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In [[mathematics]], the '''Sierpiński space''' (or the '''connected two-point set''') is a [[finite topological space]] with two points, only one of which is [[closed set|closed]].
It is the smallest example of a [[topological space]] which is neither [[trivial topology|trivial]] nor [[discrete topology|discrete]]. It is named after [[Wacław Sierpiński]].
 
The Sierpiński space has important relations to the [[Computability theory|theory of computation]] and [[semantics]].<ref>An online paper, it explains the motivation, why the notion of “topology” can be applied in the investigation of concepts of the computer science. Alex Simpson: [http://www.dcs.ed.ac.uk/home/als/Teaching/MSfS/ Mathematical Structures for Semantics]. Chapter III: [http://www.dcs.ed.ac.uk/home/als/Teaching/MSfS/l3.ps Topological Spaces from a Computational Perspective]. The “References” section provides many online materials on [[domain theory]].</ref><ref>{{cite book | title = Synthetic topology of data types and classical spaces | last1 = Escardó | first1 = Martín | publisher = [[Elsevier]] | year = 2004 | series = Electronic Notes in Theoretical Computer Science | volume = 87 | url = http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.129.2886 | accessdate = July 6, 2011 }}</ref>
 
==Definition and fundamental properties==
 
Explicitly, the '''Sierpiński space''' is a [[topological space]] ''S''  whose underlying [[set (mathematics)|point set]] is {0,1} and whose [[open set]]s are
:<math>\{\varnothing,\{1\},\{0,1\}\}.</math>
The [[closed set]]s are
:<math>\{\varnothing,\{0\},\{0,1\}\}.</math>
So the [[singleton set]] {0} is closed (but not open) and the set {1} is open (but not closed).
 
The [[Kuratowski closure axioms|closure operator]] on ''S'' is determined by
:<math>\overline{\{0\}} = \{0\},\qquad\overline{\{1\}} = \{0,1\}.</math>
 
A finite topological space is also uniquely determined by its [[specialization preorder]]. For  the Sierpiński space this [[preorder]] is actually a [[partial order]] and given by
:<math>0\leq 0,\qquad 0\leq 1,\qquad 1\leq 1.</math>
 
==Topological properties==
 
The Sierpiński space ''S'' is a special case of both the finite [[particular point topology]] (with particular point 1) and the finite [[excluded point topology]] (with excluded point 0). Therefore ''S'' has many properties in common with one or both of these families.
 
===Separation===
 
*The points 0 and 1 are [[topologically distinguishable]] in ''S'' since {1} is an open set which contains only one of these points. Therefore ''S'' is a [[Kolmogorov space|Kolmogorov (T<sub>0</sub>) space]].
*However, ''S'' is not T<sub>1</sub> since the point 1 is not closed. It follows that ''S'' is not [[Hausdorff space|Hausdorff]], or T<sub>''n''</sub> for any ''n'' &ge; 1.
*''S'' is not [[regular space|regular]] (or [[completely regular]]) since the point 1 and the disjoint closed set {0} cannot be [[separated set|separated by neighborhoods]]. (Also regularity in the presence of T<sub>0</sub> would imply Hausdorff.)
*''S'' is [[vacuous truth|vacuously]] [[normal space|normal]] and [[completely normal space|completely normal]] since there are no nonempty [[separated set]]s.
*''S'' is not [[perfectly normal space|perfectly normal]] since the disjoint closed sets &empty; and {0} cannot be precisely separated by a function. Indeed {0} cannot be the [[zero set]] of any [[continuous function (topology)|continuous function]] ''S'' &rarr; '''R''' since every such function is [[constant function|constant]].
 
===Connectedness===
 
*The Sierpiński space ''S'' is both [[hyperconnected]] (since every nonempty open set contains 1) and [[ultraconnected]] (since every nonempty closed set contains 0).
*It follows that ''S'' is both [[connected space|connected]] and [[path connected space|path connected]].
*A [[path (topology)|path]] from 0 to 1 in ''S'' is given by the function: ''f''(0) = 0 and ''f''(''t'')  = 1 for ''t'' &gt; 0. The function ''f'' : ''I'' &rarr; ''S'' is continuous since ''f''<sup>&minus;1</sup>(1) = (0,1] which is open in ''I''.
*Like all finite topological spaces, ''S'' is [[locally path connected]].
*The Sierpiński space is [[contractible space|contractible]], so the [[fundamental group]] of ''S'' is [[trivial group|trivial]] (as are all the [[higher homotopy groups]]).
 
===Compactness===
 
*Like all finite topological spaces, the Sierpiński space is both [[compact space|compact]] and [[second-countable]].
*The compact subset {1} of ''S'' is not closed showing that compact subsets of T<sub>0</sub> spaces need not be closed.
*Every [[open cover]] of ''S'' must contain ''S'' itself since ''S'' is the only open neighborhood of 0. Therefore every open cover of ''S'' has an open [[subcover]] consisting of a single set: {''S''}.
*It follows that ''S'' is [[fully normal space|fully normal]].<ref>Steen and Seebach incorrectly list the Sierpiński space as ''not'' being fully normal (or fully T<sub>4</sub> in their terminology).</ref>
 
===Convergence===
 
*Every [[sequence]] in ''S'' [[limit of a sequence|converges]] to the point 0. This is because the only neighborhood of 0 is ''S'' itself.
*A sequence in ''S'' converges to 1 if and only if the sequence contains only finitely many terms equal to 0 (i.e. the sequence is eventually just 1's).
*The point 1 is a [[cluster point]] of a sequence in ''S'' if and only if the sequence contains infinitely many 1's.
*''Examples'':
**1 is not a cluster point of (0,0,0,0,&hellip;).
**1 is a cluster point (but not a limit) of (0,1,0,1,0,1,&hellip;).
**The sequence (1,1,1,1,&hellip;) converges to both 0 and 1.
 
===Metrizability===
 
*The Sierpiński space ''S'' is not [[metrizable space|metrizable]] or even [[pseudometrizable space|pseudometrizable]] since every pseudometric space is [[Tychonoff space|completely regular]] but the Sierpiński space it is not even [[Regular space|regular]].
* ''S'' is generated by the [[hemimetric]] (or [[pseudometric space|pseudo]]-[[quasimetric]]) <math>d(0,1)=0</math> and <math>d(1,0)=1</math>.
 
===Other properties===
 
*There are only three [[continuous function (topology)|continuous maps]] from ''S'' to itself: the [[identity function|identity map]] and the [[constant map]]s to 0 and 1.
*It follows that the [[homeomorphism group]] of ''S'' is [[trivial group|trivial]].
 
==Continuous functions to the Sierpiński space==
 
Let ''X'' be an arbitrary set. The [[function space|set of all functions]] from ''X'' to the set {0,1} is typically denoted 2<sup>''X''</sup>. These functions are precisely the [[indicator function|characteristic function]]s of ''X''. Each such function is of the form
:<math>\chi_U(x) = \begin{cases}1 & x \in U \\ 0 & x \not\in U\end{cases}</math>
where ''U'' is a [[subset]] of ''X''. In other words, the set of functions 2<sup>''X''</sup> is in [[bijective]] correspondence with ''P''(''X''), the [[power set]] of ''X''. Every subset ''U'' of ''X'' has its characteristic function &chi;<sub>''U''</sub> and every function from ''X'' to {0,1} is of this form.
 
Now suppose ''X'' is a topological space and let {0,1} have the Sierpiński topology. Then a function &chi;<sub>''U''</sub> : ''X'' &rarr; ''S'' is [[continuous function (topology)|continuous]] if and only if &chi;<sub>''U''</sub><sup>&minus;1</sup>(1) is open in ''X''. But, by definition
:<math>\chi_U^{-1}(1) = U.</math>
So &chi;<sub>''U''</sub> is continuous if and only if ''U'' is open in ''X''. Let C(''X'',''S'') denote the set of all continuous maps from ''X'' to ''S'' and let ''T''(''X'') denote the topology of ''X'' (i.e. the family of all open sets). Then we have a bijection from  ''T''(''X'') to C(''X'',''S'') which sends the open set ''U'' to &chi;<sub>''U''</sub>.
:<math>C(X,S)\cong \mathcal{T}(X)</math>
That is, if we identify 2<sup>''X''</sup> with ''P''(''X''), the subset of continuous maps C(''X'',''S'') &sub; 2<sup>''X''</sup> is precisely the topology of ''X'': ''T''(''X'') &sub; ''P''(''X'').
 
===Categorical description===
 
The above construction can be described nicely using the language of [[category theory]]. There is [[contravariant functor]] ''T'' : '''Top''' &rarr; '''Set''' from the [[category of topological spaces]] to the [[category of sets]] which assigns each topological space ''X'' its set of open sets ''T''(''X'') and each continuous function ''f'' : ''X'' &rarr; ''Y'' the [[preimage]] map
:<math>f^{-1} : \mathcal{T}(Y) \to \mathcal{T}(X).</math>
The statement then becomes: the functor ''T'' is [[representable functor|represented]] by (''S'', {1}) where ''S'' is the Sierpiński space. That is, ''T'' is [[naturally isomorphic]] to the [[Hom functor]] Hom(&ndash;, ''S'') with the natural isomorphism determined by the [[universal element]] {1} &isin; ''T''(''S'').
 
===The initial topology===
 
Any topological space ''X'' has the [[initial topology]] induced by the family C(''X'',''S'') of continuous functions to Sierpiński space. Indeed, in order to [[coarser topology|coarsen]] the topology on ''X'' one must remove open sets. But removing the open set ''U'' would render &chi;<sub>''U''</sub> discontinuous. So ''X'' has the coarsest topology for which each function in C(''X'',''S'') is continuous.
 
The family of functions C(''X'',''S'') [[separating set|separates points]] in ''X'' if and only if ''X'' is a [[T0 space|T<sub>0</sub> space]]. Two points ''x'' and ''y'' will be separated by the function &chi;<sub>''U''</sub> if and only if the open set ''U'' contains precisely one of the two points. This is exactly what it means for ''x'' and ''y'' to be [[topologically distinguishable]].
 
Therefore if ''X'' is T<sub>0</sub>, we can embed ''X'' as a [[subspace (topology)|subspace]] of a [[product topology|product]] of Sierpiński spaces, where there is one copy of ''S'' for each open set ''U'' in ''X''. The embedding map
:<math>e : X \to \prod_{U\in \mathcal{T}(X)}S = S^{\mathcal{T}(X)}</math>
is given by
:<math>e(x)_U = \chi_U(x).\,</math>
Since subspaces and products of T<sub>0</sub> spaces are T<sub>0</sub>, it follows that a topological space is T<sub>0</sub> if and only if it is [[homeomorphic]] to a subspace of a power of ''S''.
 
==In algebraic geometry==
 
In [[algebraic geometry]] the Sierpiński space arises as the [[spectrum of a ring|spectrum]], Spec(''R''), of a [[discrete valuation ring]] ''R'' such as '''Z'''<sub>(2)</sub> (the [[localization of a ring|localization]] of the [[integer]]s at the [[prime ideal]] generated by 2). The [[generic point]] of Spec(''R''), coming from the [[zero ideal]], corresponds to the open point 1, while the [[special point]] of Spec(''R''), coming from the unique [[maximal ideal]], corresponds to the closed point 0.
 
==See also==
*[[Finite topological space]]
*[[Pseudocircle]]
 
==Notes==
 
<references/>
 
==References==
*{{Citation | last1=Steen | first1=Lynn Arthur | author1-link=Lynn Arthur Steen | last2=Seebach | first2=J. Arthur Jr. | author2-link=J. Arthur Seebach, Jr. | title=[[Counterexamples in Topology]] | origyear=1978 | publisher=[[Springer-Verlag]] | location=Berlin, New York | edition=[[Dover Publications|Dover]] reprint of 1978 | isbn=978-0-486-68735-3 | id={{MathSciNet|id=507446}} | year=1995}}
 
{{DEFAULTSORT:Sierpinski space}}
[[Category:General topology]]
[[Category:Topological spaces]]

Revision as of 18:18, 1 July 2013

In mathematics, the Sierpiński space (or the connected two-point set) is a finite topological space with two points, only one of which is closed. It is the smallest example of a topological space which is neither trivial nor discrete. It is named after Wacław Sierpiński.

The Sierpiński space has important relations to the theory of computation and semantics.[1][2]

Definition and fundamental properties

Explicitly, the Sierpiński space is a topological space S whose underlying point set is {0,1} and whose open sets are

{,{1},{0,1}}.

The closed sets are

{,{0},{0,1}}.

So the singleton set {0} is closed (but not open) and the set {1} is open (but not closed).

The closure operator on S is determined by

{0}={0},{1}={0,1}.

A finite topological space is also uniquely determined by its specialization preorder. For the Sierpiński space this preorder is actually a partial order and given by

00,01,11.

Topological properties

The Sierpiński space S is a special case of both the finite particular point topology (with particular point 1) and the finite excluded point topology (with excluded point 0). Therefore S has many properties in common with one or both of these families.

Separation

Connectedness

Compactness

  • Like all finite topological spaces, the Sierpiński space is both compact and second-countable.
  • The compact subset {1} of S is not closed showing that compact subsets of T0 spaces need not be closed.
  • Every open cover of S must contain S itself since S is the only open neighborhood of 0. Therefore every open cover of S has an open subcover consisting of a single set: {S}.
  • It follows that S is fully normal.[3]

Convergence

  • Every sequence in S converges to the point 0. This is because the only neighborhood of 0 is S itself.
  • A sequence in S converges to 1 if and only if the sequence contains only finitely many terms equal to 0 (i.e. the sequence is eventually just 1's).
  • The point 1 is a cluster point of a sequence in S if and only if the sequence contains infinitely many 1's.
  • Examples:
    • 1 is not a cluster point of (0,0,0,0,…).
    • 1 is a cluster point (but not a limit) of (0,1,0,1,0,1,…).
    • The sequence (1,1,1,1,…) converges to both 0 and 1.

Metrizability

Other properties

Continuous functions to the Sierpiński space

Let X be an arbitrary set. The set of all functions from X to the set {0,1} is typically denoted 2X. These functions are precisely the characteristic functions of X. Each such function is of the form

χU(x)={1xU0x∉U

where U is a subset of X. In other words, the set of functions 2X is in bijective correspondence with P(X), the power set of X. Every subset U of X has its characteristic function χU and every function from X to {0,1} is of this form.

Now suppose X is a topological space and let {0,1} have the Sierpiński topology. Then a function χU : XS is continuous if and only if χU−1(1) is open in X. But, by definition

χU1(1)=U.

So χU is continuous if and only if U is open in X. Let C(X,S) denote the set of all continuous maps from X to S and let T(X) denote the topology of X (i.e. the family of all open sets). Then we have a bijection from T(X) to C(X,S) which sends the open set U to χU.

C(X,S)𝒯(X)

That is, if we identify 2X with P(X), the subset of continuous maps C(X,S) ⊂ 2X is precisely the topology of X: T(X) ⊂ P(X).

Categorical description

The above construction can be described nicely using the language of category theory. There is contravariant functor T : TopSet from the category of topological spaces to the category of sets which assigns each topological space X its set of open sets T(X) and each continuous function f : XY the preimage map

f1:𝒯(Y)𝒯(X).

The statement then becomes: the functor T is represented by (S, {1}) where S is the Sierpiński space. That is, T is naturally isomorphic to the Hom functor Hom(–, S) with the natural isomorphism determined by the universal element {1} ∈ T(S).

The initial topology

Any topological space X has the initial topology induced by the family C(X,S) of continuous functions to Sierpiński space. Indeed, in order to coarsen the topology on X one must remove open sets. But removing the open set U would render χU discontinuous. So X has the coarsest topology for which each function in C(X,S) is continuous.

The family of functions C(X,S) separates points in X if and only if X is a T0 space. Two points x and y will be separated by the function χU if and only if the open set U contains precisely one of the two points. This is exactly what it means for x and y to be topologically distinguishable.

Therefore if X is T0, we can embed X as a subspace of a product of Sierpiński spaces, where there is one copy of S for each open set U in X. The embedding map

e:XU𝒯(X)S=S𝒯(X)

is given by

e(x)U=χU(x).

Since subspaces and products of T0 spaces are T0, it follows that a topological space is T0 if and only if it is homeomorphic to a subspace of a power of S.

In algebraic geometry

In algebraic geometry the Sierpiński space arises as the spectrum, Spec(R), of a discrete valuation ring R such as Z(2) (the localization of the integers at the prime ideal generated by 2). The generic point of Spec(R), coming from the zero ideal, corresponds to the open point 1, while the special point of Spec(R), coming from the unique maximal ideal, corresponds to the closed point 0.

See also

Notes

  1. An online paper, it explains the motivation, why the notion of “topology” can be applied in the investigation of concepts of the computer science. Alex Simpson: Mathematical Structures for Semantics. Chapter III: Topological Spaces from a Computational Perspective. The “References” section provides many online materials on domain theory.
  2. 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  3. Steen and Seebach incorrectly list the Sierpiński space as not being fully normal (or fully T4 in their terminology).

References

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