Abstract
The luminescent and magnetic properties of trivalent lanthanides (Ln(3+)) are indispensable for many emerging technologies, but exacting fine control over these properties requires an understanding of how to purposefully engineer the coordination geometry and site symmetry of Ln(3+) centres. Here, we use the Cambridge Structural Database to extract the structures of 12,670 eight-coordinate Ln(3+) centres and use Continuous Shape Measures, Continuous Symmetry Operation Measures, and a new structural similarity-based network analysis to survey geometry and structure trends. This survey is then leveraged to deliver concrete strategies for controlling the coordination geometry of eight-coordinate Ln(3+) centres using familiar concepts like Ln(3+) metal size and ligand denticity, bite angle, flexibility, shape, symmetry, and size. Ultimately, we present a roadmap for targeting each of the six common eight-coordinate geometries - hexagonal bipyramidal, cubic, square antiprismatic, dodecahedral, bicapped trigonal prismatic, and snub disphenoid - which are each demonstrated to have unique use-cases in diverse research areas. The effects of crystal packing and non-covalent interactions are also illustrated, allowing fine-grained control over the geometry and symmetry of Ln(3+) centres. This work ultimately serves to inform the deliberate design of Ln(3+) coordination complexes and materials for applications including data-storage, quantum information processing, lighting, thermometry, and medical bioimaging.