Topological property explained

In topology and related areas of mathematics, a topological property or topological invariant is a property of a topological space that is invariant under homeomorphisms. Alternatively, a topological property is a proper class of topological spaces which is closed under homeomorphisms. That is, a property of spaces is a topological property if whenever a space X possesses that property every space homeomorphic to X possesses that property. Informally, a topological property is a property of the space that can be expressed using open sets.

A common problem in topology is to decide whether two topological spaces are homeomorphic or not. To prove that two spaces are not homeomorphic, it is sufficient to find a topological property which is not shared by them.

Properties of topological properties

A property

P

is:

(X,l{T})

and subset

S\subseteqX,

the subspace

\left(S,l{T}|S\right)

has property

P.

(X,l{T})

and closed subset

S\subseteqX,

the subspace

\left(S,l{T}|S\right)

has property

P.

Common topological properties

Cardinal functions

\vertX\vert

of the space

X

.

\vert\tau(X)\vert

of the topology (the set of open subsets) of the space

X

.

w(X)

, the least cardinality of a basis of the topology of the space

X

.

d(X)

, the least cardinality of a subset of

X

whose closure is

X

.

Separation

See main article: Separation axiom. Some of these terms are defined differently in older mathematical literature; see history of the separation axioms.

Countability conditions

See also: Axiom of countability.

Connectedness

f\colon[0,1]\toX

with

p(0)=x

and

p(1)=y

. Arc-connected spaces are path-connected.

f\colonS1\toX

is homotopic to a constant map.

Compactness

Metrizability

(X,T)

is said to be metrizable if there exists a metric for

X

such that the metric topology

T(d)

is identical with the topology

T.

Miscellaneous

f\colonX\toX

such that

f(x)=y.

Intuitively speaking, this means that the space looks the same at every point. All topological groups are homogeneous.

\kappa

-resolvable. A space is said to be κ-resolvable[1] (respectively: almost κ-resolvable) if it contains κ dense sets that are pairwise disjoint (respectively: almost disjoint over the ideal of nowhere dense subsets). If the space is not

\kappa

-resolvable then it is called

\kappa

-irresolvable.

X

is maximally resolvable if it is

\Delta(X)

-resolvable, where

\Delta(X)= min\{|G|:G\varnothing,Gisopen\}.

Number

\Delta(X)

is called dispersion character of

X.

D

is strongly discrete subset of the space

X

if the points in

D

may be separated by pairwise disjoint neighborhoods. Space

X

is said to be strongly discrete if every non-isolated point of

X

is the accumulation point of some strongly discrete set.

Non-topological properties

There are many examples of properties of metric spaces, etc, which are not topological properties. To show a property

P

is not topological, it is sufficient to find two homeomorphic topological spaces

X\congY

such that

X

has

P

, but

Y

does not have

P

.

For example, the metric space properties of boundedness and completeness are not topological properties. Let

X=\R

and

Y=(-\tfrac{\pi}{2},\tfrac{\pi}{2})

be metric spaces with the standard metric. Then,

X\congY

via the homeomorphism

\operatorname{arctan}\colonX\toY

. However,

X

is complete but not bounded, while

Y

is bounded but not complete.

See also

References

[2] Simon Moulieras, Maciej Lewenstein and Graciana Puentes, Entanglement engineering and topological protection by discrete-time quantum walks, Journal of Physics B: Atomic, Molecular and Optical Physics 46 (10), 104005 (2013).https://iopscience.iop.org/article/10.1088/0953-4075/46/10/104005/pdf

Notes and References

  1. Juhász. István. Soukup, Lajos . Szentmiklóssy, Zoltán . Resolvability and monotone normality. Israel Journal of Mathematics. 2008. 166. 1. 1–16. 10.1007/s11856-008-1017-y. free. 0021-2172. math/0609092. 14743623.