Real-time observations were made of the shape change from pyramids to domes during the growth of germanium-silicon islands on silicon (001). Small islands are pyramidal in shape, whereas larger islands are dome-shaped. During growth, the transition from pyramids to domes occurs through a series of asymmetric transition states with increasing numbers of highly inclined facets. Postgrowth annealing of pyramids results in a similar shape change process. The transition shapes are temperature dependent and transform reversibly to the final dome shape during cooling. These results are consistent with an anomalous coarsening model for island growth.
We demonstrate that the nucleation sites of nanoscale, self-assembled Ge islands on Si(001) can be controlled by patterning the Si surface in situ with a focused ion beam. At low doses of 6000 Ga+ ions per <100 nm spot, the selective growth is achieved without modifying the initial surface topography. At larger doses, topographic effects produced by sputtering and redeposition control the selective nucleation sites. Islands grown on irradiated spots are smaller with higher aspect ratio than islands grown on clean Si(001), suggesting a strong surfactant effect of Ga.
We investigate the fundamental mechanism by which self-assembled Ge islands can be
nucleated at specific sites on Si(001) using ultra-low-dose focused ion beam (FIB)
pre-patterning. Island nucleation is controlled by a nanotopography that forms after the
implantation of Ga ions during subsequent thermal annealing of the substrate. This
nanotopography evolves during the annealing stage, changing from a nanoscale annular
depression associated with each focused ion beam spot to a nanoscale pit, and eventually
disappearing (planarizing). The correspondence of Ge quantum dot nucleation
sites to the focused ion beam features requires a growth surface upon which the
nanotopography is preserved. A further key observation is that the Ge wetting layer
thickness is reduced in patterned regions, allowing the formation of islands on the
templated regions without nucleation elsewhere. These results provide routes to the
greatly enhanced design and control of quantum dot distributions and dimensions.
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