Abstract
The structural growth of Gd-doped germanium anionic nanoclusters, GdGe (n) (-) (n = 5-18), has been explored via quantum chemistry calculations using the mPW2PLYP method and an unprejudiced structural searching technique known as ABCluster. The optimized geometries exhibited that when n = 10-14, the structural evolution favors the Gd-linked configuration where the Gd atom as a connector bridges two Ge subgroups, while the Gd atom is encapsulated in a closed cage-like Ge frame when n = 15-18. The properties like magnetic moment, charge transfer, relative stability, HOMO-LUMO gap, photoelectron spectra, and infrared and Raman spectra have been predicted. The information of these spectra could provide extra approaches to experimentally determine the electronic structures and equilibrium configuration of these compounds. The largest spin magnetic moment of 7 μ (B) is attained via half-filled 4f states. The GdGe(16) (-) nanocluster is determined to be a superatom because its total valence of 75 electrons can be distributed to the orbital sequence of 1S(2)1P(6)(4f(7))1D(10)1F(14)2S(2)2P(2)1G(18)2P(4)2D(10), which complies with not only Hund's rule, but also the spherical jellium model. Particularly, its UV-Vis spectra match well with solar energy distribution. Such materials act as nano multifunctional building units potentially used in solar energy converters or ultra-highly sensitive near-infrared photodetectors.