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Filtrations, closure operations and prime divisors

Published online by Cambridge University Press:  24 October 2008

J. S. Okon  and
L. J. Ratliff Jr
J. S. Okon
Affiliation:
Department of Mathematics, California State University, San Bernardino, California 92407, U.S.A.
L. J. Ratliff Jr
Affiliation:
Department of Mathematics, University of California, Riverside, California 92521, U.S.A.
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Abstract

Let ƒ = {In}n ≽ 0 be a filtration on a ring R, let

(In)w = {x ε R; x satisfies an equation xk + i1xk − 1 + … + ik = 0, where ij ε Inj} be the weak integral closure of In and let ƒw = {(In)w}n ≽ 0. Then it is shown that ƒ ↦ ƒw is a closure operation on the set of all filtrations ƒ of R, and if R is Noetherian, then ƒw is a semi-prime operation that satisfies the cancellation law: if ƒh ≤ (gh)w and Rad (ƒ) ⊆ Rad (h), then ƒwgw. These results are then used to show that if R and ƒ are Noetherian, then the sets Ass (R/(In)w) are equal for all large n. Then these results are abstracted, and it is shown that if IIx is a closure (resp.. semi-prime, prime) operation on the set of ideals I of R, then ƒ ↦ ƒx = {(In)x}n ≤ 0 is a closure (resp., semi-prime, prime) operation on the set of filtrations ƒ of R. In particular, if Δ is a multiplicatively closed set of finitely generated non-zero ideals of R and (In)Δ = ∪KεΔ(In, K: K), then ƒ ↦ ƒΔ is a semi-prime operation that satisfies a cancellation law, and if R and ƒ are Noetherian, then the sets Ass (R/(In)Δ) are quite well behaved.

Type
Research Article
Information
Mathematical Proceedings of the Cambridge Philosophical Society , Volume 104 , Issue 1 , July 1988 , pp. 31 - 46
Copyright
Copyright © Cambridge Philosophical Society 1988

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References

REFERENCES

[1]Bishop, W.. A theory of multiplicity for multiplicative filtrations. Ph.D. thesis, Western Michigan University 1971.Google Scholar
[2]Bishop, W., Petro, J. W., Ratliff, L. J. Jr. and Rush, D. E.. Note on Noetherian filtrations. Comm. Algebra, to appear.Google Scholar
[3]Katz, D. and Ratliff, L. J. Jr. On the symbolic Rees ring of a primary ideal. Comm. Algebra 14 (1986), 959970.Google Scholar
[4]Katz, D. and Ratliff, L. J. Jr. On the prime divisors of IJ when I is integrally closed. Preprint.Google Scholar
[5]McAdam, S. and Ratliff, L. J. Jr. On the asymptotic cograde of an ideal. J. Algebra 87 (1984), 3652.CrossRefGoogle Scholar
[6]Mirbagheri, A. and Ratliff, L. J. Jr. On the relevant transform and the relevant component of an ideal. J. Algebra 111 (1987), 507519.CrossRefGoogle Scholar
[7]Okon, J. S.. Prime divisors, analytic spread and filtrations. Pacific J. Math. 113 (1984), 451462.CrossRefGoogle Scholar
[8]Petro, J. W.. Some results on the asymptotic completion of an ideal. Proc. Amer. Math. Soc. 15 (1964), 519524.CrossRefGoogle Scholar
[9]Ratlife, L. J. Jr. A characterization of analytically unramified semi-local rings and applications. Pacific J. Math. 27 (1968), 127143.CrossRefGoogle Scholar
[10]Ratliff, L. J. Jr. Notes on essentially powers filtrations. Michigan Math. J. 26 (1979), 337353.CrossRefGoogle Scholar
[11]Ratliff, L. J. Jr. On asymptotic prime divisors. Pacific J. Math. 111 (1984), 395413.CrossRefGoogle Scholar
[12]Ratliff, L. J. Jr. Asymptotic prime divisors and integral extension rings. J. Algebra 95 (1985), 409431.CrossRefGoogle Scholar
[13]Ratliff, L. J. Jr. Δ-closures of ideals and rings, Trans. Amer. Math. Soc. (to appear).Google Scholar
[14]Rees, D.. Asymptotic properties of ideals. Preprint.Google Scholar
[15]Whittington, K.. Asymptotic prime divisors and the altitude formula (preprint).Google Scholar
[16]Zariski, O. and Samuel, P.. Commutative Algebra, Vol. 1 (Van Nostrand. 1958).Google Scholar