Probing the Magic Numbers of Aluminum-Magnesium Cluster Anions and Their Reactivity toward Oxygen

摘要

We report a joint experimental and theoretical investigation into the geometry, stability, and reactivity with oxygen of alloy metal clusters Al_nMg_m~- (4 ≤ n+m ≤ 15; 0 ≤ m ≤ 3). Considering that Al and Mg possess three and two valence electrons, respectively, clusters with all possible valence electron counts from 11 to 46 are studied to probe the magic numbers predicted by the spherical jellium model, and to determine whether enhanced stability and reduced reactivity may be found for some Al_nMg_m~- at non-magic numbers. Al_5Mg_2~- and Al_(11)Mg_3~- exhibit enhanced stability corresponding to the expected magic numbers of 20 and 40 electrons, respectively; while Al_7Mg_3~-, Al_(11)Mg~-, and Al_(11)Mg_2~- turn out to be unexpectedly stable at electron counts of 28, 36, and 38, respectively. The enhanced stability at non-magic numbers is explained through a crystal-field-like splitting of degenerate shells by the geometrical distortions of the clusters. Al_nMg_m~- clusters appear to display higher oxidation than pure Al_n~- clusters, suggesting that the addition of Mg atoms enhances the combustion of pure aluminum clusters.