Jin Chan Wang , Lan Hui Huang , Hai Jun Hou , Miao Cao , Yan Xi , Miao Miao Li , Ya Ru Zhao
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引用次数: 0
Abstract
Bimetallic clusters have garnered heightened attention due to their capacity to adjust their intrinsic properties by modifying size, structure, and doping. In this study, we perform a structural search to identify the global minimum of the Rb2Mgn (n = 1–12) clusters using the CALYPSO code for structural predicting, followed by DFT optimization. The geometric, electronic and spectral behaviors that vary with size are discussed in depth. Our findings indicate a transition in structure from planar to 3D frameworks at n = 3, then to hollow cage-like structure at n = 8 for Rb2Mgn clusters, which happens slightly later than pure magnesium clusters. The convex site is where the Rb atom likes to localize in their structures. Charge transfer studies reveal the electron-loss behavior of Rb along with the presence of sp hybridization in the clusters. Analysis of stability suggests that the Rb2Mg3 and Rb2Mg9 clusters exhibit greater stability, which is attributed to their closed-shell electronic configurations such as 1S21P6 and 1S21P61D102S2. A study of the bonding characteristic not only reveals the delocalization of the bond, but also indicates the stronger Rb–Mg bond than the Mg–Mg bond in Rb2Mg3 and Rb2Mg9. The spectral characteristics, as determined from IR and Raman spectroscopy, have also been examined.
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