posted on 2018-05-25, 00:00authored byFabian Schulz, Juha Ritala, Ondrej Krejčí, Ari Paavo Seitsonen, Adam S. Foster, Peter Liljeroth
There
are currently no experimental techniques that combine atomic-resolution
imaging with elemental sensitivity and chemical fingerprinting on
single molecules. The advent of using molecular-modified tips in noncontact
atomic force microscopy (nc-AFM) has made it possible to image (planar)
molecules with atomic resolution. However, the mechanisms responsible
for elemental contrast with passivated tips are not fully understood.
Here, we investigate elemental contrast by carrying out both nc-AFM
and Kelvin probe force microscopy (KPFM) experiments on epitaxial
monolayer hexagonal boron nitride (hBN) on Ir(111). The hBN overlayer
is inert, and the in-plane bonds connecting nearest-neighbor boron
and nitrogen atoms possess strong covalent character and a bond length
of only ∼1.45 Å. Nevertheless, constant-height maps of
both the frequency shift Δf and the local contact
potential difference exhibit striking sublattice asymmetry. We match
the different atomic sites with the observed contrast by comparison
with nc-AFM image simulations based on the density functional theory
optimized hBN/Ir(111) geometry, which yields detailed information
on the origin of the atomic-scale contrast.