Copper(II), Zinc(II), and Cadmium(II) Formylbenzoate Complexes: Reactivity and Emission Properties

Abstract: Synthesis, characterization, reactivity, and sensing properties of 4-formylbenzoate complexes of copper(II), zinc(II), and cadmium(II) possessing the 1,10-phenanthroline ancillary ligand are studied. The crystal structures of the (1,10-phenanthroline)bis(4-formylbenzoate)(aqua)copper(II) and (1,10-phenanthroline)bis(4-formylbenzo-ate)zinc(II) and a novel molecular complex comprising an assembly of mononuclear and dinuclear species of (1,10-phenanthroline)bis(4-formylbenzoate)cadmium(II) are reported. These zin… Show more

“…Furthermore, the increase in the concentration of water initially competes with the solvent to make an organized structure by taking possible coordination sites and making an assembly suitable for showing AIE. As the amount of water increases, water reorganizes the assembly to segregate the self-assembled zinc complexes yet provides scope to remain as newly formed assemblies through fast exchange that are not detected in the NMR time scale in solution . Such equilibriums are possible as the change of solvents makes different zinc complexes and dimensionality of carboxylate polymers changes with solvent coordination .…”

“…As the amount of water increases, water reorganizes the assembly to segregate the self-assembled zinc complexes yet provides scope to remain as newly formed assemblies through fast exchange that are not detected in the NMR time scale in solution. 37 Such equilibriums are possible as the change of solvents makes different zinc complexes 27 and dimensionality of carboxylate polymers changes with solvent coordination. 56 The changes in dimensionality also affect the photoluminescence properties.…”

“…The self-assembly of various zinc complexes shows novel emission properties. − Many zinc complexes have prospects as applied optoelectronic materials. − Besides enhanced chemical reactivity for catalytic reactions, − optoelectronic properties of zinc oxide necessitate the study of polynuclear zinc clusters possessing a ZnO 4 environment. − Solvent plays an important role in the synthesis of such zinc clusters or coordination polymers. , Design of ligands − and improvisation of noncovalent interactions of ligands are common ways to synthesize complexes with less conventional coordination numbers such as five-coordinated , zinc complexes. A careful look at the number of zinc complexes suggests that, irrespective of ligands, they show emissions near 400–430 nm with some exceptions. − Some d 10 zinc complexes show sample- and size-dependent fluorescence emissions, whereas in certain cases, aggregation-induced emissions (AIE) of zinc complexes are comparable to similar emissions by corresponding d 10 cadmium complexes . Those observations together with the emergence of AIEgens of zinc complexes − and the development of newer aspects of AIEgens , make one curious to explore the emission behavior of simple zinc complexes.…”

“…1−8 Some d 10 zinc complexes show sample-and size-dependent fluorescence emissions, 36 whereas in certain cases, aggregation-induced emissions (AIE) of zinc complexes are comparable to similar emissions by corresponding d 10 cadmium complexes. 37 Those observations together with the emergence of AIEgens of zinc complexes 38−41 and the development of newer aspects of AIEgens 42,43 make one curious to explore the emission behavior of simple zinc complexes. Furthermore, the AIEgens are generally developed from fluorescent compounds, whereas a metal complex helps to bring together nonfluorescent components to modulate emission based on metal-to-ligand charge-transfer transitions.…”

Self-Assemblies of Zinc Complexes for Aggregation-Induced Emission Luminogen Precursors

“…Furthermore, the increase in the concentration of water initially competes with the solvent to make an organized structure by taking possible coordination sites and making an assembly suitable for showing AIE. As the amount of water increases, water reorganizes the assembly to segregate the self-assembled zinc complexes yet provides scope to remain as newly formed assemblies through fast exchange that are not detected in the NMR time scale in solution . Such equilibriums are possible as the change of solvents makes different zinc complexes and dimensionality of carboxylate polymers changes with solvent coordination .…”

“…As the amount of water increases, water reorganizes the assembly to segregate the self-assembled zinc complexes yet provides scope to remain as newly formed assemblies through fast exchange that are not detected in the NMR time scale in solution. 37 Such equilibriums are possible as the change of solvents makes different zinc complexes 27 and dimensionality of carboxylate polymers changes with solvent coordination. 56 The changes in dimensionality also affect the photoluminescence properties.…”

“…The self-assembly of various zinc complexes shows novel emission properties. − Many zinc complexes have prospects as applied optoelectronic materials. − Besides enhanced chemical reactivity for catalytic reactions, − optoelectronic properties of zinc oxide necessitate the study of polynuclear zinc clusters possessing a ZnO 4 environment. − Solvent plays an important role in the synthesis of such zinc clusters or coordination polymers. , Design of ligands − and improvisation of noncovalent interactions of ligands are common ways to synthesize complexes with less conventional coordination numbers such as five-coordinated , zinc complexes. A careful look at the number of zinc complexes suggests that, irrespective of ligands, they show emissions near 400–430 nm with some exceptions. − Some d 10 zinc complexes show sample- and size-dependent fluorescence emissions, whereas in certain cases, aggregation-induced emissions (AIE) of zinc complexes are comparable to similar emissions by corresponding d 10 cadmium complexes . Those observations together with the emergence of AIEgens of zinc complexes − and the development of newer aspects of AIEgens , make one curious to explore the emission behavior of simple zinc complexes.…”

“…1−8 Some d 10 zinc complexes show sample-and size-dependent fluorescence emissions, 36 whereas in certain cases, aggregation-induced emissions (AIE) of zinc complexes are comparable to similar emissions by corresponding d 10 cadmium complexes. 37 Those observations together with the emergence of AIEgens of zinc complexes 38−41 and the development of newer aspects of AIEgens 42,43 make one curious to explore the emission behavior of simple zinc complexes. Furthermore, the AIEgens are generally developed from fluorescent compounds, whereas a metal complex helps to bring together nonfluorescent components to modulate emission based on metal-to-ligand charge-transfer transitions.…”

Self-Assemblies of Zinc Complexes for Aggregation-Induced Emission Luminogen Precursors

“…The bond lengths and bond angles range between 2.2939(17)-2.3637( 14) Å and 56.26(5)-154.07( 6)°( ESI: † Table S4), presenting similar values to that of other hexacoordinated Cd(II) compounds based on μ 1 -η 2 coordinated carboxylate moieties and 1,10-phen ligands. 50,51 Their intermolecular interactions expand the structure along the bc plane, forming a 2D supramolecular structure (Fig. 4b).…”

Influence of a series of pyridine ligands on the structure and photophysical properties of Cd(ii) complexes

Inorganic Molecular Complexes: Potential for Growth of a New Subject Area in Self-Assembly