The majority of 'everyday' spaces in
mathematics are first-countable. In particular, every
metric space is first-countable. To see this, note that the set of
open balls centered at x with radius 1/n for integers form a countable local base at x. An example of a space that is not first-countable is the
cofinite topology on an
uncountable set (such as the
real line). More generally, the
Zariski topology on an
algebraic variety over an uncountable field is not first-countable. Another counterexample is the
ordinal space \omega_1 + 1 = \left[0, \omega_1\right] where \omega_1 is the
first uncountable ordinal number. The element \omega_1 is a
limit point of the subset \left[0, \omega_1\right) even though no sequence of elements in \left[0, \omega_1\right) has the element \omega_1 as its limit. In particular, the point \omega_1 in the space \omega_1 + 1 = \left[0, \omega_1\right] does not have a countable local base. Since \omega_1 is the only such point, however, the subspace \omega_1 = \left[0, \omega_1\right) is first-countable. The
quotient space \R / \N where the natural numbers on the real line are identified as a single point is not first countable. However, this space has the property that for any subset A and every element x in the closure of A, there is a sequence in A converging to x. A space with this sequence property is sometimes called a
Fréchet–Urysohn space. First-countability is strictly weaker than
second-countability. Every
second-countable space is first-countable, but any uncountable
discrete space is first-countable but not second-countable. == Properties ==