Motivated by recent transport experiments and proposed atomic-scale semiconductor devices, we present measurements that extend the reach of scanned-probe methods to discern the properties of individual dopants tens of nanometers below the surface of a silicon sample. Using a capacitance-based approach, we have both spatially-resolved individual subsurface boron acceptors and detected spectroscopically single holes entering and leaving these minute systems of atoms. A resonance identified as the B+ state is shown to shift in energy from acceptor to acceptor. We examine this behavior with respect to nearest-neighbor distances. By directly measuring the quantum levels and testing the effect of dopant-dopant interactions, this method represents a valuable tool for the development of future atomic-scale semiconductor devices.
@article{arxiv.0904.2617,
title = {Single-Electron Capacitance Spectroscopy of Individual Dopants in Silicon},
author = {M. Gasseller and R. Loo and J. F. Harrison and M. Caymax and S. Rogge and S. H. Tessmer},
journal= {arXiv preprint arXiv:0904.2617},
year = {2009}
}
Comments
17 pages (main text is 5 pages), 3 figures and 4 supplementary figures