In topology and related branches of mathematics, a totally disconnected space is a topological space that is maximally disconnected, in the sense that it has no non-trivial connected subsets. In every topological space the empty set and the one-point sets are connected; in a totally disconnected space these are the only connected subsets.
An important example of a totally disconnected space is the Cantor set. Another example, playing a key role in algebraic number theory, is the field Qp of p-adic numbers.
A topological space X is totally disconnected if the connected components in X are the one-point sets. Analogously, a topological space X is totally path-disconnected if all path-components in X are the one-point sets.
The following are examples of totally disconnected spaces:
Discrete spacesThe rational numbersThe irrational numbersThe p-adic numbers; more generally, profinite groups are totally disconnected.The Cantor setThe Baire spaceThe Sorgenfrey lineZero-dimensional T1 spacesExtremally disconnected Hausdorff spacesStone spacesThe Knaster–Kuratowski fan provides an example of a connected space, such that the removal of a single point produces a totally disconnected space.The Erdős space ℓp(Z)∩ Q ω is a totally disconnected space that does not have dimension zero.Subspaces, products, and coproducts of totally disconnected spaces are totally disconnected.Totally disconnected spaces are T1 spaces, since singletons are closed.Continuous images of totally disconnected spaces are not necessarily totally disconnected, in fact, every compact metric space is a continuous image of the Cantor set.A locally compact Hausdorff space is zero-dimensional if and only if it is totally disconnected.Every totally disconnected compact metric space is homeomorphic to a subset of a countable product of discrete spaces.It is in general not true that every open set is also closed.It is in general not true that the closure of every open set is open, i.e. not every totally disconnected Hausdorff space is extremally disconnected.Let X be an arbitrary topological space. Let x ∼ y if and only if y ∈ c o n n ( x ) (where c o n n ( x ) denotes the largest connected subset containing x ). This is obviously an equivalence relation. Endow X / ∼ with the quotient topology, i.e. the coarsest topology making the map m : x ↦ c o n n ( x ) continuous. With a little bit of effort we can see that X / ∼ is totally disconnected. We also have the following universal property: if f : X → Y a continuous map to a totally disconnected space, then it uniquely factors into f = f ˘ ∘ m where f ˘ : ( X / ∼ ) → Y is continuous.
