An insight into molecular structures, fluorescent, and catalytic oxidase properties of novel heteromultinuclear [Cu II 4 Sm III 2 ] and [Cu II 2 Tb III ] bis (salamo)‐based complexes

Two newly designed heteromultinuclear [Cu II 4 Sm III 2 ] and [Cu II 2 Tb III ] bis (salamo)‐based complexes, [{Cu 2 (L)Sm (NO 3 ) 2 ( μ 2 ‐NO 3 )(CH 3 OH)} 2 ]·2CH 3 OH and [Cu 2 (L)Tb (NO 3 ) 2 ( μ 2 ‐NO 3 )][Cu 2 (L)Tb (NO 3 ) 2 ( μ 2 ‐NO 3 )(H 2 O)]·CH 3 OH, were synthesized and characterized by elemental analyses, Fourier transform infrared (FT‐IR) spectra, ultraviolet–visible (UV–vis) absorption spectra, and X‐ray crystallography. The ultraviolet titration experiments exhibited that the coordination ratio of the ligand, rare earth metal, and transition metal is 1:1:2. In the [Cu II 4 Sm III 2 ] complex, Cu1 atom has a distorted quadrilateral pyramid geometry, whereas Cu2 atom forms a slightly distorted octahedral geometry. The [Cu II 2 Tb III ] complex unit cell contains two crystallographically independent and chemically different heterotrinuclear complexes (Molecules A and B). In Molecule A, the Cu1 atom bears a four‐coordinated plane quadrilateral geometry, whereas the five‐coordinated Cu2 atom forms a slightly distorted tetragonal cone geometry. In Molecule B, the five‐coordinated Cu3 and Cu4 atoms possess slightly distorted tetragonal cone geometries. Noncovalent interactions like hydrogen bonding and π···π stacking interactions are operative in construction of supramolecular architectures. The [Cu II 2 Tb III ] complex behaves as a catalyst towards oxidative coupling of 2‐AP in MeCN medium. In addition, fluorescence properties of the ligand H 4 L and its [Cu II 4 Sm III 2 ] and [Cu II 2 Tb III ] complexes have also been discussed.