By design, all objectives in the project are persuadable independently. From the very start, we have performed massive first principle investigation of magnetism of isolated molecular systems with different clusters inside fullerene cages like dimmers of lanthanides, small lanthanides nitrides, oxides, sulfides and many more. Over time, it has mounted in a library of fundamental properties for the systems accessed by theoretical means and checked against experimental data if possible. Working in close collaboration with an outstanding research team, we have been able to report our theoretical findings in multiple joined scientific. Some of these systems, like lanthanides dimmers, have shown truly remarkable and even records breaking magnetic properties and single molecular magnetism stability. The theoretical investigations have helped better understand the systems and strategies further research.
As mentioned, the geometries of these clusters and special orientations are sensitive to the global environment. Importantly, in these systems, the magnetic order is strongly intertwined with these geometrical characteristics. Thus, the knowledge of structural order will provide great insight into magnetic arrangements. A small perturbation by surfaces by other molecules around may have a profound effect. These, in due turn, control the system's functionality and ability to use the desire properties in ensembles on surfaces in the form of self-assembled monolayers. Also, in the compact arrays on surfaces or crystals, the molecular magnets may be sensitive to the magnetic field generated by neighbor molecules. This facilitates unexpected system behaviors. SamSD dives deep in these issues through comprehensive research and modeling, using cutting-edge theoretical models. Having proposed a sophisticated way of sampling of the cluster conformational spaces, we were able to figure out the fundamental forces which control the clusters ordering and thus ordering of magnetic characteristics. These have improved a general knowledge about the sensitivities of the system and provided means to justify the experimental spectroscopy data, sensitive to the magnetic ordering of molecular arrays on surfaces.
Furthermore, we have considered the impact of valence electron on the formation of a magnetic state of the systems. The proposed theoretical strategy reviles a significant influence of valence shell compositions on magnetic properties and stability of molecular magnetism. Within this project, we have also entertained the idea of modeling the magnetic relaxation in these systems with the full complexity of atomic motions.
The dissemination of the SamSD results has been achieved through open access publication research that was presented at the research conference and general workshops. In multiple instances, the novelty and quality of the research were noted by editorials and awarded by the journal front covers.