Litcius/Paper detail

Two-Dimensional Artificial Ge Superlattice Confining in Electronic Kagome Lattice Potential Valleys

Qiwei Tian, Sahar Izadi Vishkayi, Meysam Bagheri Tagani, Li Zhang, Li Zhang, Yuan Tian, Long‐Jing Yin, Lijie Zhang, Lijie Zhang, Zhihui Qin

2023Nano Letters11 citationsDOI

Abstract

Constructing two-dimensional (2D) artificial superlattices based on single-atom and few-atom nanoclusters is of great interest for exploring exotic physics. Here we report the realization of two types of artificial germanium (Ge) superlattice self-confined by a 37 × 37 R25.3° superstructure of bismuth (Bi) induced electronic kagome lattice potential valleys. Scanning tunneling microscopy measurements demonstrate that Ge atoms prefer to be confined in the center of the Bi electronic kagome lattice, forming a single-atom superlattice at 120 K. In contrast, room temperature grown Ge atoms and clusters are confined in the sharing triangle corner and the center, respectively, of the kagome lattice potential valleys, forming an artificial honeycomb superlattice. First-principle calculations and Mulliken population analysis corroborate that our reported atomically thin Bi superstructure on Au(111) has a kagome surface potential valley with the center of the inner Bi hexagon and the space between the outer Bi hexagons being energetically favorable for trapping Ge atoms.

Topics & Concepts

SuperlatticeCondensed matter physicsLattice (music)Scanning tunneling microscopeMaterials scienceBismuthElectronic structureNanoclustersAtom (system on chip)PopulationNanotechnologyPhysicsSociologyDemographyAcousticsEmbedded systemComputer scienceMetallurgyTopological Materials and PhenomenaGraphene research and applicationsAdvanced Chemical Physics Studies