Analytically unramified ring: Difference between revisions

Browse history interactively

← Previous edit

Content deleted Content added

VisualWikitext

Inline

Latest revision as of 03:46, 25 August 2023

In algebra, an analytically unramified ring is a local ring whose completion is reduced (has no nonzero nilpotent).

The following rings are analytically unramified:

pseudo-geometric reduced ring.
excellent reduced ring.

Chevalley (1945) showed that every local ring of an algebraic variety is analytically unramified. Schmidt (1936) gave an example of an analytically ramified reduced local ring. Krull showed that every 1-dimensional normal Noetherian local ring is analytically unramified; more precisely he showed that a 1-dimensional normal Noetherian local domain is analytically unramified if and only if its integral closure is a finite module.^{[citation needed]} This prompted Zariski (1948) to ask whether a local Noetherian domain such that its integral closure is a finite module is always analytically unramified. However Nagata (1955) gave an example of a 2-dimensional normal analytically ramified Noetherian local ring. Nagata also showed that a slightly stronger version of Zariski's question is correct: if the normalization of every finite extension of a given Noetherian local ring R is a finite module, then R is analytically unramified.

There are two classical theorems of David Rees (1961) that characterize analytically unramified rings. The first says that a Noetherian local ring (R, m) is analytically unramified if and only if there are a m-primary ideal J and a sequence $n_{j}\to \infty$ such that ${\overline {J^{j}}}\subset J^{n_{j}}$ , where the bar means the integral closure of an ideal. The second says that a Noetherian local domain is analytically unramified if and only if, for every finitely-generated R-algebra S lying between R and the field of fractions K of R, the integral closure of S in K is a finitely generated module over S. The second follows from the first.

Nagata's example

Let K₀ be a perfect field of characteristic 2, such as F₂. Let K be K₀({u_n, v_n : n ≥ 0}), where the u_n and v_n are indeterminates. Let T be the subring of the formal power series ring K [[x,y]] generated by K and K² [[x,y]] and the element Σ(u_nxⁿ+ v_nyⁿ). Nagata proves that T is a normal local noetherian domain whose completion has nonzero nilpotent elements, so T is analytically ramified.

References

Chevalley, Claude (1945), "Intersections of algebraic and algebroid varieties", Trans. Amer. Math. Soc., 57: 1–85, doi:10.1090/s0002-9947-1945-0012458-1, JSTOR 1990167, MR 0012458
Huneke, Craig; Swanson, Irena (2006), Integral closure of ideals, rings, and modules, London Mathematical Society Lecture Note Series, vol. 336, Cambridge, UK: Cambridge University Press, ISBN 978-0-521-68860-4, MR 2266432, archived from the original on 2019-11-15, retrieved 2013-07-13
Nagata, Masayoshi (1955), "An example of normal local ring which is analytically ramified", Nagoya Math. J., 9: 111–113, MR 0073572
Rees, D. (1961), "A note on analytically unramified local rings", J. London Math. Soc., 36: 24–28, MR 0126465
Schmidt, Friedrich Karl (1936), "Über die Erhaltung der Kettensätze der Idealtheorie bei beliebigen endlichen Körpererweiterungen", Mathematische Zeitschrift, 41 (1): 443–450, doi:10.1007/BF01180433
Zariski, Oscar (1948), "Analytical irreducibility of normal varieties", Ann. of Math., 2, 49: 352–361, doi:10.2307/1969284, MR 0024158
Zariski, Oscar; Samuel, Pierre (1975) [1960], Commutative algebra. Vol. II, Berlin, New York: Springer-Verlag, ISBN 978-0-387-90171-8, MR 0389876

@@ Line 1: / Line 1: @@
-In algebra, an '''analytically unramified ring''' is a [[local ring]] whose [[completion (ring theory)|completion]] is reduced (has no nonzero [[nilpotent]]).
+In algebra, an '''analytically unramified ring''' is a [[local ring]] whose [[completion (ring theory)|completion]] is [[reduced ring|reduced]] (has no nonzero [[nilpotent]]).
 The following rings are analytically unramified:
@@ Line 6: / Line 6: @@
 {{harvtxt|Chevalley|1945}} showed that every local ring of an [[algebraic variety]] is analytically unramified.
-{{harvtxt|Schmidt|1936}} gave an example of an analytically ramified reduced local ring. {{harvtxt|Krull|1930}} showed that every 1-dimensional normal [[Noetherian ring|Noetherian]] local ring is analytically unramified; more precisely he showed that a 1-dimensional normal Noetherian local domain is analytically unramified if and only if its integral closure is a finite module. This prompted {{harvtxt|Zariski|1948}} to ask whether a local Noetherian domain such that its integral closure is a finite module is always analytically unramified. However {{harvtxt|Nagata|1955}} gave an example of a 2-dimensional normal analytically ramified Noetherian local ring. Nagata also showed that a slightly stronger version of Zariski's question is correct: if the normalization of every finite extension of a given Noetherian local ring ''R'' is a finite module, then ''R'' is analytically unramified.
+{{harvtxt|Schmidt|1936}} gave an example of an analytically ramified reduced local ring. Krull showed that every 1-dimensional normal [[Noetherian ring|Noetherian]] local ring is analytically unramified; more precisely he showed that a 1-dimensional normal Noetherian local domain is analytically unramified if and only if its integral closure is a finite module.{{CN|date=March 2022}} This prompted {{harvtxt|Zariski|1948}} to ask whether a local Noetherian domain such that its integral closure is a finite module is always analytically unramified. However {{harvtxt|Nagata|1955}} gave an example of a 2-dimensional normal analytically ramified Noetherian local ring. Nagata also showed that a slightly stronger version of Zariski's question is correct: if the normalization of every finite extension of a given Noetherian local ring ''R'' is a finite module, then ''R'' is analytically unramified.
 There are two classical theorems of {{harvs|txt|authorlink=David Rees (mathematician)|first=David|last=Rees|year=1961}}  that characterize analytically unramified rings. The first says that a Noetherian local ring (''R'', ''m'') is analytically unramified if and only if there are a ''m''-primary ideal ''J'' and a sequence <math>n_j \to \infty</math> such that <math>\overline{J^j} \subset J^{n_j}</math>, where the bar means the [[integral closure of an ideal]]. The second says that a Noetherian local domain is analytically unramified if and only if, for every finitely-generated ''R''-algebra ''S'' lying between ''R'' and the field of fractions ''K'' of ''R'', the [[integral closure]] of ''S'' in ''K'' is a finitely generated module over ''S''. The second follows from the first.
@@ Line 12: / Line 12: @@
 ==Nagata's example==
+Let ''K''<sub>0</sub> be a perfect field of characteristic 2, such as '''F'''<sub>2</sub>.
-Suppose that ''K'' is a field of characteristic ''p''>0 containing infinitely many algebraically independent elements ''b''<sub>''n''</sub>, ''c''<sub>''n''</sub> such that ''K'' has infinite degree over ''K''<sup>''p''</sup>. For example, ''K'' could be the purely transcendental extension of the finite field '''F'''<sub>''p''</sub> generated by elements ''b''<sub>''n''</sub>, ''c''<sub>''n''</sub>. Let ''T'' be the subring of the formal power series ring ''K''<nowiki>[[</nowiki>''x'',''y''<nowiki>]]</nowiki> generated by ''K'' and the power series with coefficients in ''K''<sup>''p''</sup> and the element Σ''b''<sub>''n''</sub>''x''<sup>''n''</sup>+ ''c''<sub>''n''</sub>''y''<sup>''n''</sup>. Then the ring ''T'' is a normal local Noetherian domain, but its completion has nilpotent elements, so ''T'' is analytically ramified.
+Let ''K'' be ''K''<sub>0</sub>({''u''<sub>''n''</sub>, ''v''<sub>''n''</sub> : ''n'' ≥ 0}), where the ''u''<sub>''n''</sub> and ''v''<sub>''n''</sub> are indeterminates.
+Let ''T'' be the subring of the [[formal power series ring]] ''K''&nbsp;{{brackets|''x'',''y''}} generated by ''K'' and ''K''<sup>''2''</sup>&nbsp;{{brackets|''x'',''y''}} and the element Σ(''u''<sub>''n''</sub>''x''<sup>''n''</sup>+ ''v''<sub>''n''</sub>''y''<sup>''n''</sup>).  Nagata proves that ''T'' is a normal local noetherian domain whose completion has nonzero nilpotent elements, so ''T'' is analytically ramified.
 == References ==
-*{{citation|mr=0012458|last=Chevalley|first= Claude|title=Intersections of algebraic and algebroid varieties|journal=Trans. Amer. Math. Soc. |volume=57|year=1945|pages= 1–85|jstor=1990167}}
+*{{citation|mr=0012458|last=Chevalley|first= Claude|authorlink=Claude Chevalley|title=Intersections of algebraic and algebroid varieties|journal=Trans. Amer. Math. Soc. |volume=57|year=1945|pages= 1–85|jstor=1990167|doi=10.1090/s0002-9947-1945-0012458-1|doi-access=free}}
-* {{Citation | ref=Reference-idHS2006 | last=Huneke | first=Craig | last2=Swanson | first2=Irena | title=Integral closure of ideals, rings, and modules  | url=http://people.reed.edu/~iswanson/book/index.html | publisher=[[Cambridge University Press]] | location=Cambridge, UK | series=London Mathematical Society Lecture Note Series | isbn=978-0-521-68860-4 | mr=2266432  | year=2006 | volume=336 }}
+* {{Citation | ref=Reference-idHS2006 | last=Huneke | first=Craig | last2=Swanson | first2=Irena | author2-link=Irena Swanson | title=Integral closure of ideals, rings, and modules | url=http://people.reed.edu/~iswanson/book/index.html | publisher=[[Cambridge University Press]] | location=Cambridge, UK | series=London Mathematical Society Lecture Note Series | isbn=978-0-521-68860-4 | mr=2266432 | year=2006 | volume=336 | access-date=2013-07-13 | archive-date=2019-11-15 | archive-url=https://web.archive.org/web/20191115053353/http://people.reed.edu/~iswanson/book/index.html | url-status=dead }}
-*{{citation|mr=0073572|last=Nagata|first= Masayoshi|title=An example of normal local ring which is analytically ramified
+*{{citation|mr=0073572|last=Nagata|first= Masayoshi|authorlink=Masayoshi Nagata|title=An example of normal local ring which is analytically ramified
 |journal=Nagoya Math. J.|volume= 9 |year=1955|pages= 111–113|url= http://projecteuclid.org/euclid.nmj/1118799688}}
 *{{citation|mr=0126465|last=Rees|first= D.|title=A note on analytically unramified local rings|journal=
 J. London Math. Soc. |volume=36 |year=1961|pages= 24–28}}
 *{{citation|title=Über die Erhaltung der Kettensätze der Idealtheorie bei beliebigen endlichen Körpererweiterungen|first=Friedrich Karl|last= Schmidt|journal=Mathematische Zeitschrift|year=1936|volume= 41|issue =1|pages= 443–450|doi=10.1007/BF01180433}}
-*{{citation| mr=0024158 |last=Zariski|first= Oscar|title=Analytical irreducibility of normal varieties|journal=Ann. of Math. (2) |volume=49|year=1948|pages= 352–361|doi=10.2307/1969284}}
+*{{citation| mr=0024158 |last=Zariski|first= Oscar|authorlink=Oscar Zariski|title=Analytical irreducibility of normal varieties|journal=Ann. of Math. |series= 2 |volume=49|year=1948|pages= 352–361|doi=10.2307/1969284}}
-*{{Citation | last1=Zariski | first1=Oscar | author1-link=Oscar Zariski | last2=Samuel | first2=Pierre | author2-link=Pierre Samuel | title=Commutative algebra. Vol. II | origyear=1960 | publisher=[[Springer-Verlag]] | location=Berlin, New York | isbn=978-0-387-90171-8 | id={{MathSciNet | id = 0389876}} | year=1975}}
+*{{Citation | last1=Zariski | first1=Oscar | author1-link=Oscar Zariski | last2=Samuel | first2=Pierre | author2-link=Pierre Samuel | title=Commutative algebra. Vol. II | origyear=1960 | publisher=[[Springer-Verlag]] | location=Berlin, New York | isbn=978-0-387-90171-8 |mr=0389876 | year=1975}}
 [[Category:Commutative algebra]]