Molybdenum(III) Thiocyanate- and Selenocyanate-Based One-Dimensional Heteronuclear Polymers: Coordination Affinity-Controlled Assemblage of Mixed Spin and Mixed Valence Derivatives with Ni(II) and Co(II/III).
Malihe MousaviCarine DuhayonKateryna BretoshVirginie BéreauJean-Pascal SutterPublished in: Inorganic chemistry (2020)
One-dimensional coordination polymers constructed with the 4d metallo-ligand [Mo(NCS)6]3- associated with NiII and CoII complexes are reported. The first series consists of anionic NCS-bridged [Mo-MII]- coordination polymers associated with a discrete paramagnetic complex or a diamagnetic CoIII complex acting as cations. The latter takes advantage of the coordination preference of the S-ligand for the soft 3d ions and has led to hetero-trimetallic [MoIIINiIICoIII] and mixed valence [MoIIICoIICoIII] compounds. A second series concerns neutral chains in which trinuclear [Mo M2II] units are bridged by an additional NCS anion. The soft character of the S atom was also the key to a rare example of a compound involving both high-spin and low-spin CoII centers associated with [Mo(NCS)6]. A [Mo-Ni] derivative obtained with [Mo(NCSe)6]3- has been considered in order to evaluate the effect of Se versus S on the exchange interaction. The spin distribution for selenocyanate metallo-ligand has been assessed by density functional theory calculations. The crystal structures for all compounds have been characterized, and their magnetic behaviors have been investigated. These ferrimagnetic systems are characterized by antiferromagnetic Mo-MII interactions in the range of -40 to -90 cm-1 (based on H = -JSaSb formalism) operative both with CoII and with NiII, thus demonstrating the potential of the MoIII-NCS combination for molecular systems in which exchange interactions play an important role.