posted on 2016-09-28, 00:00authored byMikołaj Lewandowski, Irene M. N. Groot, Zhi-Hui Qin, Tomasz Ossowski, Tomasz Pabisiak, Adam Kiejna, Anastassia Pavlovska, Shamil Shaikhutdinov, Hans-Joachim Freund, Ernst Bauer
Polar ionic surfaces with bulk termination
are inherently unstable
because of their diverging electrostatic surface energy. Nevertheless,
they are frequently observed in nature, mainly because of charge neutralization
by adsorbates, but occur also under atomically clean conditions. Several
mechanisms have been invoked to explain the stability of atomically
clean polar surfaces, but the frequently observed periodic nanoscale
pattern formation has not yet been explained. Here we propose that
long-range interactions between alternating electropositive and electronegative
regions of different surface terminations minimize the electrostatic
energy of the surface and thus stabilize the nanoscale pattern. This
is illustrated using the example of polar Fe oxide surfaces by combining
scanning tunneling microscopy and spectroscopy results with results
from density functional theory-based calculations and dipole–dipole
interaction models.