A subset S of a topological space is closed precisely when , i.e. when contains all its limit points. Two subsets S and T are separated precisely when they are disjoint and each is disjoint from the other's derived set (though the derived sets don't need to be disjoint from each other).
A bijection between two topological spaces is a homeomorphism if and only if the derived set of the image (in the second space) of any subset of the first space is the image of the derived set of that subset.
The Cantor–Bendixson theorem states that any Polish space can be written as the union of a countable set and a perfect set. Because any Gδ subset of a Polish space is again a Polish space, the theorem also shows that any Gδ subset of a Polish space is the union of a countable set and a set that is perfect with respect to the induced topology.
Topology in terms of derived sets
Because homeomorphisms can be described entirely in terms of derived sets, derived sets have been used as the primitive notion in topology. A set of points X can be equipped with an operator S ↦ S* mapping subsets of X to subsets of X, such that for any set S and any point a:
Calling a set S closed if will define a topology on the space in which S ↦ S* is the derived set operator, that is, . If we also require that the derived set of a set consisting of a single element be empty, the resulting space will be a T1 space. In fact, 2 and 3' can fail in a space that is not T1.
- for limit ordinals λ.
The transfinite sequence of Cantor–Bendixson derivatives of X must eventually be constant. The smallest ordinal α such that Xα+1 = Xα is called the Cantor–Bendixson rank of X.