Normal space

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Separation axioms
in topological spaces

Kolmogorov classification

T0 

(Kolmogorov)

T1 

(Fréchet)

T2 

(Hausdorff)
T2½
(Urysohn)

completely T2 

(completely Hausdorff)

T3 

(regular Hausdorff)
T
(Tychonoff)

T4 

(normal Hausdorff)

T5 

(completely normal
 Hausdorff)

T6 

(perfectly normal
 Hausdorff)

History

In topology and related branches of mathematics, a normal space is a topological space X that satisfies Axiom T4: every two disjoint closed sets of X have disjoint open neighborhoods. A normal Hausdorff space is also called a T4 space. These conditions are examples of separation axioms and their further strengthenings define completely normal Hausdorff spaces, or T5 spaces, and perfectly normal Hausdorff spaces, or T6 spaces.




Contents





  • 1 Definitions


  • 2 Examples of normal spaces


  • 3 Examples of non-normal spaces


  • 4 Properties


  • 5 Relationships to other separation axioms


  • 6 Citations


  • 7 References




Definitions


A topological space X is a normal space if, given any disjoint closed sets E and F, there are neighbourhoods U of E and V of F that are also disjoint. More intuitively, this condition says that E and F can be separated by neighbourhoods.




The closed sets E and F, here represented by closed disks on opposite sides of the picture, are separated by their respective neighbourhoods U and V, here represented by larger, but still disjoint, open disks.


A T4 space is a T1 space X that is normal; this is equivalent to X being normal and Hausdorff.


A completely normal space or a hereditarily normal space is a topological space X such that every subspace of X with subspace topology is a normal space. It turns out that X is completely normal if and only if every two separated sets can be separated by neighbourhoods.


A completely T4 space, or T5 space is a completely normal T1 space topological space X, which implies that X is Hausdorff; equivalently, every subspace of X must be a T4 space.


A perfectly normal space is a topological space X in which every two disjoint closed sets E and F can be precisely separated by a continuous function f from X to the real line R: the preimages of 0 and 1 under f are, respectively, E and F. (In this definition, the real line can be replaced with the unit interval [0,1].)


It turns out that X is perfectly normal if and only if X is normal and every closed set is a Gδ set. Equivalently, X is perfectly normal if and only if every closed set is a zero set. Every perfectly normal space is automatically completely normal.[1]


A Hausdorff perfectly normal space X is a T6 space, or perfectly T4 space.


Note that the terms "normal space" and "T4" and derived concepts occasionally have a different meaning. (Nonetheless, "T5" always means the same as "completely T4", whatever that may be.) The definitions given here are the ones usually used today. For more on this issue, see History of the separation axioms.


Terms like "normal regular space" and "normal Hausdorff space" also turn up in the literature – they simply mean that the space both is normal and satisfies the other condition mentioned. In particular, a normal Hausdorff space is the same thing as a T4 space. Given the historical confusion of the meaning of the terms, verbal descriptions when applicable are helpful, that is, "normal Hausdorff" instead of "T4", or "completely normal Hausdorff" instead of "T5".


Fully normal spaces and fully T4 spaces are discussed elsewhere; they are related to paracompactness.


A locally normal space is a topological space where every point has an open neighbourhood that is normal. Every normal space is locally normal, but the converse is not true. A classical example of a completely regular locally normal space that is not normal is the Nemytskii plane.



Examples of normal spaces


Most spaces encountered in mathematical analysis are normal Hausdorff spaces, or at least normal regular spaces:


  • All metric spaces (and hence all metrizable spaces) are perfectly normal Hausdorff;

  • All pseudometric spaces (and hence all pseudometrisable spaces) are perfectly normal regular, although not in general Hausdorff;

  • All compact Hausdorff spaces are normal;

  • In particular, the Stone–Čech compactification of a Tychonoff space is normal Hausdorff;

  • Generalizing the above examples, all paracompact Hausdorff spaces are normal, and all paracompact regular spaces are normal;

  • All paracompact topological manifolds are perfectly normal Hausdorff. However, there exist non-paracompact manifolds which are not even normal.

  • All order topologies on totally ordered sets are hereditarily normal and Hausdorff.

  • Every regular second-countable space is completely normal, and every regular Lindelöf space is normal.

Also, all fully normal spaces are normal (even if not regular). Sierpinski space is an example of a normal space that is not regular.



Examples of non-normal spaces


An important example of a non-normal topology is given by the Zariski topology on an algebraic variety or on the spectrum of a ring, which is used in algebraic geometry.


A non-normal space of some relevance to analysis is the topological vector space of all functions from the real line R to itself, with the topology of pointwise convergence.
More generally, a theorem of A. H. Stone states that the product of uncountably many non-compact metric spaces is never normal.



Properties


Every closed subset of a normal space is normal. The continuous and closed image of a normal space is normal.[2]


The main significance of normal spaces lies in the fact that they admit "enough" continuous real-valued functions, as expressed by the following theorems valid for any normal space X.


Urysohn's lemma:
If A and B are two disjoint closed subsets of X, then there exists a continuous function f from X to the real line R such that f(x) = 0 for all x in A and f(x) = 1 for all x in B.
In fact, we can take the values of f to be entirely within the unit interval [0,1].
(In fancier terms, disjoint closed sets are not only separated by neighbourhoods, but also separated by a function.)


More generally, the Tietze extension theorem:
If A is a closed subset of X and f is a continuous function from A to R, then there exists a continuous function F: XR which extends f in the sense that F(x) = f(x) for all x in A.


If U is a locally finite open cover of a normal space X, then there is a partition of unity precisely subordinate to U.
(This shows the relationship of normal spaces to paracompactness.)


In fact, any space that satisfies any one of these three conditions must be normal.


A product of normal spaces is not necessarily normal. This fact was first proved by Robert Sorgenfrey. An example of this phenomenon is the Sorgenfrey plane. Also, a subset of a normal space need not be normal (i.e. not every normal Hausdorff space is a completely normal Hausdorff space), since every Tychonoff space is a subset of its Stone–Čech compactification (which is normal Hausdorff). A more explicit example is the Tychonoff plank. The only large class of product spaces of normal spaces known to be normal are the products of compact Hausdorff spaces, since both compactness (Tychonoff's theorem) and the T2 axiom are preserved under arbitrary products.[3]



Relationships to other separation axioms


If a normal space is R0, then it is in fact completely regular.
Thus, anything from "normal R0" to "normal completely regular" is the same as what we normally call normal regular.
Taking Kolmogorov quotients, we see that all normal T1 spaces are Tychonoff.
These are what we normally call normal Hausdorff spaces.


A topological space is said to be pseudonormal if given two disjoint closed sets in it, one of which is countable, there are disjoint open sets containing them. Every normal space is pseudonormal, but not vice versa.


Counterexamples to some variations on these statements can be found in the lists above.
Specifically, Sierpinski space is normal but not regular, while the space of functions from R to itself is Tychonoff but not normal.



Citations




  1. ^ Munkres 2000, p. 213


  2. ^ Willard, Stephen (1970). General topology. Reading, Mass.: Addison-Wesley Pub. Co. pp. 100–101. ISBN 0486434796. 


  3. ^ Willard 1970, Section 17.




References



  • Kemoto, Nobuyuki (2004). "Higher Separation Axioms". In K.P. Hart; J. Nagata; J.E. Vaughan. Encyclopedia of General Topology. Amsterdam: Elsevier Science. ISBN 0-444-50355-2. 


  • Munkres, James R. (2000). Topology (2nd ed.). Prentice-Hall. ISBN 0-13-181629-2. 


  • Sorgenfrey, R.H. (1947). "On the topological product of paracompact spaces". Bull. Amer. Math. Soc. 53: 631–632. doi:10.1090/S0002-9904-1947-08858-3. 


  • Stone, A. H. (1948). "Paracompactness and product spaces". Bull. Amer. Math. Soc. 54: 977–982. doi:10.1090/S0002-9904-1948-09118-2. 


  • Willard, Stephen (1970). General Topology. Reading, Massachusetts: Addison-Wesley. ISBN 0-486-43479-6. 

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