posted on 2007-09-03, 00:00authored byMatthew R. Montney, Subhashree Mallika Krishnan, Ronald M. Supkowski, Robert L. LaDuca
Hydrothermal synthesis has afforded a family of divalent metal adipate (adp) coordination polymers incorporating
the kinked dipodal organodiimine 4,4‘-dipyridylamine (dpa). As revealed by single-crystal X-ray diffraction, the structures
of these materials are critically dependent on the metal coordination geometry, the carboxylate binding modes, and
the conformations of the flexible adipate moieties. In all cases, hydrogen-bonding interactions imparted by the dpa
tethers also play a structure-directing role. All materials were further characterized via infrared spectroscopy and
elemental and thermogravimetric analysis. [Co(adp)(dpa)] (1) displays doubly interpenetrated three-dimensional
(3-D) networks with a decorated α-Po-type (pcu) topology. In contrast, [Ni(adp)(dpa)(H2O)] (2) possesses a triply
interpenetrated binodal cooperite-type (pts) framework, the highest level of interpenetration yet reported for this
structure type. [Zn(adp)(dpa)]·H2O (3) presents mutually inclined polycatenated 2-D graphitic layers consisting of
neutral dimeric [Zn2(μ2-adp)2] kernels conjoined by dipodal dpa ligands. Compound 1 exhibited weak antiferromagnetic
coupling between its carboxylate-bridged Co atoms, following Curie−Weiss behavior with ϑ = −3.3 K. Compound
3 manifested blue light emission under ultraviolet excitation, as well as a reversible structural reorganization upon
dehydration/rehydration.