Abstract
Polyhedra are ubiquitous in chemistry, biology, mathematics and other disciplines. Coordination-driven self-assembly has created molecules mimicking Platonic, Archimedean and even Goldberg polyhedra, however, nesting multiple polyhedra in one cluster is challenging, not only for synthesis but also for determining the alignment of the polyhedra. Here, we synthesize a nested Ag(90) nanocluster under solvothermal condition. This pseudo-T(h) symmetric Ag(90) ball contains three concentric Ag polyhedra with apparently incompatible symmetry. Specifically, the inner (Ag(6)) and middle (Ag(24)) shells are octahedral (O(h)), an octahedron (a Platonic solid with six 3.3.3.3 vertices) and a truncated octahedron (an Archimedean solid with twenty-four 4.6.6 vertices), whereas the outer (Ag(60)) shell is icosahedral (I(h)), a rhombicosidodecahedron (an Archimedean solid with sixty 3.4.5.4 vertices). The Ag(90) nanocluster solves the apparent incompatibility with the most symmetric arrangement of 2- and 3-fold rotational axes, similar to the arrangement in the model called Kepler's Kosmos, devised by the mathematician John Conway.