Abstract
The appearance of ``magic'' heights of Pb islands grown on Cu(111) is studied by self-consistent electronic structure calculations. The Cu(111) substrate is modeled with a one-dimensional pseudopotential reproducing the essential features, i.e., the band gap and the work function, of the Cu band structure in the [111] direction. Pb islands are presented as stabilized jellium overlayers. The experimental eigenenergies of the quantum-well states confined in the Pb overlayer are well reproduced. The total energy oscillates as a continuous function of the overlayer thickness reflecting the electronic shell structure. The energies for completed Pb monolayers show a modulated oscillatory pattern reminiscent of the supershell structure of clusters and nanowires. The energy minima correlate remarkably well with the measured most probable heights of Pb islands. The proper modeling of the substrate is crucial to set the quantitative agreement.
Highlights
The confinement of valence electron states in lowdimensional systems has a strong influence on the size distributions of nanostructures produced in experiments
The Cu111͒ substrate is modeled with a one-dimensional pseudopotential reproducing the essential features, i.e., the band gap and the work function, of the Cu band structure in the111͔ direction
The vertical confinement in the Pb overlayer is due to the potential barrier between Pb and the vacuum and the energy gap in the projection of the Cu bulk bands in the111͔ direction
Summary
The confinement of valence electron states in lowdimensional systems has a strong influence on the size distributions of nanostructures produced in experiments. The appearance of ‘‘magic’’ heights of Pb islands grown on Cu111͒ is studied by self-consistent electronic structure calculations. The Cu111͒ substrate is modeled with a one-dimensional pseudopotential reproducing the essential features, i.e., the band gap and the work function, of the Cu band structure in the111͔ direction.
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