An overview on copper based heterometallic complexes in combination with d10 metal ions derived from N2O2 donor di-Schiff base ligands.

Synopsis on Cu(II)-M(II) (M = Zn, Cd and Hg) hetero-metallic compounds derived from Cu(II) chelates of N 2 O 2 donor di-Schiff base ligands. [Display omitted] • Hetero-metallic complexes of Cu(II) bound N 2 O 2 donor Schiff bases with Zn(II)/Cd(II)/Hg(II). • Different synthetic approaches (mostly "complex as ligand") for the isolation of hetero-metallic complexes. • Effects of coordination motif of anionic coligands on structural diversities and nuclearities of complexes. • Few novel isomers in coordination chemistry have been described. A good number of heterometallic complexes based on various Cu(II) bound "metalloligands" of N 2 O 2 donor di-Schiff bases and some of their reduced counterpart along with group 12 metal ions have been synthesized and characterized by different research groups in the literature. This review focuses on an overview of the synthetic strategies, X-ray crystallographic structures and a few important properties of these complexes. These have been discussed in three major sub-classes: Cu(II)-Zn(II), Cu(II)-Cd(II) and Cu(II)-Hg(II) heterometallic complexes. Judicious combinations of carbonyls and di-amines in an easy and effective manner gives 14 selected di-Schiff base ligands (symmetrical and unsymmetrical) with particular shape, geometry and denticity that direct the synthesis of these metal complexes totally or preferentially towards di-, tri- or poly-nuclear entities. Moreover, owing to their ability to assemble three metal ions in close proximity, these resulting oxido-bridged flexible coordination clusters adapted to various other ligand functionalities with particular shape and sometimes unusual coordination modes with certain degree of control. Such unique structural aspect of this system is immensely important in inorganic synthesis. The inherent flexibility of the di-oxido bridged trinuclear coordination cluster led to produce isomeric linear and bent structures that usually depend upon various factors e.g. the nature of the Schiff base, anionic co-ligands, temperature, solvent etc. The structural aspects of resulting discrete and polymeric self-assemblies have enriched the coordination library that extended to develop numerous heterometallic systems with significant applications and new scopes [ABSTRACT FROM AUTHOR]