Metal organic framework (MOF) liquid crystals. 1D, 2D and 3D ionic coordination polymer structures in the thermotropic mesophases of metal soaps, including alkaline earth, transition metal and lanthanide soaps

• Published in: Current opinion in colloid & interface science Vol. 13; no. 4; pp. 288 - 302
• Main Author: Corkery, Robert W.
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.08.2008; Elsevier
• Subjects: Chemistry; Colloidal state and disperse state; Exact sciences and technology; General and physical chemistry; review lanthanide carboxylic acid complex MOF liq crystal transition; Surface physical chemistry; Self assembly; Lanthanide; Support; Experimental method; Review; Alkaline earth metal; Soap; Liquid crystals; Phase transitions; Depolymerization; Chemical reduction; Strontium; Liquid metal; Packing; Ordering; Structure; Oxygen; Hydrocarbon; Rod; Polymer; Crystallinity; Topology; Liquid; Carboxylate; Homologous series; Models; Mesophase
• ISSN: 1359-0294; 1879-0399; 1879-0399
• DOI: 10.1016/j.cocis.2008.03.001

Taken together, the body of existing literature on metal soap crystal structures and mesophases supports the view that much is to be gained by treating the soaps as metal organic frameworks (MOF's) when relating their structure and liquid crystallinity. We argue that metal soaps mesophases often consist of disordered metal organic (carboxylate) frameworks (MOF's). Metal atoms are linked by bridging carboxylates, and the metal–oxygen networks form semi-flexible rods, chains and sheets of M–O polyhedra within their co-bonded, mesotructured, self-assemblies of lipidic chains. The packing of the molten hydrocarbon chains allows otherwise unconnected MOF networks to coexist as spatially isolated units in the same unit cell. For instance the lamellar phases are true 2D MOF's or layers of 1-D MOF's. The phase transitions can then be regarded as coupled disordering/re-ordering transitions involving rotational and conformational disordering of the hydrocarbon chains balanced with disordering of MOF symmetries, MOF topological transformations, depolymerizations and dimensionality reductions ultimately leading to anisotropic melts. By way of demonstration, thermotropic phase transitions of homologous series of lanthanide soaps are systematically studied using a variety of experimental methods, and the data are used in a topological model for testing the consistency with the MOF concept of metal soap crystal structures and thermotropic mesophases. Finally, an interpenetrating bicontinuous MOF comprised of SrO 6 polyhedral rods is presented as an atomically resolved model for the network topology of the cubic mesophase of strontium soaps. Metal soaps are therefore shown to afford a bridge between liquid crystals and metal organic framework (MOF) materials.