Synthesis, structure and reactivity of µ3-SnH capped trinuclear nickel cluster.

Treatment of the trichlorotin-capped trinuclear nickel cluster, [Ni3(dppm)3(µ3-Cl)(µ3-SnCl3)], 1, with 4 eq. NaHB(Et)3 yields a µ3-SnH capped trinuclear nickel cluster, [Ni3(dppm)3(µ3-H)(µ3-SnH)], 2 [dppm = bis(diphenylphosphino)methane]. Single-crystal X-ray diffraction, nuclear magnetic resonance (NMR) spectroscopy, and computational studies together support that cluster 2 is a divalent tin hydride. Complex 2 displays a wide range of reactivity including oxidative addition of bromoethane across the Sn center. Addition of 1 eq. iodoethane to complex 2 releases H2 (g) and generates an ethyltin-capped nickel cluster with a µ3-iodide, [Ni3(dppm)3(µ3-I)(µ3-Sn(CH2CH3))], 4. Notably, insertion of alkynes into the Sn-H bond of 2 can be achieved via addition of 1 eq. 1-hexyne to generate the 1-hexen-2-yl-tin-capped nickel cluster, [Ni3(dppm)3(µ3H)(µ3-Sn(C6H11))], 5. Addition of H2 (g) to 5 regenerates the starting material, 2, and hexane. The formally 44-electron cluster 2 also displays significant redox chemistry with two reversible one-electron oxidations (E = -1.3 V, -0.8 V vs. Fc0/+) and one-electron reduction process (E = -2.7 V vs. Fc0/+) observed by cyclic voltammetry.

PM-IRRAS and DFT investigation of the surface orientation of new Ir piano-stool complexes attached to Au(111).

Surface immobilization of organometallic catalysts is a promising approach to developing new catalytic systems that combine molecular catalysts with heterogenous surfaces to probe surface mechanisms. The orientation of the catalyst relative to the surface is one important parameter that must be considered in such hybrid systems. In this work, we synthesize three new sulfide-modified Ir piano-stool complexes with sulfide-modified bipyridine and phenylpyridine ligands for the attachment to Au(111) surfaces. Self-assembled monolayers made from (Cp*Ir(2,2'-bipyridine-4-sulfide)Cl)2[Cl]2 (C1m) and [Cp*Ir(2-phenylpyridine-4-sulfide)Cl]2 (C2m) were characterized by combining polarization modulation infrared reflection absorption spectroscopy (PM-IRRAS) with DFT calculations of the minimum energy orientations of the complexes on the surface. We find that the bipyridine and phenylpyridine ligands are oriented at between 73-77° relative to the surface normal, irrespective of the orientation of the other ligands. Additionally, DFT and PM-IRRAS support that there is no orientation preference for C1m and C2m, with both orientations present on the surface.

Investigation of Immobilization Effects on Ni(P2N2)2 Electrocatalysts.

A new synthetic route to complexes of the type Ni(P2N2)22+ with highly functionalized phosphine substituents and the investigation of immobilization effects on these catalysts is reported. Ni(P2N2)22+ complexes have been extensively studied as homogeneous and surface-attached molecular electrocatalysts for the hydrogen evolution reaction (HER). A synthesis based on postsynthetic modification of PArBr2NPh2 was developed and is described here. Phosphonate-modified ligands and their corresponding nickel complexes were isolated and characterized. Subsequent deprotection of the phosphonic ester derivatives provided the first Ni(P2N2)22+ catalyst that can be covalently attached via pendent phosphonate groups to an electrode without involvement of the important pendent amine groups. Mesoporous TiO2 electrodes were surface modified by attachment of the new phosphonate functionalized Ni(P2N2)22+ complexes, and these provided electrocatalytic materials that proved to be competent and stable for sustained HER in aqueous solution at mild pH and low overpotential. We directly compared the new ligand to a previously reported complex that utilized the amine moiety for surface attachment. Using HER as the benchmark reaction, the P-attached catalyst showed a marginally (9-14%) higher turnover number than its N-attached counterpart.