Spin–Orbit Coupling Effects on Ligand-Free Icosahedral Matryoshka Superatoms

Long, Feiyun; Liu, Haitao; Li, Dafang; Yan, Jun

doi:10.1021/acs.jpca.6b12186

Cited by 6 publications

(1 citation statement)

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“…Therefore, this unique magnetic icosahedral Matryoshka cluster with huge magnetic moment is a promising building block for the spin-filtering device in molecular spintronics. The SOC effects in the icosahedral Matryoshka clusters, E@M 12 @E 20 (E = Ge, M = Zn; E = Sn, M = Mg, Mn, Zn, Cd; E = Pb, M = Mg, Mn, Cd, Hg) have been systematically investigated by Long et al 858 using the PAW potentials with a SOC term added to the scalar relativistic DFT Hamiltonian. For the Matryoshka superatoms containing heavy elements like Pb, SOC was found to play a substantial role in reducing the atomization energy and the HOMO−LUMO gap to a certain extent.…”

Section: Multilayer Matryoshka Cages and Core-shell Structuresmentioning

confidence: 99%

Endohedrally Doped Cage Clusters

2020

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The discovery of carbon fullerene cages and their solids opened a new avenue to build materials from stable cage clusters as “artificial atoms” or “superatoms” instead of atoms. However, cage clusters of other elements are generally not stable. In 2001, ab initio calculations showed that endohedral doping of Zr and Ti atoms leads to highly stable Zr@Si16 fullerene and Ti@Si16 Frank–Kasper polyhedral clusters with large HOMO–LUMO gaps. In 2002, Zr@Ge16 was shown to form a Frank–Kasper polyhedron, suggesting the possibility of designing novel clusters by tuning endohedral and cage atoms. These results were subsequently confirmed from experiments. In the past nearly two decades, many experimental and theoretical studies have been carried out on different clusters, and many very stable cage clusters with possibly high abundance have been found by endohedral doping. Indeed in 2017, Ta@Si16 and Ti@Si16 cage clusters have been synthesized in bulk quantity of about 100 mg using a dry-chemistry method, giving rise to a new hope of developing cluster-based materials in macroscopic quantity besides the well-known C60 fullerene solid. Also, wet-chemistry methods have been used to synthesize endohedrally doped clusters as well as ligated clusters and their solids, which auger well for the development of novel nanostructured materials using atomically precise clusters with unique properties. In this comprehensive review, we present results of many such developments in this fast-growing field including (i) endohedrally doped Al, Ga, and In clusters, (ii) small endohedral carbon fullerene cages with ≤ 28 carbon atoms, (iii) metal doped boron cages, (iv) endohedrally doped cages of group 14 elements (Si, Ge, Sn, and Pb), (v) coinage metal (Cu, Ag, Au) cages doped with a transition metal atom as well as their ligated clusters and crystals, (vi) endohedrally doped cages of compound semiconductors, and (vii) multilayer Matryoshka cages and core–shell structures. In a large number of cases, we have performed ab initio calculations to present updated results of the most stable atomic structures and fundamental electronic properties of the endohedrally doped cage clusters. We discuss electronic, magnetic, optical, and catalytic properties in order to shed light on their potential applications. The stability of the doped cage clusters has been correlated to the concept of filling the electronic shells for superatoms such as within a spherical potential model and also using various electron counting rules including Wade–Mingos rules, systems with 18 and 32 electrons, and the spherical aromaticity rule. We also discuss cluster–cluster interaction in cluster dimers and assemblies of some of the promising doped cage clusters in different dimensions. Finally, we give a perspective of this field with a bright future.

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Section: Multilayer Matryoshka Cages and Core-shell Structuresmentioning

confidence: 99%