Interactions between atomic and molecular objects are to a large extent defined by the nanoscale electrostatic potentials which these objects produce. We introduce a scanning probe technique that enables three-dimensional imaging of local electrostatic potential fields with sub-nanometer resolution. Registering single electron charging events of a molecular quantum dot attached to the tip of a (qPlus tuning fork) atomic force microscope operated at 5 K, we quantitatively measure the quadrupole field of a single molecule and the dipole field of a single metal adatom, both adsorbed on a clean metal surface. Because of its high sensitivity, the technique can record electrostatic potentials at large distances from their sources, which above all will help to image complex samples with increased surface roughness.
@article{arxiv.1503.07738,
title = {Scanning Quantum Dot Microscopy},
author = {Christian Wagner and Matthew F. B. Green and Phillipp Leinen and Thorsten Deilmann and Peter Krüger and Michael Rohlfing and Ruslan Temirov and F. Stefan Tautz},
journal= {arXiv preprint arXiv:1503.07738},
year = {2015}
}
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main text: 5 pages, 4 figures, supplementary information file: 4 pages, 2 figures