Atomically Precise Platinum Carbonyl Nanoclusters: Synthesis, Total Structure, and Electrochemical Investigation of [Pt(CO)] Displaying a Defective Structure.

The molecular Pt nanocluster [Pt(CO)] () was obtained by thermal decomposition of [Pt(CO)] in tetrahydrofuran under a H atmosphere. The reaction of with increasing amounts of HBFEtO afforded the previously reported [Pt(CO)] () and [Pt(CO)] (). The new nanocluster was characterized by IR and UV-visible spectroscopy, single-crystal X-ray diffraction, direct-current superconducting quantum interference device magnetometry, cyclic voltammetry, IR spectroelectrochemistry (IR SEC), and electrochemical impedance spectroscopy. The cluster displays a cubic-close-packed Pt framework generated by the overlapping of four ABCA layers, composed of 3, 7, 11, and 6 atoms, respectively, that encapsulates a fully interstitial Pt tetrahedron. One Pt atom is missing within layer 3, and this defect (vacancy) generates local deformations within layers 2 and 3. These local deformations tend to repair the defect (missing atom) and increase the number of Pt-Pt bonding contacts, minimizing the total energy. The cluster is perfectly diamagnetic and displays a rich electrochemical behavior. Indeed, six different oxidation states have been characterized by IR SEC, unraveling the series of ( = 3-8) isostructural nanoclusters. Computational studies have been carried out to further support the interpretation of the experimental data.