In algebra, an analytically unramified ring is a local ring whose completion is reduced (has no nonzero nilpotent).
The following rings are analytically unramified:
showed that every local ring of an algebraic variety is analytically unramified. 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. This prompted to ask whether a local Noetherian domain such that its integral closure is a finite module is always analytically unramified. However 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 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 such that , 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.
Let K<sub>0</sub> be a perfect field of characteristic 2, such as F<sub>2</sub>. Let K be K<sub>0</sub>({u<sub>n</sub>, v<sub>n</sub> : n âÂÂ¥ 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 generated by K and K<sup>2</sup> and the element ã(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.