The Lawson number of a semitopological semilattice

Abstract

For a Hausdorff topologized semilattice X its Lawson\;\; number (X) is the smallest cardinal such that for any distinct points x,y∈ X there exists a family U of closed neighborhoods of x in X such that | U| and U is a subsemilattice of X that does not contain y. It follows that (X)(X), where (X) is the smallest cardinal such that for any point x∈ X there exists a family U of closed neighborhoods of x in X such that | U| and U=\x\. We prove that a compact Hausdorff semitopological semilattice X is Lawson (i.e., has a base of the topology consisting of subsemilattices) if and only if (X)=1. Each Hausdorff topological semilattice X has Lawson number (X)ω. On the other hand, for any infinite cardinal λ we construct a Hausdorff zero-dimensional semitopological semilattice X such that |X|=λ and (X)=(X)=cf(λ). A topologized semilattice X is called (i) ω-Lawson if (X)ω; (ii) complete if each non-empty chain C⊂ X has ∈f C∈C and C∈C. We prove that for any complete subsemilattice X of an ω-Lawson semitopological semilattice Y, the partial order X=\(x,y)∈ X× X:xy=x\ of X is closed in Y× Y and hence X is closed in Y. This implies that for any continuous homomorphism h:X Y from a compete topologized semilattice X to an ω-Lawson semitopological semilattice Y the image h(X) is closed in Y.