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Abstract
For future nanoelectronic devices – such as room-temperature single electron transistors – the site-controlled formation of single Si nanocrystals (NCs) is a crucial prerequisite. Here, we report an approach to fabricate single Si NCs via medium-energy Si+ or Ne+ ion beam mixing of Si into a buried SiO2 layer followed by thermally activated phase separation. Binary collision approximation and kinetic Monte Carlo methods are conducted to gain atomistic insight into the influence of relevant experimental parameters on the Si NC formation process. Energy-filtered transmission electron microscopy is performed to obtain quantitative values on the Si NC size and distribution in dependence of the layer stack geometry, ion fluence and thermal budget. Employing a focused Ne+ beam from a helium ion microscope, we demonstrate site-controlled self-assembly of single Si NCs. Line irradiation with a fluence of 3000 Ne+/nm2 and a line width of 4 nm leads to the formation of a chain of Si NCs, and a single NC with 2.2 nm diameter is subsequently isolated and visualized in a few nanometer thin lamella prepared by a focused ion beam (FIB). The Si NC is centered between the SiO2 layers and perpendicular to the incident Ne+ beam.
Highlights
Silicon has been the main material in the semiconductor industry for almost all use cases with the exception of optical applications
The simulations show that after ion beam mixing with 100 Si+ nm−2 at 50 keV only a small change in stoichiometry is expected for the center of the thick oxide layer
We have demonstrated a novel method for the site-controlled formation of single Si NCs in a buried SiO2 layer using ion beam mixing
Summary
Silicon has been the main material in the semiconductor industry for almost all use cases with the exception of optical applications. First the formation of a Si NC δ-layer in Si/SiO2/Si stacks by broad-beam Si+ irradiation is studied for different buried oxide thicknesses.
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