Pseudocircle

Not to be confused with Quasicircle.

The pseudocircle is the finite topological space X consisting of four distinct points {a,b,c,d } with the following non-Hausdorff topology:

$${\displaystyle \{\{a,b,c,d\},\{a,b,c\},\{a,b,d\},\{a,b\},\{a\},\{b\},\varnothing \}.}$$

This topology corresponds to the partial order ${\displaystyle a<c,\ b<c,\ a<d,\ b<d}$ where open sets are downward-closed sets. X is highly pathological from the usual viewpoint of general topology as it fails to satisfy any separation axiom besides T₀. However, from the viewpoint of algebraic topology X has the remarkable property that it is indistinguishable from the circle S¹.

More precisely the continuous map ${\displaystyle f}$ from S¹ to X (where we think of S¹ as the unit circle in ${\displaystyle \mathbb {R} ^{2}}$) given by

$${\displaystyle f(x,y)={\begin{cases}a,&x<0\\b,&x>0\\c,&(x,y)=(0,1)\\d,&(x,y)=(0,-1)\end{cases}}}$$

is a weak homotopy equivalence, that is ${\displaystyle f}$ induces an isomorphism on all homotopy groups. It follows^[1] that ${\displaystyle f}$ also induces an isomorphism on singular homology and cohomology and more generally an isomorphism on all ordinary or extraordinary homology and cohomology theories (e.g., K-theory).

This can be proved using the following observation. Like S¹, X is the union of two contractible open sets {a,b,c} and {a,b,d } whose intersection {a,b} is also the union of two disjoint contractible open sets {a} and {b}. So like S¹, the result follows from the groupoid Seifert-van Kampen theorem, as in the book Topology and Groupoids.^[2]

More generally McCord has shown that for any finite simplicial complex K, there is a finite topological space X_K which has the same weak homotopy type as the geometric realization |K| of K. More precisely there is a functor, taking K to X_K, from the category of finite simplicial complexes and simplicial maps and a natural weak homotopy equivalence from |K| to X_K.^[3]

See also

• List of topologies – List of concrete topologies and topological spaces

References

1. Allen Hatcher (2002) Algebraic Topology, Proposition 4.21, Cambridge University Press
2. Ronald Brown (2006) "Topology and Groupoids", Bookforce
3. McCord, Michael C. (1966). "Singular homology groups and homotopy groups of finite topological spaces". Duke Mathematical Journal. 33: 465–474. doi:10.1215/S0012-7094-66-03352-7.