Octagold selenido nanoclusters: Significance of surface ligands on tuning geometric and electronic structure of Au8Se2 kernel

Two diphosphine-protected superatom gold selenido nanoclusters, [Au8Se2(dppm)(4)](2+) (SD/Au8a, dppm = Ph2PCH2PPh2) and [Au8Se2(dppe)(4)](2+) (SD/Au8b, dppe = Ph2P(CH2)2PPh2), were obtained by the reduction of [Au(SMe2)Cl] in the presence of Ph3PSe as the selenium ion releasing agents. Both can be regarded as superatoms with 1S(2) configuration based on the spherical Jellium model. Despite the same metal ligand binding motifs on the surface and the intrinsic C-2 molecular symmetry, the configurations of Au8Se2 kernels in them are different in terms of Au Au bonded metallic frameworks. SD/Au8a displays a heart-shaped [core + exo] type structure (Au-4 tetrahedron core + two exo Au2Se units), whereas the two exo Au2Se counterparts in SD/Au8b are additionally locked by an obvious Au Au bond, forming a distorted hexagonal Au-6 ring with two capping AuSe units appended above and below it. Consequently, they showed different photophysical properties as reflected by their electronic absorption and emission spectra. Especially, both SD/Au8a and SD/Au8b exhibit blue-shifted thermochromic luminescence upon cooling from 293 to 83 K but the latter exhibits anomalous emission intensity evolution trends due to the occurrence of temperature-induced phase transition as revealed by varied-temperature crystallographic analyses. This work not only clearly illustrates the significance of ligands on tuning the kernel structure but also provides two rarely comparable examples for better understanding of the structure property relationship of gold nanoclusters.

Automated summary

Two diphosphine-protected superatom gold selenido nanoclusters were synthesized and compared in terms of their structures and photophysical properties, highlighting the significance of ligands in tuning the kernel structure.