Sober space explained

In mathematics, a sober space is a topological space X such that every (nonempty) irreducible closed subset of X is the closure of exactly one point of X: that is, every nonempty irreducible closed subset has a unique generic point.

Definitions

Sober spaces have a variety of cryptomorphic definitions, which are documented in this section. All except the definition in terms of nets are described in.^[1] In each case below, replacing "unique" with "at most one" gives an equivalent formulation of the T₀ axiom. Replacing it with "at least one" is equivalent to the property that the T₀ quotient of the space is sober, which is sometimes referred to as having "enough points" in the literature.

With irreducible closed sets

A closed set is irreducible if it cannot be written as the union of two proper closed subsets. A space is sober if every nonempty irreducible closed subset is the closure of a unique point.

A topological space X is sober if every map that preserves all joins and all finite meets from its partially ordered set of open subsets to

is the inverse image of a unique continuous function from the one-point space to X.

This may be viewed as a correspondence between the notion of a point in a locale and a point in a topological space, which is the motivating definition.

Using completely prime filters

A filter F of open sets is said to be completely prime if for any family

of open sets such that , we have that for some i. A space X is sober if it each completely prime filter is the neighbourhood filter of a unique point in X.

In terms of nets

is self-convergent if it converges to every point in , or equivalently if its eventuality filter is completely prime. A net that converges to converges strongly if it can only converge to points in the closure of . A space is sober if every self-convergent net converges strongly to a unique point .^[2]

In particular, a space is T1 and sober precisely if every self-convergent net is constant.

As a property of sheaves on the space

A space X is sober if every functor from the category of sheaves Sh(X) to Set that preserves all finite limits and all small colimits must be the stalk functor of a unique point x.

Properties and examples

Any Hausdorff (T₂) space is sober (the only irreducible subsets being points), and all sober spaces are Kolmogorov (T₀), and both implications are strict.^[3]

Sobriety is not comparable to the T₁ condition:

• an example of a T₁ space which is not sober is an infinite set with the cofinite topology, the whole space being an irreducible closed subset with no generic point;
• an example of a sober space which is not T₁ is the Sierpinski space.

Moreover T₂ is stronger than T₁ and sober, i.e., while every T₂ space is at once T₁ and sober, there exist spaces that are simultaneously T₁ and sober, but not T₂. One such example is the following: let X be the set of real numbers, with a new point p adjoined; the open sets being all real open sets, and all cofinite sets containing p.

Sobriety of X is precisely a condition that forces the lattice of open subsets of X to determine X up to homeomorphism, which is relevant to pointless topology.

Sobriety makes the specialization preorder a directed complete partial order.

Every continuous directed complete poset equipped with the Scott topology is sober.

Finite T₀ spaces are sober.^[4]

The prime spectrum Spec(R) of a commutative ring R with the Zariski topology is a compact sober space.^[3] In fact, every spectral space (i.e. a compact sober space for which the collection of compact open subsets is closed under finite intersections and forms a base for the topology) is homeomorphic to Spec(R) for some commutative ring R. This is a theorem of Melvin Hochster.More generally, the underlying topological space of any scheme is a sober space.

The subset of Spec(R) consisting only of the maximal ideals, where R is a commutative ring, is not sober in general.

See also

• Stone duality, on the duality between topological spaces that are sober and frames (i.e. complete Heyting algebras) that are spatial.

Further reading

• Book: Pedicchio . Maria Cristina . Tholen . Walter . Categorical foundations. Special topics in order, topology, algebra, and sheaf theory . Encyclopedia of Mathematics and Its Applications . 97 . Cambridge . . 2004 . 0-521-83414-7 . 1034.18001 .
• Book: Vickers, Steven . Steve Vickers (computer scientist)

. Steve Vickers (computer scientist) . Topology via logic . Cambridge Tracts in Theoretical Computer Science . 5 . Cambridge . . 1989 . 0-521-36062-5 . 0668.54001 . 66 .

Notes and References

1. Book: Mac Lane . Saunders . Sheaves in geometry and logic: a first introduction to topos theory . 1992 . Springer-Verlag . New York . 978-0-387-97710-2 . 472-482.
2. Sünderhauf . Philipp . Sobriety in Terms of Nets . Applied Categorical Structures . 1 December 2000 . 8 . 4 . 649–653 . 10.1023/A:1008673321209.
3. Book: Encyclopedia of general topology . limited . Klaas Pieter . Hart . Jun-iti . Nagata . Jerry E. . Vaughan . Elsevier . 2004 . 978-0-444-50355-8 . 155–156 .
4. Web site: General topology - Finite $T_0$ spaces are sober.