IDEALS AND THEIR INTEGRAL CLOSURE

Similar documents
arxiv:math/ v1 [math.ac] 4 Oct 2002

THE ASSOCIATED PRIMES OF LOCAL COHOMOLOGY MODULES OVER RINGS OF SMALL DIMENSION. Thomas Marley

A Filtration of the Sally Module and the Associated Graded Ring of an Ideal

A FORMULA FOR THE -core OF AN IDEAL

m-full AND BASICALLY FULL IDEALS IN RINGS OF CHARACTERISTIC p

m-full AND BASICALLY FULL IDEALS IN RINGS OF CHARACTERISTIC p

AN INEQUALITY INVOLVING TIGHT CLOSURE AND PARAMETER IDEALS. Dedicated to the memory of Professor Nicolae Radu

MATH 690 NOTES. 1. Associated graded rings

Primary Decompositions of Powers of Ideals. Irena Swanson

Modules, ideals and their. Rees algebras

COURSE SUMMARY FOR MATH 508, WINTER QUARTER 2017: ADVANCED COMMUTATIVE ALGEBRA

HILBERT POLYNOMIALS FOR THE EXTENSION FUNCTOR

M ath. Res. Lett. 15 (2008), no. 2, c International Press 2008 JOINT REDUCTIONS OF MONOMIAL IDEALS AND MULTIPLICITY OF COMPLEX ANALYTIC MAPS

arxiv:math/ v1 [math.ac] 4 Oct 2002

ALMOST GORENSTEIN RINGS

ADDENDUM TO FROBENIUS AND CARTIER ALGEBRAS OF STANLEY-REISNER RINGS [J. ALGEBRA 358 (2012) ]

arxiv: v2 [math.ac] 7 Nov 2017

Rees Algebras of Modules

arxiv:math/ v1 [math.ac] 15 Sep 2002

On the vanishing of Tor of the absolute integral closure

arxiv: v1 [math.ac] 23 Jun 2010

REDUCTION NUMBERS OF EQUIMULTIPLE IDEALS

Integral closures of ideals and rings

(dim Z j dim Z j 1 ) 1 j i

VANISHING THEOREMS FOR COMPLETE INTERSECTIONS. Craig Huneke, David A. Jorgensen and Roger Wiegand. August 15, 2000

ALMOST GORENSTEIN RINGS

ON THE IDEAL CASE OF A CONJECTURE OF HUNEKE AND WIEGAND 1. INTRODUCTION

Boundary of Cohen-Macaulay cone and asymptotic behavior of system of ideals

THE CORE OF ZERO-DIMENSIONAL MONOMIAL IDEALS

arxiv:math/ v1 [math.ac] 3 Apr 2006

Math 145. Codimension

Two theorems about maximal Cohen Macaulay modules

arxiv: v1 [math.ac] 19 May 2015

FINE BEHAVIOR OF SYMBOLIC POWERS OF IDEALS

D-MATH Algebraic Geometry FS 2018 Prof. Emmanuel Kowalski. Solutions Sheet 1. Classical Varieties

TIGHT CLOSURE IN NON EQUIDIMENSIONAL RINGS ANURAG K. SINGH

IF THE SOCLE FITS. Andrew R. Kustin and Bernd Ulrich

REFLEXIVE MODULES OVER GORENSTEIN RINGS

n-canonical modules over non-commutative algebras

FILTERED RINGS AND MODULES. GRADINGS AND COMPLETIONS.

Math 711: Lecture of September 7, Symbolic powers

arxiv:math/ v1 [math.ac] 19 Sep 2002 Ian M. Aberbach

ALGEBRAIC GEOMETRY COURSE NOTES, LECTURE 2: HILBERT S NULLSTELLENSATZ.

ACYCLIC COMPLEXES OF FINITELY GENERATED FREE MODULES OVER LOCAL RINGS

ABSTRACT NONSINGULAR CURVES

MIMS Technical Report No ( )

Gorenstein modules, finite index, and finite Cohen Macaulay type

Introduction to Arithmetic Geometry Fall 2013 Lecture #17 11/05/2013

On intersections of complete intersection ideals

LOCAL COHOMOLOGY IN COMMUTATIVE ALGEBRA AND ALGEBRAIC GEOMETRY

THE FROBENIUS FUNCTOR AND INJECTIVE MODULES

A degree bound for codimension two lattice ideals

Annihilation of Cohomology over Curve Singularities

COFINITENESS AND ASSOCIATED PRIMES OF LOCAL COHOMOLOGY MODULES

Effective Normality Criteria for Algebras of Linear Type

THE AUSLANDER BUCHSBAUM FORMULA. 0. Overview. This talk is about the Auslander-Buchsbaum formula:

The Hilbert functions which force the Weak Lefschetz Property

F -SINGULARITIES AND FROBENIUS SPLITTING NOTES 9/

GENERATING FUNCTIONS ASSOCIATED TO FROBENIUS ALGEBRAS

11. Dimension. 96 Andreas Gathmann

UNMIXED LOCAL RINGS WITH MINIMAL HILBERT-KUNZ MULTIPLICITY ARE REGULAR

NUMERICAL MACAULIFICATION

Honors Algebra 4, MATH 371 Winter 2010 Assignment 4 Due Wednesday, February 17 at 08:35

Citation Osaka Journal of Mathematics. 44(4)

arxiv: v1 [math.ac] 4 Nov 2012

10. Noether Normalization and Hilbert s Nullstellensatz

Frobenius maps on injective hulls and their applications Moty Katzman, The University of Sheffield.

BETTI NUMBERS AND DEGREE BOUNDS FOR SOME LINKED ZERO-SCHEMES

Lecture 4. Corollary 1.2. If the set of all nonunits is an ideal in A, then A is local and this ideal is the maximal one.

WHEN IS A NAKAYAMA CLOSURE SEMIPRIME?

LOCAL COHOMOLOGY MODULES WITH INFINITE DIMENSIONAL SOCLES

Extended Index. 89f depth (of a prime ideal) 121f Artin-Rees Lemma. 107f descending chain condition 74f Artinian module

On a Conjecture of Auslander and Reiten

Journal of Algebra 226, (2000) doi: /jabr , available online at on. Artin Level Modules.

DUALITY FOR KOSZUL HOMOLOGY OVER GORENSTEIN RINGS

ON ASSOCIATED GRADED RINGS OF NORMAL IDEALS. Sam Huckaba and Thomas Marley

PROBLEMS, MATH 214A. Affine and quasi-affine varieties

Algebraic Varieties. Chapter Algebraic Varieties

APPLICATIONS OF LOCAL COHOMOLOGY

CONSTRUCTIONS OF GORENSTEIN RINGS

Summer School & Conference Schedule

OPENNESS OF FID-LOCI

arxiv: v1 [math.ac] 24 Feb 2010

Decompositions Of Modules And Matrices

THE RADIUS OF A SUBCATEGORY OF MODULES

LINKAGE AND DUALITY OF MODULES

RINGS WITH A BOUNDED NUMBER OF GENERATORS FOR RIGHT IDEALS

WEAK NULLSTELLENSATZ

MATH 233B, FLATNESS AND SMOOTHNESS.

ALGEBRA EXERCISES, PhD EXAMINATION LEVEL

Integral Extensions. Chapter Integral Elements Definitions and Comments Lemma

E. GORLA, J. C. MIGLIORE, AND U. NAGEL

MATH 631: ALGEBRAIC GEOMETRY: HOMEWORK 1 SOLUTIONS

Toric Ideals, an Introduction

Integral Closures of Ideals in Completions of Regular Local Domains

Primary Decomposition

Lyubeznik Numbers of Local Rings and Linear Strands of Graded Ideals

Cellular Binomial Ideals. Primary Decomposition of Binomial Ideals

NEW CLASSES OF SET-THEORETIC COMPLETE INTERSECTION MONOMIAL IDEALS

DIRAC S THEOREM ON CHORDAL GRAPHS

Transcription:

IDEALS AND THEIR INTEGRAL CLOSURE ALBERTO CORSO (joint work with C. Huneke and W.V. Vasconcelos) Department of Mathematics Purdue University West Lafayette, 47907 San Diego January 8, 1997 1

SETTING Let R be a Noetherian ring a and I one of its ideals. The integral closure of I is the ideal I of all elements of R that satisfy an equation of the form X n + a 1 X n 1 + + a n 1 X + a n = 0, a i I i. The radical I consists of all the solutions in R of equations of the form X m b = 0, b I. In particular: I I I. I is integrally closed (resp. normal) if I = I (resp. I n = I n for all n). a Later we may even want to assume the ring to have other additional properties (such as: Cohen Macaulay, with infinite residue field, etc. 2

PROBLEMS For an ideal I of R we would like to give an answer to questions of the following kind: Find efficient and global criteria to test whether or not I is integrally closed. Comment: The criteria should involve natural objects associated with I: e.g. the powers of I, the radical of I, modules of syzygies, etc. If I fails the above tests, find a procedure to compute (part of) the integral closure of I. Comment: It is not an easy task. For example, if R is a polynomial ring over a field and I is a monomial ideal, I is then the monomial ideal defined by the integral convex hull of the exponent vectors of I. However, if I is binomial then I need not be binomial. When I integrally closed implies I normal. 3

POSSIBLE APPROACHES A consequence of the determinant trick is that for every finitely generated faithful R-module M then I IM: M I. In particular if I is integrally closed, for any such M, IM: M = I. We then need appropriate test modules for a given ideal I. An alternative approach is through the Rees algebra R[It] = R + It + I 2 t 2 + + I n t n + of I; one then looks for its integral closure inside R[t]: R + It + I 2 t 2 + R[t]. This is obviously wasteful of resources since the integral closure of all powers of I will be computed. Of course this could be profitably taken if it turns out that I is normal. 4

CRITERION Let I be a height unmixed ideal in a Cohen Macaulay ring R. Suppose that I is generically a complete intersection. Then the following conditions are equivalent: I is integrally closed; I = IL: L, where L = I: I. Remarks: An earlier version of this criterion had the condition I = IL: L replaced by I = IL: L 2. The proof in both cases is essentially the same, and it is based on the following two local criteria. 5

Theorem a : A LOCAL RESULT OF GOTO Let I be an ideal in a Noetherian ring R and assume that µ R (I) = height R (I) = g. Then the following conditions are equivalent: I = I, i.e. I is integrally closed; I n = I n, i.e. I is normal; for each p Ass R (R/I), the local ring R p is regular and ( IRp + p 2 ) R p λ Rp p 2 g 1. R p When this is the case, Ass R (R/I) = Min R (R/I) and I is generated by an R-regular sequence. a S. Goto: Integral closedness of complete-intersection ideals, J. Algebra 108 (1987), 151 160. 6

Theorem a+b : LINKAGE AND REDUCTION NUMBER Let (R, m) be a Cohen Macaulay local ring and let I = (z 1,..., z g ) be an ideal generated by a regular sequence inside a prime ideal p of height g. If we set L = I: p then L 2 = IL if one of the following two conditions holds: (l 1 ) R p is not a regular local ring; (l 2 ) R p is a regular local ring with dimension at least 2 and two of the z i s in p (2). a A. Corso, C. Polini and W. V. Vasconcelos: Links of prime ideals, Math. Proc. Camb. Phil. Soc. 115 (1994), 431 436. b A. Corso and C. Polini: Links of prime ideals and their Rees algebras, J. Algebra 178 (1995), 224 238. 7

ANOTHER USEFUL CRITERION Let R be a Gorenstein ring and let I be a Gorenstein ideal of codimension 3. Then the following conditions are equivalent: I is generically a complete intersection; I 2 : I = I. Remarks: In particular, if I is integrally closed then it is generically a complete intersection. Furthermore, one could combine this and the previous criterion to get a condition for a perfect Gorenstein ideal of codimension 3 to be integrally closed. However, this is not necessary as the next result shows. 8

GORENSTEIN IDEALS Let I be a Gorenstein ideal of codimension g 2 of a regular local ring R. Then the following conditions are equivalent: I is an integrally closed ideal; I = IL: L, where L = I: I. Comments: As a consequence of the proof, I is generically a complete intersection of the kind described in Goto s paper. Is it possible to find an easy, global criterion to characterize integrally closed ideals with type 2 (3, etc...)? 9

INTEGRAL CLOSEDNESS AND NORMALITY: ideals with linear presentation Theorem: Let k be a field of characteristic zero and let I R = k[x 1,..., x d ] be a Gorenstein ideal defined by the Pfaffians of a n n skew symmetric matrix ϕ with linear forms as entries. Suppose n = d + 1 (hence d is even) and that I is a complete intersection on the punctured spectrum. If I is integrally closed it is also normal. Remark: The proof is based on the Jacobian criterion. Corollary: Let k be a field of characteristic zero and let I R = k[x 1, x 2, x 3, x 4 ] be a Gorenstein ideal defined by the Pfaffians of a five by five skew symmetric matrix ϕ with linear forms as entries. If I is integrally closed it is also normal. 10

(COUNTER)EXAMPLE Let R = k[a, b, c, d] with a, b, c, d be variables and char(k) = 0. The Pfaffians of the 5 5 matrix ϕ 0 a 2 b 2 c 2 d 2 a 2 0 d 2 ab c 2 ϕ = b 2 d 2 0 a 2 ab, c 2 ab a 2 0 b 2 d 2 c 2 ab b 2 0 define an height 3 Gorenstein ideal I such that I 2 : I = I and I = IL: L, where L = I: I. Hence I is integrally closed BUT it is not normal. Note that I 2 is integrally closed as well. Is I 3 BAD? 11

INTEGRAL CLOSEDNESS AND NORMALITY: complete intersections of codimension 2 Theorem: Let R be a regular local ring and I = (a, b) a complete intersection of codimension 2. Then I is normal, i.e., for all n 1. I n = (I) n Remark: For dimension 2 this is a very well known result of Zariski. 12

A METHOD TO COMPUTE THE INTEGRAL CLOSURE If I = (a 1,..., a n ) then one can represent its Rees algebra as R[It] = R[T 1,..., T n ]/P, where P is the kernel of the map ϕ : R[T 1,..., T n ] R[It] that sends T i to a i t. If R[It] is an affine domain over a field of characteristic zero and Jac denotes its Jacobian ideal, then the ring Hom R[It] (Jac 1, Jac 1 ) = = (Jac Jac 1 ) 1, is guaranteed to be larger than R[It] if the ring is not already normal. Naturally, this process can be repeated several times until the integral closure of R[It] has been reached. The degree one component of the final output gives the desired integral closure of I. 13

EXAMPLE Let k be a field of characteristic zero and let I R = k[x, y] be the codimension 2 complete intersection I = (x 3 + y 6, xy 3 y 5 ). Iterating three times the method outlined before we can compute I. To be precise, the three outputs are: J 1 = (x 3 + y 6, xy 3 y 5, y 8 ), J 2 = (x 3 + y 6, xy 3 y 5, x 2 y 2 y 6, y 7 ), J 3 = I = (xy 3 y 5, y 6, x 3, x 2 y 2 ). Note that I is also a normal ideal. For the records, despite the fact that the original setting for the problem is a polynomial ring in 2 variables over a field of characteristic zero, overall we had to make use of 18 additional variables: quite a waste! 14

FINAL COMMENT If I is a complete intersection, several initial iterations of the process may be avoided (see [CP2] and [PU]). If I is an m-primary complete intersection of a Gorenstein local ring (R, m) and I m s but I m s+1 then one has an increasing sequence of ideals I k = I: m k satisfying I 2 k = II k for k = 1,..., s if dim(r) 3 or for k = 1,... s 1 if R is a regular local ring and dim(r) = 2. This says that the I k s are contained in the integral closure of I. Hence, instead of computing the integral closure of R[It] one may start directly from R[I s t] (or R[I s 1 t] if R is a regular local ring and dim(r) = 2). 15

If I is not primary to the maximal ideal one may use instead the sequence of ideals I k = I: ( I) (k) = I: ( I) k, provided that at each localization at the associated primes of I the conditions in [CP2] and [PU] are satisfied so that I 2 k = II k for all the k s in the appropriate range. In the case of the example: R = k[x, y] and I = (x 3 + y 6, xy 3 y 5 ) one has that I (x, y) 3. Since dim(r) = 2 one can consider only the cases k = 1, 2 = s 1. We can check that J 1 = I: m J 2 = I: m 2. 16

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback