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There are many ways to state connectedness, and one can just as well start with disconnected and then define "connected" as "not disconnected". I have attempted to pick one and mention the others, do not be put off if you have found another definition! I have started with the most intuitive definition

Definition

Let $(X,\mathcal{ J })$ be a topological space. We say $X$ is connected if^[1]:

it is not disconnected^{[Note 1]} (expand the yellow box below for a reminder of this definition)

There are equivalent definitions, some are given below. Note also, that by this convention the $\emptyset$ is connected.

[Expand]

Recall the definition of a topological space being disconnected

A topological space, $(X,\mathcal{ J })$ , is said to be disconnected if^[1]:

$\exists U,V\in\mathcal{J}[U\ne\emptyset\wedge V\neq\emptyset\wedge V\cap U=\emptyset\wedge U\cup V=X]$ , in words "if there exists a pair of disjoint and non-empty open sets, $U$ and $V$ , such that their union is $X$ "

In this case, $U$ and $V$ are said to disconnect $X$ ^[1] and are sometimes called a separation of $X$ .

Of a subset

Let $A\in\mathcal{P}(X)$ be an arbitrary subset of $X$ , then:

we say $A$ is connected if it is connected when considered as a topological subspace of $(X,\mathcal{ J })$ ^[1]^[2].

There are equivalent definitions, some are given below.

Equivalent conditions

To a topological space $(X,\mathcal{ J })$ being connected:

To an arbitrary subset, $A\in\mathcal{P}(X)$ , being connected:

Obviously, the only sets being both relatively open and relatively closed in $A$ are $\emptyset$ and $A$ itself. (This comes directly from the subspace definition above)
A subset of a topological space is disconnected if and only if it can be covered by two non-empty-in-the-subset and disjoint-in-the-subset sets that are open in the space itself
- Then apply the definition above, a subset is considered connected if it is not disconnected
A subset of a topological space is connected if and only if and only if the only two subsets that are both relatively open and relatively closed with respect to the subset are the empty-set and the subset itself

Notes

Jump up ↑
We could write this as:
- $\neg(\exists U,V\in\mathcal{J}[U\ne\emptyset\wedge V\neq\emptyset\wedge U\cap V=\emptyset\wedge U\cup V=X])$
Which is:
- $\forall U,V\in\mathcal{J}[U=\emptyset\vee V=\emptyset\vee U\cap V\ne\emptyset\vee U\cup V\ne X]$
but, whilst completely "true", this is difficult to read and far less intuitive.

References

↑ ^{Jump up to: 1.0} ^1.1 ^1.2 ^1.3 Introduction to Topological Manifolds - John M. Lee
↑ ^{Jump up to: 2.0} ^2.1 Introduction to Topology - Bert Mendelson

OLD PAGE

Definition

A topological space

$(X,\mathcal{J})$ is connected if there is no separation of

$X$ ^[1] A separation of

$X$ is:

A pair of non-empty open sets in X, which we'll denote as $U,\ V$ where:
1. $U\cap V=\emptyset$ and
2. $U\cup V=X$

If there is no such separation then the space is connected^[2]

Equivalent definition

This definition is equivalent (true if and only if) the only empty sets that are both open in $X$ are:

$\emptyset$ and
$X$ itself.

I will prove this claim now:

[Expand]
Claim: A topological space
$(X,\mathcal{J})$ is connected if and only if the sets $X,\emptyset$ are the only two sets that are both open and closed.

Connected

$\implies$ only sets both open and closed are $X,\emptyset$

Suppose

$X$ is connected and there exists a set

$A$ that is not empty and not all of

$X$ which is both open and closed. Then as :this is closed,

$X-A$ is open. Thus

$A,X-A$ is a separation, contradicting that

$X$ is connected.

Only sets both open and closed are

$X,\emptyset\implies$ connected

TODO:

Connected subset

A subset $A$ of a Topological space $(X,\mathcal{J})$ is connected if (when considered with the Subspace topology) the only two Relatively open and Relatively closed (in A) sets are $A$ and $\emptyset$ ^[3]

Useful lemma

Given a topological subspace $Y$ of a space $(X,\mathcal{J})$ we say that $Y$ is disconnected if and only if:

$\exists U,V\in\mathcal{J}$ such that:
- $Y\subseteq U\cup V$ and
- $U\cap V\subseteq C(Y)$ and
- Both $U\cap Y\ne\emptyset$ and $V\cap Y\ne\emptyset$

This is basically says there has to be a separation of $Y$ that isn't just $Y$ and the $\emptyset$ for $Y$ to be disconnected, but the sets may overlap outside of {{M|Y}

[Expand]
Proof of lemma:

Results

[Expand]
Theorem:Given a topological subspace $Y$ of a space $(X,\mathcal{J})$ we say that $Y$ is disconnected if and only if
$\exists U,V\in\mathcal{J}$ such that: $A\subseteq U\cup V$ , $U\cap V\subseteq C(A)$ , $U\cap A\ne\emptyset$ and $V\cap A\ne\emptyset$

[Expand]
Theorem: The image of a connected set is connected under a continuous map

References

Jump up ↑ Topology - James R. Munkres - 2nd edition
Jump up ↑ Analysis - Part 1: Elements - Krzysztof Maurin
Jump up ↑ Introduction to topology - Mendelson - third edition

[2] Jump up ↑ We could write this as:
$\neg(\exists U,V\in\mathcal{J}[U\ne\emptyset\wedge V\neq\emptyset\wedge U\cap V=\emptyset\wedge U\cup V=X])$
Which is:
$\forall U,V\in\mathcal{J}[U=\emptyset\vee V=\emptyset\vee U\cap V\ne\emptyset\vee U\cup V\ne X]$
but, whilst completely "true", this is difficult to read and far less intuitive.

[2] $\neg(\exists U,V\in\mathcal{J}[U\ne\emptyset\wedge V\neq\emptyset\wedge U\cap V=\emptyset\wedge U\cup V=X])$

[3] $\forall U,V\in\mathcal{J}[U=\emptyset\vee V=\emptyset\vee U\cap V\ne\emptyset\vee U\cup V\ne X]$

[ITTMJML-1] {Jump up to: 1.0} ^1.1 ^1.2 ^1.3 Introduction to Topological Manifolds - John M. Lee

[ITTBM-3] {Jump up to: 2.0} ^2.1 Introduction to Topology - Bert Mendelson

[Topology-4] Jump up ↑ Topology - James R. Munkres - 2nd edition

[Analysis-5] Jump up ↑ Analysis - Part 1: Elements - Krzysztof Maurin

[6] Jump up ↑ Introduction to topology - Mendelson - third edition

[1]

[Note 1]

[2]

[1]

[2]

[3]

Connected (topology)

Contents

Definition

Of a subset

Equivalent conditions

See also

Notes

References

OLD PAGE

Definition

Equivalent definition

Connected subset

Useful lemma

Results

References

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