OAR@UM Collection:https://www.um.edu.mt/library/oar/handle/123456789/1437792026-04-23T06:05:59Z2026-04-23T06:05:59ZIntrinsic topologies on ordered structures : applicationshttps://www.um.edu.mt/library/oar/handle/123456789/1440702026-02-24T14:06:37Z2026-01-01T00:00:00ZTitle: Intrinsic topologies on ordered structures : applications
Abstract: This thesis is divided into two main parts. The first three chapters
focus on the study of order and unbounded order convergence. We examine various well-established definitions of order convergence, that
have emerged over time, each associated with a corresponding topology. These notions are compared in detail, with particular attention
to the conditions under which they coincide or differ. Furthermore, in
the context of a semi-finite measure space, we investigate the relationship between the topologies on L∞ arising from the duality (L∞, L1),
and we compare these to the order topology. Notably, we establish
a condition under which the Mackey topology is strictly weaker than
the order topology.
Compared to order convergence, unbounded order convergence is
relatively new and is generally studied on Riesz spaces. In this thesis, we explore it in the broader context of lattices. Our results show
that, similar to the order topology, the unbounded order topology is
independent of the definition of order convergence. In addition, we
extend key properties known to hold in Riesz spaces to lattices. We
prove that order continuity of unbounded order convergence is equivalent to the lattice being infinitely distributive. Moreover, we show
that the O-closure and uO-closure of a sublattice coincide and form a
sublattice. Furthermore, we show that the uO-adherence of an ideal
is an O-closed ideal. We also examine the MacNeille completion of a
sublattice Y relative to that of a lattice L, identifying two conditions
under which the completion of Y embeds regularly in that of L.
The last chapter is dedicated to the study of lattice uniformities. It
is known that for a locally solid Riesz space (X, τ ) there exists a locally
solid linear topology uτ on X such that unbounded τ -convergence
coincides with uτ -convergence. This topology is the weakest locally
solid linear topology that agrees with τ on all order bounded subsets.
Thus, for a uniform lattice (L, U), we introduce the weakest lattice
uniformity U∗ on L that coincides with U on each order bounded
subset of L. We see that if U is the uniformity induced by the topology
of a locally solid Riesz space (X, τ ), then the U∗ -topology coincides
with uτ . We also provide answers to several questions posed in [44, 37].
Description: Ph.D.(Melit.)2026-01-01T00:00:00Z