- Sequential space
In
topology and related fields ofmathematics , a sequential space is atopological space that satisfies a very weakaxiom of countability . Sequential spaces are the most general class of spaces for whichsequence s suffice to determine the topology.Every sequential space has
countable tightness .Definitions
Let "X" be a topological space.
*A subset "U" of "X" is sequentially open if each sequence ("x""n") in "X" converging to a point of "U" is eventually in "U" (i.e. there exists "N" such that "x""n" is in "U" for all "n" ≥ "N".)
*A subset "F" of "X" is sequentially closed if, whenever ("x""n") is a sequence in "F" converging to "x", then "x" must also be in "F".The complement of a sequentially open set is a sequentially closed set, and vice-versa. Every open subset of "X" is sequentially open and every closed set is sequentially closed. The converses are not generally true.
A sequential space is a space "X" satisfying one of the following equivalent conditions:
#Every sequentially open subset of "X" is open.
#Every sequentially closed subset of "X" is closed.equential closure
Given a subset of a space , the sequential closure is the set :
that is, the set of all points for which there is a sequence in that converges to . The map
:
is called the sequential closure operator. It shares some properties with ordinary closure, in that the empty set is sequentially closed:
:
Sequentially closed sets are subsets of closed sets:
:
for all ; here denotes the ordinary closure of the set . Sequential closure commutes with union:
:
for all . However, unlike ordinary closure, the sequential closure operator is not in general
idempotent ; that is, one may have that:
even when is a subset of a sequential space .
Fréchet-Urysohn space
Topological spaces for which sequential closure is the same as ordinary closure are known as Fréchet-Urysohn spaces. That is, a Fréchet-Urysohn space has
:
for all . A space is Fréchet-Urysohn if and only if every subspace is a sequential space. Every
first-countable space is a Fréchet-Urysohn space.The space is named after
Maurice Fréchet andPavel Urysohn .History
Although spaces satisfying such properties had implicitly been studied for several years, the first formal definition is originally due to S. P. Franklin in 1965, who was investigating the question of "what are the classes of topological spaces that can be specified completely by the knowledge of their convergent sequences?" Franklin arrived at the definition above by noting that every
first-countable space can be specified completely by the knowledge of its convergent sequences, and then he abstracted properties of first countable spaces that allowed this to be true.Examples
Every
first-countable space is sequential, hence each second countable,metric space , anddiscrete space is sequential. Further examples are furnished by applying the categorical properties listed below.There are sequential spaces that are not first countable. (One example is to take the real line R and identify the set Z of integers to a point.)
An example of a space that is "not" sequential is the
cocountable topology on an uncountable set. Every convergent sequence in such a space is eventually constant, hence every set is sequentially open. But the cocountable topology is not discrete. In fact, one could say that the cocountable topology on an uncountable set is "sequentially discrete".Equivalent conditions
Many conditions have been shown to be equivalent to being sequential. Here are a few:
*"X" is sequential.
*"X" is the quotient of a first countable space.
*"X" is the quotient of a metric space.
*For every topological space "Y" and every map "f" : "X" → "Y", we have that "f" is continuous if and only if for every sequence of points ("x""n") in "X" converging to "x", we have ("f"("x""n")) converging to "f"("x").The final equivalent condition shows that the class of sequential spaces consists precisely of those spaces whose topological structure is determined by convergent sequences in the space.
Categorical properties
The
full subcategory Seq of all sequential spaces is closed under the following operations in Top:* Quotients
* Continuous closed or open images
* Sums
* Inductive limits
* Open and closed subspacesThe category Seq is "not" closed under the following operations in Top:
* Continuous images
* Subspaces
* ProductsSince they are closed under topological sums and quotients, the sequential spaces form a
coreflective subcategory of thecategory of topological spaces . In fact, they are the coreflective hull ofmetrizable space s (i.e., the smallest class of topological spaces closed under sums and quotients and containing the metrizable spaces).The subcategory Seq is a
cartesian closed category with respect to its own product (not that of Top). Theexponential object s are equipped with the (convergent sequence)-open topology. P.I. Booth and A. Tillotson have shown that Seq is the smallest cartesian closed subcategory of Top containing the underlying topological spaces of allmetric space s,CW-complex es, anddifferentiable manifold s and that is closed under limits, colimits, subspaces, quotients, and other "certain reasonable identities" thatNorman Steenrod described as "convenient".See also
*
Axioms of countability
*First-countable space References
*Arkhangel'skii, A.V. and Pontryagin, L.S., "General Topology I", Springer-Verlag, New York (1990) ISBN 3-540-18178-4.
*Booth, P.I. and Tillotson, A., "Monoidal closed, cartesian closed and convenient categories of topological spaces" Pacific J. Math., 88 (1980) pp. 35–53.
*Engelking, R., "General Topology", PWN, Warsaw, (1977).
*Franklin, S. P., "Spaces in Which Sequences Suffice", Fund. Math. 57 (1965), 107-115.
*Franklin, S. P., "Spaces in Which Sequences Suffice II", Fund. Math. 61 (1967), 51-56.
*Goreham, Anthony, " [http://www.citebase.org/cgi-bin/citations?id=oai:arXiv.org:math/0412558 Sequential Convergence in Topological Spaces]
*Steenrod, N.E., "A convenient category of topological spaces", Michigan Math. J., 14 (1967), 133-152.
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