck introduced generic points, which are the points with maximal closure, that is the minimal prime ideals. The closed points correspond to maximal ideals of However, the spectrum and projective spectrum are still T_0 spaces: given two points that are prime ideals of at least one of them, say does not contain the other. Then contains P but, of course, not Just as in classical algebraic geometry, any spectrum or projective spectrum is (quasi)compact, and if the ring in question is Noetherian then the space is a Noetherian topological space. However, these facts are counterintuitive: we do not normally expect open sets, other than connected components, to be compact, and for affine varieties (for example, Euclidean space) we do not even expect the space itself to be compact. This is one instance of the geometric unsuitability of the Zariski topology. Grothendieck solved this problem by defining the notion of properness of a scheme (actually, of a morphism of schemes), which recovers the intuitive idea of compactness: Proj is proper, but Spec is not. ==See also==