Stability of cationic silver doped gold clusters and the subshell-closed electronic configuration of AgAu₁₄⁺

Silver doping is a valuable route to modulate the structural, electronic, and optical properties of gold clusters. We combine photofragmentation experiments with density functional theory calculations to investigate the relative stability of cationic Ag doped Au clusters, AgAu_{N−1}⁺ (N ≤ 40). The mass spectra of the clusters after photofragmentation reveal marked drops in the intensity of AgAu₈⁺, AgAu₁₄⁺, and AgAu₃₄⁺, indicating a higher relative stability of these sizes. This is confirmed by the calculated AgAu_{N−1}⁺ (N ≤ 17) dissociation energies peaking for AgAu₆⁺, AgAu₈⁺, and AgAu₁₄⁺. While the stability of AgAu₆⁺ and AgAu₈⁺ can be explained by the accepted electronic shell model for metal clusters, density of states analysis shows that the geometry plays an important role in the higher relative stability of AgAu₁₄⁺. For this size, there is a degeneracy lifting of the 1D shell, which opens a relatively large HOMO–LUMO gap with a subshell-closed 1S²1P⁴1P²1D⁶ electronic configuration.

Publication year:2020

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Authors:International

Authors from:Higher Education

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