Conjunctive Join Semi-Lattices

Abstract

A join-semilattice L is said to be conjunctive if it has a top element 1 and it satisfies the following first-order condition: for any two distinct a,b∈ L, there is c∈ L such that either a c=1=b c or a c=1=b c. Equivalently, a join-semilattice is conjunctive if every principal ideal is an intersection of maximal ideals. We present simple examples showing that a conjunctive join-semilattice may fail to have any prime ideals. (Maximal ideals of a join-semilattice need not be prime.) We show that every conjunctive join-semilattice is isomorphic to a join-closed subbase for a compact T1-topology on Max L, the set of maximal ideals of L. The representation is canonical in that when applied to a join-closed subbase for a compact T1-space X, the space produced by the representation is homeomorphic with X. We say a join-semilattice morphism φ:L M is conjunctive if φ-1(w) is an intersection of maximal ideals of L whenever w is a maximal ideal of M. We show that every conjunctive morphism between conjunctive join-semilattices is induced by a multi-valued function from Max M to Max L. A base for a topological space is said to be annular if it is a lattice, and Wallman if it is annular and for any point u in any basic open U, there a basic open V that misses u and together with U covers X. It is easy to show that every Wallman base is conjunctive. We give an example of a conjunctive annular base that is not Wallman. Finally, we examine the free distributive lattice dL over a conjunctive join semilattice L. In general, it is not conjunctive, but we show that a certain canonical, algebraically-defined quotient of dL is isomorphic to the sub-lattice of the topology of the representation space that is generated by L. We describe numerous applications.