Complete Intersections

Satyagopal Mandal

Department of Mathematics

University of Kansas

Office: 502 Snow Hall Phone: 785-864-5180

e-mail: mandal@math.ukans.edu

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Cancellation of projective modules and complete intersections

This talk is on the joint work with Bangere Purnaprajna.

We first state the following theorem of Bloch-Murthy-Szpiro ([BMS]).

Theorem 1.1 Let R=k[X₁,X₂,X₃,X₄] be a polynomial ring over an algebraically closed field k and I be an ideal of height 2 in R and A=R/I, such that X = Spec(R/I) is smooth over k. Let $ω$ _I= $Λ$ ²(I/I²)^-1 and K_X = C₁( $ω$ _I) be the canonical divisor of X. If rK_X² =0 in the Chow group CH²(X), for some integer r>0, then X is set-theoretically complete intersection.

Following theorem is helpful to understand the statement of this theorem K-theoretically.

Theorem 3.2 Let X =Spec(A) be a smooth affine algebra over an algebraically closed field k. Assume that projective A-modules of rank 2 have cancellation property. Let L be a projective A-module of rank one. Then the following conditions are equivalent:

L is generated by 2 elements.
C₁(L)² =0 in CH²(X).
L $⊕$ L^-1 $≡$ A².

We will try to give a 5-dimentional version of the theorem 1.1 assuming that projective moduled of rank n-1 have cancellation property, where n is the dimention of the ring.

For (an increasing sequence of) positive integers n, Mohan Kumar ([MK]) constructed smooth affine algebras A with dim A = n and stably free projective A-modules of rank n-2 that are not free. He also posed the following question.

LRC-problem: Let A be a (smooth) affine algebra of dimension n over an algebraically closed field k. Does the projective A-modules of rank n-1 have the cancellation property? That is, for a projective A-module P with rank(P)=n-1, does P $⊕$ A $≡$ Q $⊕$ A $⇒$ P $≡$ Q?

If LRC-problem has an affirmative answer for 3-folds, then we prove a three dimensional analogue of the above theorem of Bloch-Murthy-Szpiro.

Let us give some preliminaries:

Let A be commutative noetherian ring .

Let CP(A) denote the catagory of finitely generated projective A-modules.
Let CFPD(A) denote the catagory of finitely generated A-modules with finite projective dimension.
Let K₀(A) denote the Grothendieck group of CP(A).
Let G₀(A) denote the Grothendieck group of CFPD(A).
Exercise. Prove that the natural map K₀(A) → G₀(A) is an isomorphism.

Before we go into our main results we state the following (monic polynomial version of) theorem of Ferrand and Szpiro.

Lemma 2.1 Let R= A[X] be a polynomial ring over a noetherian commutative ring A and I be a locally complete intersection ideal of height 2 in R. Assume that I contains a monic polynomial and there is a surjective map I/I² $→ ω$ _I = Ext²(R/I,R). Then I is set theoretically generated by 2 elements.

Proof.

Let J be defined by the exact sequence

0 $→$ J/I² $→$ I/I² $→$ $ω$ _I $→$ 0

Then J is a locally complete intersection ideal with rad(J) =rad(I) and

ω

_J = Ext²(R/J,R) = Ext¹(J,R) is one generated .

The generator e of Ext¹(J,R) correcpond to an exact sequence

0 $→$ R $→$ P $→$ J $→$ 0

It follows that P is a projective R-module of rank 2. Since J contains a monic polynomial, we have P_f $≡ R$ _f². Hence by the theorem of Quillen-Suslin, it follows that P is free and hence J is complete intersection ideal.

Exercise. Why P is projective? So, the main Idea is to get a map like in this lemma.

2 Main Results

We now prove a lemma which is a three dimensional analogue of a result in [BMS]. Lemma 2.2 Let R=R'[X] be polynomial ring over a noetherian commutative ring R' with dim R' =4 (so dim R=5). Let I be a locally complete intersection ideal of height 2 in R that contains a monic polynomial and A= R/I. Assume that all rank 2 projective A=R/I modules have cancellation property. Then

I/I² $≡$ A $⊕ &omega$ ^-1
Consider the following conditions
1. $ω$ is generated by two elements.
2. I/I² $≡ ω ⊕ ω$ ^-2
3. $ω$ ^-2 is generated by 2 elements.
Then a) $⇒$ b) $⇒$ c).

Proof.

dim A =3.

0 $→$ P $→$ Rⁿ $→$ I $→$ 0

n-1.

rank P = n-1 > dim R

P_f $≡ R$ _f^n-1.

P $≡ R$ ^n-1.

0 $→$ L $→$ A^n-1 $→$ Aⁿ $→$ I/I² $→$ 0

[I/I²] = [L]+[A]

K₀(A).

dim A-modules

I/I² $≡$ L $⊕$ A.

$Λ$ ² I/I² = L = $ω$ ^-1.

I/I² $≡$ A $⊕$ $ω$ ^-1

Now we prove the second statement:

a) $⇒$ b): By 1) we have I/I² $≡$ $ω$ ^-1 $⊕$ A and also A² $≡$ $ω$ $⊕ ω$ ^-1. So,

I/I² $⊕$ A $≡$ (A $⊕ ω$ ^-1) $⊕$ A $≡$ $ω$ ^-1 $⊕$ A² $≡$ $ω$ ^-1 $⊕$ ( $ω$ $⊕ ω$ ^-1)
$≡$ $ω$ $⊕$ ( $ω$ ^-1 $⊗$ A²) $≡$ $ω$ $⊕ ω$ ^-1 $⊗$ ( $ω$ $⊕ ω$ ^-1) $≡$ $ω$ $⊕$ A $⊕ ω$ ^-2.

Since all rank 2 projective A-modules have cancellation property, we have I/I² $≡$ $ω$ $⊕ ω$ ^-2.

b) $⇒$ c): By 1) and b) it follows that

A $⊕ ω$ ^-1 $≡$ $ω$ $⊕ ω$ ^-2.

A $⊕ ω$ $≡$ $ω$ ^-1 $⊕ ω$ ².

A² $⊕ ω$ $≡$ (A $⊕ ω$ ^-1) $⊕ ω$ ² $≡$ I/I² $⊕ ω$ ² $≡$ ( $ω$ $⊕ ω$ ^-2) $⊕ ω$ ²

A-modules

$ω$

A² $≡$ $ω$ ^-2 $⊕ ω$ ².

$ω$ ²

Following theorem relates the cancellation property of rank 2 projective modules with set theoretic complete intersection property of height 2 locally complete intersection ideals.

Theorem 2.1 Let R=R'[X] be a polynomial ring over a noetherian commutative ring R' with dim R' =4 (so dim R=5). Let I $⊆$ R be a locally complete intersection ideal of height 2 that contains a monic polynomial and A = R/I. Assume that projective A-modules of rank 2 have the cancellation property. Let $ω$ = Ext²(A,R). Assume that $ω$ ^r is generated by 2 elements, for some integer r ≥1. Then I is a set-theoretic complete intersection ideal.

Proof.

I/I² $≡$ A $⊕ ω$ ^-1.

0 $→$ A $→$ I/I² $→$ $ω$ ^-1 $→$ 0,

A $→$ I/I²

f $∈$ I.

I=Rf + I' ,

I² $&sube$ I' $&sube$ I

I'/I² $≡$ $ω$ ^-1.

J=I^r+Rf.

p $∈$ Spec(R)

I_p = (f,g),

$ω$ ^-1.

J_p= (f,g)^r + R_pf.

J_p=(g^r,f),

Let L be the cokernel of the map given by f as follows

f: R/J $→$ J/J² $→$ L $→$ 0.

J_p

(f,g^r)

Since rad(I) = rad(J), all rank 2 projective R/J-modules also have cancellation property. By the above lemma, we have J/J² $≡$ R/J $⊕ ω$ _J^-1 and L $≡$ $ω$ _J^-1. It follows that

J/J² $≡$ (R/J)f $⊕ ω$ _J^-1.
$ω$ _J^-1 $≡$ J/(J²+Rf).

Consider the exact sequence

0 $→$ R/J $→$ J/J² $→$ $ω$ _J^-1 $→$ .

R/I

0 $→$ R/I $→$ J/IJ $→$ $ω$ _J^-1 $⊗$ R/I $→$ 0

$ω$ _J^-1 $⊗$ R/I $≡$ J/(IJ,f) $≡$ (I^r,f)/(I^r+1,f) $≡$ $ω$ _I^r,

$ω$ _J^-1

A² $≡$ $ω$ _J^-1 $⊕ ω$ _J.

2a) $⇒$ 2b),

J/J² $→$ $ω$ _J.

Now it follows from lemma 2.1 that J is set theoretically generated by 2 elements. This completes the proof of this theorem.

Now we give a criterion for locally complete intersection ideal of height 2, in the polynomial ring R, to be ideal theoretically generated by dim R -2 elements.

Theorem 2.2 Let R=R'[X] be the polynomial ring over a noetherian commutative R'. Assume dim R =n ≥ 3. Suppose I is a locally complete intersection ideal of height 2 that contains a monic polynomial and A=R/I. Assume that all projective A-modules of rank n-3. have cancellation property. Write $ω$ =Ext²(A,R). Then the following conditions are equivalent:

I is generated by n-2 elements,
I/I² is generated by n-2 elements,
$ω$ is generated by n-3 elements.

Proof.

1) $⇒$ 2):

2) $⇒$ 3): We have the following exact sequence:

0 $→$ P $→$ R^m $→$ I $→$ 0

rank(P) > dim R.

P_f

≡

^m-1

f $∈$ I

So, by the theorem of Quillen and Suslin, P $≡$ R^m-1.

By tensoring the above sequence with A=R/I, we get the following exact sequence:

0 $→$ L $→$ A^m-1 $→$ A^m $→$ I/I² $→$ 0

L $≡ Λ$ ² I/I² $≡$ $ω$ ^-1.

[I/I²]=[ $ω$ ^-1 $⊕$ A]

I/I² $⊕$ A^k $≡$ $ω$ ^-1 $⊕$ A^k+1

Since I/I² is generated by n-2 elements, we have a surjective map A^n-2+k $→ ω$ ^-1 $⊕$ A^k+1.

Therefore,

Q $⊕ ω$ ^-1 $⊕$ A^k+1 $≡$ A^n-2+k.

n-3

A^n-3 $≡$ Q $⊕ ω$ ^-1.

$ω$

n-3

3) $⇒$ 1): Since $ω$ is n-3 generated, by the argument of Serre (see [Mu]), there is an exact sequence

0 $→$ R^n-3 $→$ P $→$ I $→$ 0

P_f

P $≡$ R^n-2.

n-2

Theorem 2.3 Let R' be a smooth affine algebra, with dim R'=n-1, over an algebraically closed field k, with trivial differential module $Ω$ _R'/k $≡$ R'^n-1. Let R=R'[X] be the polynomial ring. Assume n=dim R ≥ 5. Let I be an ideal of R so that A = R/I is smooth and let I contain a monic polynomial. Assume that n-2 ≥ dim A +2 or height(I)=1,2. In case height (I) =1, assume that all projective A-modules of rank n -2 have cancellation property. Then the following conditions are equivalent:

I is generated by n-2 elements.
I/I² is generated by n-2 elements.
$Ω$ _A/k has a free direct summand of rank 2.

Proof.

1) $⇒$ 2):

2) $⇒$ 3): Consider the sequence

0 $→$ I/I² $→ Ω$ _R/k / I $Ω$ _R/k→ Ω_A/k $→$ 0

The sequence is exact. Also note that

$Ω$ _R/k $≡
Ω$ _R'/k ⊗ R $⊕$ RdX $≡$ Rⁿ.

I/I² $⊕ Ω$ _A/k $≡$ Aⁿ

By 2), we have I/I² $⊕$ Q $≡$ A^n-2. So, in K₀(A), we have [A²] + [Q] = [ $Ω$ _A/k]. By cancellation theorem of Suslin, we have $Ω$ _A/k $≡$ A² $⊕$ Q.

3) $⇒$ 2): We have $Ω$ _A/k $≡$ A² $⊕$ P and I/I² $⊕ Ω$ _A/k $≡$ Aⁿ So,

I/I² $⊕$ A² $⊕$ P $≡$ Aⁿ.

height(I)=1

I/I² $⊕$ P $≡$ A^n-2.

2) $⇒$ 1): If n-2 ≥ dim (A) +2, then it follows from [Ma1] that I is n-2 generated. If height(I) =1 then I is one generated. If height(I)=2 it follows from the above theorem.

3 Smooth 3-folds in A⁵

Recall that for any smooth affine variety X over an algebraically closed field k, the Chow group A₀(X) =Aⁿ(X) is torsion free (see [Sr] and [Mu]).

Notation 3.1 Let A a smooth affine algebra over an algebraically closed field k and X=Spec(A).

A^r(X) will denote the Chow group of cycles of codimension r.
For a projective A-module P, C_i(P) $∈$ Aⁱ(X) will denote the i-th Chern class of P.

Following is a restatement of the theorem of Murthy and Mohan Kumar ([MKM]) in our context of LRC-question.

Theorem 3.1 Let X =Spec(A) be a smooth affine 3-fold over an algebraically closed field k. Assume that projective A-modules of all rank have cancellation property. Then, for any two projective modules P and Q of same rank, P $≡$ Q if and only if C_i(P) = C_i(Q) for i=1,2,3.

Proof.

$⇒$

( $⇐$ ) The theorem of Mohan Kumar and Murthy ([MKM]) implies that P and Q are stably isomorphic. Now P $≡$ Q by the cancellation property.

L is generated by 2 elements.
C₁(L)² =0 in A²(X).
L $⊕$ L^-1 $≡$ A².

Proof.

1) $⇒$ 2):

L $⊕$ L^-1 $≡$ A².

C(L $⊕$ L^-1) = 1

(1+C^-1(L))(1-C^-1(L)) =1

C^-1(L)² =0.

2) $⇒$ 3): It follows that the total Chern class C(L $⊕$ L^-1) =1. Hence [L] $⊕$ [L^-1] = [A²] in K₀(A) and by cancellation L $⊕$ L^-1 $≡$ A².

3) $⇒$ 1): This implication is obvious.

Theorem 3.3 Suppose k is an algebraically closed field and R=R'[X] a polynomial ring over an affine algebra R' with dim R' =4. Let I be a locally complete intersection ideal in R of height 2 that contains a monic polynomial. Assume A =R/I is smooth and rank 2 projective A-modules have cancellation property. Then the following conditions are equivalent:

K² =0 in A²(X) (where K =C₁( $ω$ _I)).
$ω$ _I is two generated.
I is generated by 3 elements.

In all these cases, we have I/I² $≡$ $ω$ _I $⊕ ω$ _I^-2 and that I is a set-theoretic complete intersection ideal.

Proof.

1) $⇒$ 2)

2) $⇒$ 1)

2) $⇒$ 3)

3) $⇒$ 2)

By lemma 2.2, we have I/I² $≡$ A $⊕ ω$ ^-1. Since K²=0, the total Chern class C(I/I²) = C(A $⊕ ω$ _I^-1) =C( $ω$ _I $⊕
ω$ _I^-2). By cancellation I/I² $≡$ $ω$ _I $⊕ ω$ _I^-2. Also I is set-theoretic complete intersection by Theorem 2.1. So, the proof of this theorem is complete.

Theorem 3.4 Suppose k is an algebraically closed field and R=R'[X] is a polynomial ring over an affine algebra R' with dim R' =4. Let I be a locally complete intersection ideal of R with height(I) = 2 and A=R/I is smooth over k. Assume that all rank 2 projective A-modules have cancellation property. Suppose rK² = 0 for some r > 0 where K=C₁( $ω$ _I). Then I is set-theoretic complete intersection.

Proof.

r²K²=0.

L = $ω$ ^r.

C(L $⊕$ L^-1) = (1+rK)(1 - rK) = 1.

So, L $⊕$ L^-1 $≡$ A². So, $ω$ _I ^r is two generated. By Theorem 2.1, I is a set-theoretic complete intersection.

Following corollary follows from the above thoerem.

Corollary 3.1 Let k be an algebraically closed field and R=k[X₁, ... ,X₅] be polynomial ring and $φ$ : R $→$ A =A'[X] be a surjective map onto a polynomial algebra over a smooth algebra A' of dimension 2. Let I be a the kernel of $φ$ and K=C₁ ( $ω$ _I). If rK² =0 for some positive integer r then I is set theoretic complete intersection.

Proof.

A-modules

Theorem 3.5 Let R=k[X₁, .... , X₅] be a polynomoal ring over an algebraically closed field k and I be a locally complete intersection ideal of height 2. Assume A=R/I is smooth and rank 2 projective A-modules have cancellation property. If X=spec (A) has a projective smooth completion Y with rK_Y² =0 for some positive integer r, then X is set-theoretic complete intersection.

Proof.

rK_Y² = 0

rK_X² =0

Bibliography

[BMS] S. Bloch, M. P. Murthy and L. Szpiro, Zero cycles and the number of generators of an ideal, Soc. Math. de France {\bf 38} 91989), 51-74 .
[Ma1] Satya Mandal, Efficient Generation of Ideals, Invent. Math., {\bf 75} (1984),59-67 .
[Ma2] Satya Mandal, Ideals in polynomial rings and the module of differentials, J. of Algebra {\bf 242,} 762-768 (2001).
[MK] N. Mohan Kumar and M. Pavaman Murthy, Algebraic cycles and vector bundles over affine three-filds, Ann. of Math. {\bf 116} (1982), 579-591.
[Mu] M. P. Murthy, Complete Intersections , Conference on Commutative Algebra, Queen's Papers Pure Appl. Math. {\bf 42} (1975), 196-211.
[MKM] N. Mohan Kumar and M. Pavaman Murthy, Algebraic cycles and vector bundles over affine three-filds, Ann. of Math. {\bf 116} (1982), 579-591.
[S] A. A. Suslin, A cancellation theorem for projective modules over affine algebras, Soviet Math. Dokl. {\bf 17} (1976), 1160-1164.
[Sr] V, Srinivas, Torsion 0-cycles on affine varieties in charastic $p$, J. Algebra {\bf 120} (1989), 428-432.

Cancellation of projective modules and complete intersections

Let us give some preliminaries:

2 Main Results

3 Smooth 3-folds in A5

Bibliography

3 Smooth 3-folds in A⁵