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Revision as of 01:53, 26 January 2014

In algebraic geometry, a local ring A is said to be unibranch if the reduced ring A_red (obtained by quotienting A by its nilradical) is an integral domain, and the integral closure B of A_red is also a local ring.Template:Fact A unibranch local ring is said to be geometrically unibranch if the residue field of B is a purely inseparable extension of the residue field of A_red. A complex variety X is called topologically unibranch at a point x if for all complements Y of closed algebraic subsets of X there is a fundamental system of neighborhoods (in the classical topology) of x whose intersection with Y is connected.

In particular, a normal ring is unibranch. The notions of unibranch and geometrically unibranch points are used in some theorems in algebraic geometry. For example, there is the following result:

Theorem Template:Harv Let X and Y be two integral locally noetherian schemes and $f\colon X\to Y$ a proper dominant morphism. Denote their function fields by K(X) and K(Y), respectively. Suppose that the algebraic closure of K(Y) in K(X) has separable degree n and that $y\in Y$ is unibranch. Then the fiber $f^{-1}(y)$ has at most n connected components. In particular, if f is birational, then the fibers of unibranch points are connected.

In EGA, the theorem is obtained as a corollary of Zariski's main theorem.

References

Template:EGA

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+In algebraic geometry, a [[local ring]] ''A'' is said to be '''unibranch''' if the [[reduced ring]] ''A''<sub>red</sub> (obtained by quotienting ''A'' by its [[nilradical of a ring|nilradical]]) is an [[integral domain]], and the [[integral closure]] ''B'' of ''A''<sub>red</sub> is also a local ring.{{fact|date=August 2012}} A unibranch local ring is said to be '''geometrically unibranch''' if the [[residue field]] of ''B'' is a [[purely inseparable extension]] of the residue field of ''A''<sub>red</sub>. A complex variety ''X'' is called '''topologically unibranch''' at a point ''x'' if for all complements ''Y'' of closed algebraic subsets of ''X'' there is a fundamental system of neighborhoods (in the classical topology) of ''x'' whose intersection with ''Y'' is connected.
+In particular, a [[normal ring]] is unibranch. The notions of unibranch and geometrically unibranch points are used in some theorems in algebraic geometry. For example, there is the following result:
+'''Theorem''' {{harv|EGA|loc=4.3.7}} Let ''X'' and ''Y'' be two integral locally noetherian schemes and <math>f \colon X \to Y</math> a [[proper morphism|proper]] [[dominant morphism]]. Denote their function fields by ''K(X)'' and ''K(Y)'', respectively. Suppose that the algebraic closure of ''K(Y)'' in ''K(X)'' has separable degree ''n'' and that <math>y \in Y</math> is unibranch. Then the fiber <math>f^{-1}(y)</math> has at most ''n'' connected components. In particular, if ''f'' is [[birational]], then the fibers of unibranch points are connected.
+In EGA, the theorem is obtained as a corollary of [[Zariski's main theorem]].
+==References==
+*{{EGA |book=III-1}}
+[[Category:Algebraic geometry|*]]
+[[Category:Commutative algebra| ]]

Lehmer code: Difference between revisions

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