That is to say, b is a root of a monic polynomial over A. The set of elements of B that are integral over A is called the integral closure of A in B. It is a subring of B containing A. If every element of B is integral over A, then we say that B is integral over A, or equivalently B is an integral extension of A.
If A, B are fields, then the notions of "integral over" and of an "integral extension" are precisely "algebraic over" and "algebraic extensions" in field theory (since the root of any polynomial is the root of a monic polynomial).
The case of greatest interest in number theory is that of complex numbers integral over Z (e.g., or ); in this context, the integral elements are usually called algebraic integers. The algebraic integers in a finite extension field k of the rationals Q form a subring of k, called the ring of integers of k, a central object of study in algebraic number theory.
In this article, the term ring will be understood to mean commutative ring with a multiplicative identity.
Integral closure in algebraic number theory
Integral closure of integers in rationals
Integers are the only elements of Q that are integral over Z. In other words, Z is the integral closure of Z in Q.
The Gaussian integers, are the complex numbers of the form , and are integral over Z. is then the integral closure of Z in . Typically this ring is denoted .
The integral closure of Z in is the ring
this example and the previous one are examples of quadratic integers. The integral closure of a quadratic extension can be found by constructing the minimal polynomial of an arbitrary element and finding number-theoretic criterion for the polynomial to have integral coefficients. This analysis can be found in the quadratic extensions article.
Roots of unity
Ring of algebraic integers
The integral closure of Z in the field of complex numbers C, or the algebraic closure is called the ring of algebraic integers.
Integral closure in geometry
In geometry, integral closure is closely related with normalization and normal schemes. It is the first step in resolution of singularities since it gives a process for resolving singularities of codimension 1.
- For example, the integral closure of is the ring since geometrically, the first ring corresponds to the -plane unioned with the -plane. They have a codimension 1 singularity along the -axis where they intersect.
- Let a finite group G act on a ring A. Then A is integral over AG the set of elements fixed by G. See ring of invariants.
- Let R be a ring and u a unit in a ring containing R. Then
- u−1 is integral over R if and only if u−1 ∈ R[u].
- is integral over R.
- The integral closure of the homogeneous coordinate ring of a normal projective variety X is the ring of sections
Integrality in algebra
- If is an algebraic closure of a field k, then is integral over
- The integral closure of C[[x]] in a finite extension of C((x)) is of the form (cf. Puiseux series)
Let B be a ring, and let A be a subring of B. Given an element b in B, the following conditions are equivalent:
- (i) b is integral over A;
- (ii) the subring A[b] of B generated by A and b is a finitely generated A-module;
- (iii) there exists a subring C of B containing A[b] and which is a finitely-generated A-module;
- (iv) there exists a faithful A[b]-module M such that M is finitely generated as an A-module.
- Theorem Let u be an endomorphism of an A-module M generated by n elements and I an ideal of A such that . Then there is a relation:
This theorem (with I = A and u multiplication by b) gives (iv) ⇒ (i) and the rest is easy. Coincidentally, Nakayama's lemma is also an immediate consequence of this theorem.
Integral closure forms a ring
It follows from the above four equivalent statements that the set of elements of that are integral over forms a subring of containing . (Proof: If x, y are elements of that are integral over , then are integral over since they stabilize , which is a finitely generated module over and is annihilated only by zero.) This ring is called the integral closure of in .
Transitivity of integrality
Another consequence of the above equivalence is that "integrality" is transitive, in the following sense. Let be a ring containing and . If is integral over and integral over , then is integral over . In particular, if is itself integral over and is integral over , then is also integral over .
Integral closed in fraction field
If happens to be the integral closure of in , then A is said to be integrally closed in . If is the total ring of fractions of , (e.g., the field of fractions when is an integral domain), then one sometimes drops the qualification "in " and simply says "integral closure of " and " is integrally closed." For example, the ring of integers is integrally closed in the field .
Transitivity of integral closure with integrally closed domains
Let A be an integral domain with the field of fractions K and A' the integral closure of A in an algebraic field extension L of K. Then the field of fractions of A' is L. In particular, A' is an integrally closed domain.
Transitivity in algebraic number theory
This situation is applicable in algebraic number theory when relating the ring of integers and a field extension. In particular, given a field extension the integral closure of in is the ring of integers .
Note that transitivity of integrality above implies that if is integral over , then is a union (equivalently an inductive limit) of subrings that are finitely generated -modules.
If is noetherian, transitivity of integrality can be weakened to the statement:
- There exists a finitely generated -submodule of that contains .
Relation with finiteness conditions
Finally, the assumption that be a subring of can be modified a bit. If is a ring homomorphism, then one says is integral if is integral over . In the same way one says is finite ( finitely generated -module) or of finite type ( finitely generated -algebra). In this viewpoint, one has that
- is finite if and only if is integral and of finite type.
Or more explicitly,
- is a finitely generated -module if and only if is generated as an -algebra by a finite number of elements integral over .
An integral extension A ⊆ B has the going-up property, the lying over property, and the incomparability property (Cohen–Seidenberg theorems). Explicitly, given a chain of prime ideals in A there exists a in B with (going-up and lying over) and two distinct prime ideals with inclusion relation cannot contract to the same prime ideal (incomparability). In particular, the Krull dimensions of A and B are the same. Furthermore, if A is an integrally closed domain, then the going-down holds (see below).
In general, the going-up implies the lying-over. Thus, in the below, we simply say the "going-up" to mean "going-up" and "lying-over".
When A, B are domains such that B is integral over A, A is a field if and only if B is a field. As a corollary, one has: given a prime ideal of B, is a maximal ideal of B if and only if is a maximal ideal of A. Another corollary: if L/K is an algebraic extension, then any subring of L containing K is a field.
Let B be a ring that is integral over a subring A and k an algebraically closed field. If is a homomorphism, then f extends to a homomorphism B → k. This follows from the going-up.
Geometric interpretation of going-up
Let be an integral extension of rings. Then the induced map
is a closed map; in fact, for any ideal I and is surjective if f is injective. This is a geometric interpretation of the going-up.
Geometric interpretation of integral extensions
Let B be a ring and A a subring that is a noetherian integrally closed domain (i.e., is a normal scheme.) If B is integral over A, then is submersive; i.e., the topology of is the quotient topology. The proof uses the notion of constructible sets. (See also: torsor (algebraic geometry).)
Integrality, base-change, universally-closed, and geometry
If is integral over , then is integral over R for any A-algebra R. In particular, is closed; i.e., the integral extension induces a "universally closed" map. This leads to a geometric characterization of integral extension. Namely, let B be a ring with only finitely many minimal prime ideals (e.g., integral domain or noetherian ring). Then B is integral over a (subring) A if and only if is closed for any A-algebra R. In particular, every proper map is universally closed.
Galois actions on integral extensions of integrally closed domains
- Proposition. Let A be an integrally closed domain with the field of fractions K, L a finite normal extension of K, B the integral closure of A in L. Then the group acts transitively on each fiber of .
Proof. Suppose for any in G. Then, by prime avoidance, there is an element x in such that for any . G fixes the element and thus y is purely inseparable over K. Then some power belongs to K; since A is integrally closed we have: Thus, we found is in but not in ; i.e., .
Application to algebraic number theory
The galois group then acts on all of the prime ideals lying over a fixed prime ideal . That is, if
then there is a Galois action on the set . This is called the Splitting of prime ideals in Galois extensions.
The same idea in the proof shows that if is a purely inseparable extension (need not be normal), then is bijective.
Let A, K, etc. as before but assume L is only a finite field extension of K. Then
- (i) has finite fibers.
- (ii) the going-down holds between A and B: given , there exists that contracts to it.
Indeed, in both statements, by enlarging L, we can assume L is a normal extension. Then (i) is immediate. As for (ii), by the going-up, we can find a chain that contracts to . By transitivity, there is such that and then are the desired chain.
Let A ⊂ B be rings and A' the integral closure of A in B. (See above for the definition.)
Integral closures behave nicely under various constructions. Specifically, for a multiplicatively closed subset S of A, the localization S−1A' is the integral closure of S−1A in S−1B, and is the integral closure of in . If are subrings of rings , then the integral closure of in is where are the integral closures of in .
The integral closure of a local ring A in, say, B, need not be local. (If this is the case, the ring is called unibranch.) This is the case for example when A is Henselian and B is a field extension of the field of fractions of A.
If A is a subring of a field K, then the integral closure of A in K is the intersection of all valuation rings of K containing A.
There is also a concept of the integral closure of an ideal. The integral closure of an ideal , usually denoted by , is the set of all elements such that there exists a monic polynomial
with with as a root. Note this is the definition that appears, for example, in Eisenbud and is different from Bourbaki's and Atiyah–MacDonald's definition.
For noetherian rings, there are alternate definitions as well.
- if there exists a not contained in any minimal prime, such that for all .
- if in the normalized blow-up of I, the pull back of r is contained in the inverse image of I. The blow-up of an ideal is an operation of schemes which replaces the given ideal with a principal ideal. The normalization of a scheme is simply the scheme corresponding to the integral closure of all of its rings.
The notion of integral closure of an ideal is used in some proofs of the going-down theorem.
Let B be a ring and A a subring of B such that B is integral over A. Then the annihilator of the A-module B/A is called the conductor of A in B. Because the notion has origin in algebraic number theory, the conductor is denoted by . Explicitly, consists of elements a in A such that . (cf. idealizer in abstract algebra.) It is the largest ideal of A that is also an ideal of B. If S is a multiplicatively closed subset of A, then
If B is a subring of the total ring of fractions of A, then we may identify
Example: Let k be a field and let (i.e., A is the coordinate ring of the affine curve .) B is the integral closure of A in . The conductor of A in B is the ideal . More generally, the conductor of , a, b relatively prime, is with .
Suppose B is the integral closure of an integral domain A in the field of fractions of A such that the A-module is finitely generated. Then the conductor of A is an ideal defining the support of ; thus, A coincides with B in the complement of in . In particular, the set , the complement of , is an open set.
Finiteness of integral closure
An important but difficult question is on the finiteness of the integral closure of a finitely generated algebra. There are several known results.
The integral closure of a Dedekind domain in a finite extension of the field of fractions is a Dedekind domain; in particular, a noetherian ring. This is a consequence of the Krull–Akizuki theorem. In general, the integral closure of a noetherian domain of dimension at most 2 is noetherian; Nagata gave an example of dimension 3 noetherian domain whose integral closure is not noetherian. A nicer statement is this: the integral closure of a noetherian domain is a Krull domain (Mori–Nagata theorem). Nagata also gave an example of dimension 1 noetherian local domain such that the integral closure is not finite over that domain.
Let A be a noetherian integrally closed domain with field of fractions K. If L/K is a finite separable extension, then the integral closure of A in L is a finitely generated A-module. This is easy and standard (uses the fact that the trace defines a non-degenerate bilinear form.)
Let A be a finitely generated algebra over a field k that is an integral domain with field of fractions K. If L is a finite extension of K, then the integral closure of A in L is a finitely generated A-module and is also a finitely generated k-algebra. The result is due to Noether and can be shown using the Noether normalization lemma as follows. It is clear that it is enough to show the assertion when L/K is either separable or purely inseparable. The separable case is noted above; thus, assume L/K is purely inseparable. By the normalization lemma, A is integral over the polynomial ring . Since L/K is a finite purely inseparable extension, there is a power q of a prime number such that every element of L is a q-th root of an element in K. Let be a finite extension of k containing all q-th roots of coefficients of finitely many rational functions that generate L. Then we have: The ring on the right is the field of fractions of , which is the integral closure of S; thus, contains . Hence, is finite over S; a fortiori, over A. The result remains true if we replace k by Z.
The integral closure of a complete local noetherian domain A in a finite extension of the field of fractions of A is finite over A. More precisely, for a local noetherian ring R, we have the following chains of implications:
- (i) A complete A is a Nagata ring
- (ii) A is a Nagata domain A analytically unramified the integral closure of the completion is finite over the integral closure of A is finite over A.
Noether's normalization lemma
Noether's normalisation lemma is a theorem in commutative algebra. Given a field K and a finitely generated K-algebra A, the theorem says it is possible to find elements y1, y2, ..., ym in A that are algebraically independent over K such that A is finite (and hence integral) over B = K[y1,..., ym]. Thus the extension K ⊂ A can be written as a composite K ⊂ B ⊂ A where K ⊂ B is a purely transcendental extension and B ⊂ A is finite.
In algebraic geometry, a morphism of schemes is integral if it is affine and if for some (equivalently, every) affine open cover of Y, every map is of the form where A is an integral B-algebra. The class of integral morphisms is more general than the class of finite morphisms because there are integral extensions that are not finite, such as, in many cases, the algebraic closure of a field over the field.
Absolute integral closure
Let A be an integral domain and L (some) algebraic closure of the field of fractions of A. Then the integral closure of A in L is called the absolute integral closure of A. It is unique up to a non-canonical isomorphism. The ring of all algebraic integers is an example (and thus is typically not noetherian.)
- Normal scheme
- Noether normalization lemma
- Algebraic integer
- Splitting of prime ideals in Galois extensions
- Torsor (algebraic geometry)
- The above equation is sometimes called an integral equation and b is said to be integrally dependent on A (as opposed to algebraic dependent.)
- Milne, Theorem 6.4 harvnb error: no target: CITEREFMilne (help)
- Kaplansky, 1.2. Exercise 4.
- Hartshorne 1977, Ch. II, Exercise 5.14
- This proof is due to Dedekind (Milne, ANT). Alternatively, one can use symmetric polynomials to show integral elements form a ring. (loc cit.)
- Chapter 2 of Huneke and Swanson 2006
- Kaplansky 1970, Theorem 42 harvnb error: no target: CITEREFKaplansky1970 (help)
- Bourbaki 2006, Ch 5, §2, Corollary 4 to Theorem 1. harvnb error: no target: CITEREFBourbaki2006 (help)
- Matsumura 1970, Ch 2. Theorem 7
- Bourbaki 2006, Ch 5, §1, Proposition 5 harvnb error: no target: CITEREFBourbaki2006 (help)
- Atiyah–MacDonald 1969, Ch 5. Exercise 35 harvnb error: no target: CITEREFAtiyah–MacDonald1969 (help)
- "Section 32.14 (05JW): Universally closed morphisms—The Stacks project". stacks.math.columbia.edu. Retrieved 2020-05-11.
- Stein. Computational Introduction to Algebraic Number Theory (PDF). p. 101.
- An exercise in Atiyah–MacDonald.
- Bourbaki 2006, Ch 5, §1, Proposition 9 harvnb error: no target: CITEREFBourbaki2006 (help)
- Proof: Let be a ring homomorphism such that if is homogeneous of degree n. The integral closure of in is , where is the integral closure of A in B. If b in B is integral over A, then is integral over ; i.e., it is in . That is, each coefficient in the polynomial is in A.
- Chapter 12 of Huneke and Swanson 2006
- Swanson 2006, Example 12.2.1 harvnb error: no target: CITEREFSwanson2006 (help)
- Swanson 2006, Exercise 4.9 harvnb error: no target: CITEREFSwanson2006 (help)
- Atiyah–MacDonald 1969, Ch 5. Proposition 5.17 harvnb error: no target: CITEREFAtiyah–MacDonald1969 (help)
- Hartshorne 1977, Ch I. Theorem 3.9 A
- Swanson 2006, Theorem 4.3.4 harvnb error: no target: CITEREFSwanson2006 (help)
- Matsumura 1970, Ch 12
- Chapter 4 of Reid.
- Melvin Hochster, Math 711: Lecture of September 7, 2007
- M. Atiyah, I.G. Macdonald, Introduction to Commutative Algebra, Addison–Wesley, 1994. ISBN 0-201-40751-5
- Nicolas Bourbaki, Algèbre commutative, 2006.
- Eisenbud, David, Commutative Algebra with a View Toward Algebraic Geometry, Graduate Texts in Mathematics, 150, Springer-Verlag, 1995, ISBN 0-387-94268-8.
- Kaplansky, Irving (September 1974). Commutative Rings. Lectures in Mathematics. University of Chicago Press. ISBN 0-226-42454-5.
- Hartshorne, Robin (1977), Algebraic Geometry, Graduate Texts in Mathematics, 52, New York: Springer-Verlag, ISBN 978-0-387-90244-9, MR 0463157
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- H. Matsumura Commutative ring theory. Translated from the Japanese by M. Reid. Second edition. Cambridge Studies in Advanced Mathematics, 8.
- J. S. Milne, "Algebraic number theory." available at http://www.jmilne.org/math/
- Huneke, Craig; Swanson, Irena (2006), Integral closure of ideals, rings, and modules, London Mathematical Society Lecture Note Series, 336, Cambridge, UK: Cambridge University Press, ISBN 978-0-521-68860-4, MR 2266432
- M. Reid, Undergraduate Commutative Algebra, London Mathematical Society, 29, Cambridge University Press, 1995.
- Irena Swanson, Integral closures of ideals and rings
- Do DG-algebras have any sensible notion of integral closure?
- Is always an integral extension of for a regular sequence ?]