Alan Miralrio

Complexes of graphene nanoribbons with porphyrins and metal-encapsulated C28 as molecular rectifiers: a theoretical study

Abstract The rectification properties of porphyrin–graphene nanoflake complexes and endohedral complexes of C28 fullerene with metal atoms have been studied using the fully ab initio method. D3 dispersion-corrected PBE/-def2-SVP model was used for the optimisations and the electronic energy evaluation. In porphyrin–graphene nanoflake complexes dispersion dominates, while in the endohedral complexes of C28 dispersion does not play an important role. All studied systems do rectify. In the case of fullerenes, the rectification is possible due to the reduction in the molecular symmetry of the fullerene caused by the interaction with electrodes and the endohedral complex formation. The origin of the rectification is the asymmetrical deformation of the electron density under direct and inverse voltages which creates different currents in opposite directions. It seems that peculiar geometry of Au-TPP-Cd/NF diode is responsible for its high rectification ratio. The Cd ion is notably out of the porphyrin plane making close contact with the neighbouring electrode, increasing the asymmetry of the diode compared to other TPP/NF complexes.

Catalytic Reduction of Nitrous Oxide by the Low-Symmetry Pt8 Cluster

The search for a catalyst for the reduction of nitrous oxide (N2O) is now imperative, as this molecule is a very dangerous pollutant. We found that the low-symmetry Pt8 cluster presents multiple reaction pathways for N2O rupture, which are regioselective. This result was revealed by means of density functional theory calculations within the zero-order-regular approximation, ZORA, explicitly including relativistic effects. It is further proved that Pt8 is a competitive N2O catalyst compared to sub-nanometric rhodium clusters, obtaining similar reaction barriers. The hot adsorption site, a tip atom of Pt8, and the rotation of the N2O molecule over the metallic cluster promote the formation of a frustrated bridge activated transition state, Pt8-N2O. This transition structure yields to spontaneous dissociation of N2O without bridge formation. Along this catalytic process, rearrangements within the metal cluster take place, preserving its stability. Moreover, in addition to being important attributes of the Pt8 particle in the N2O reduction, fluxionality and multiple reaction pathways may also prevent poisoning effects. Overall, this differs from reported results for more symmetric metal particles also used as catalysts.