This book is designed for the reader who wants to get a general view of the terminology of General Topology with minimal time and effort. The reader, whom we assume to have only a rudimentary knowledge of set theory, algebra and analysis, will be able to find what they want if they will properly use the index. However, this book contains very few proofs and the reader who wants to study more systematically will find sufficiently many references in the book.
Key features:
âą More terms from General Topology than any other book ever publishedâą Short and informative articlesâą Authors include the majority of top researchers in the fieldâą Extensive indexing of terms
on a set is a quasiorder if it is transitive and reflexive. It is called a trivial quasiorder if all-ways x
y, and is defined to be a discrete relation if it agrees with equality; it is said to be an order (sometimes simply called a partial order) if it is antisymmetric, that is, (â x, y) ((x
y and y
x) â (x = y)). A subset Y of a quasiordered set X is a lower set if (â x, y) ((x
y and y â Y) â x â Y); the definition of an upper set is analogous. On a topological spaceX set x
y iff every neighbourhood of x is a neighbourhood of y. This definition introduces a quasiorder
, called the specialisation quasiorder of X. The terminology originates from algebraic geometry, see [18, II, p. 23]. The specialisation quasiorder is trivial iff X has the indiscrete topology. The closure
of a subset Y of a topological space X is precisely the lower set â Y of all x â X with x
y for some y â Y. The singleton closure {
} is the lower set â {x}, succinctly written â x. The intersection of all neighbourhoods of x is the upper set â x = {y â X : x
y}.
A topological space X is said to satisfy the separation axiomT0 (or to be a T0-space), and its topology
X is called a T0-topology, if the specialisation quasiorder is an order; in this case it is called the specialisation order. The space X is said to satisfy the separation axiomT1 (or to be a T1-space), and its topology
X is called a T1-topology, if the specialisation quasiorder is discrete. The terminology for the hierarchy Tn of separation axioms appears to have entered the literature 1935 through the influential book by Alexandroff and Hopf [3] in a section of the book called âTrennungsaxiomeâ (pp. 58 ff.). A space is a T0-space iff
(0) for two different points there is an open set containing precisely one of the two points,
and it is a T1-space iff
(1) every singleton subset is closed.
Alexandroff and Hopf call postulate (0) âdas nullte Kolmogoroffsche Trennungsaxiomâ and postulate (1) âdas er-ste Frechetsche Trennungsaxiomâ [3, pp. 58, 59], and they attach with the higher separation axioms the names of Hausdorff, Vietoris and Tietze. In Bourbaki [4], T0-spaces are relegated to the exercises and are called
[7, p. 185]. From an axiomatic viewpoint, the postulate (1) is a natural separation axiom for those who base topology on the concept of a closure operator (Kuratowski 1933); Hausdorffâs axiom, called T2 by Alexandroff and Hopf, is a natural one if the primitive concept is that of neighbourhood systems (Hausdorff [9] 1914). In [14] Kuratowski joins the...
