Abstract
Noncontact atomic force microscopy (NC-AFM) is now routinely capable of obtaining submolecular resolution, readily resolving the carbon backbone structure of planar organic molecules adsorbed on metal substrates. Here we show that the same resolution may also be obtained for molecules adsorbed on a reactive semiconducting substrate. Surprisingly, this resolution is routinely obtained without the need for deliberate tip functionalization. Intriguingly, we observe two chemically distinct apex types capable of submolecular imaging. We characterize our tip apices by ``inverse imaging'' of the silicon adatoms of the $\mathrm{Si}(111)\phantom{\rule{0.16em}{0ex}}\ensuremath{-}7\ifmmode\times\else\texttimes\fi{}7$ surface and support our findings with detailed density functional theory (DFT) calculations. We also show that intramolecular resolution on individual molecules may be readily obtained at 78 K, rather than solely at 5 K as previously demonstrated. Our results suggest a wide range of tips may be capable of producing intramolecular contrast for molecules adsorbed on semiconductor surfaces, leading to a much broader applicability for submolecular imaging protocols.
Highlights
Since Gross et al [1] first demonstrated striking submolecular resolution in Noncontact atomic force microscopy (NC-AFM) using CO-functionalized tips on the Cu(111) surface, the ability to image the detailed substructure of molecules adsorbed on metal surfaces has produced a number of impressive results
This is in addition to the scanning tunneling hydrogen microscopy (STHM) technique pioneered by Tautz and Temirov [10,11], which demonstrated similar submolecular and intermolecular contrast
We find that submolecular resolution is routinely achieved when imaging a simple prototypical planar organic molecule [naphthalene tetracarboxylic diimide (NTCDI)] on the
Summary
Since Gross et al [1] first demonstrated striking submolecular resolution in NC-AFM using CO-functionalized tips on the Cu(111) surface, the ability to image the detailed substructure of molecules adsorbed on metal surfaces has produced a number of impressive results. In addition to further developments by Gross and co-workers related to the bond order of organic molecules [2], localization of charge within a molecule [3], and the suitability of different types of tip apex termination [4], other groups have used a similar protocol to image the stages of a chemical reaction [5], different conformations of an adsorbed molecule [6], and, very recently, intermolecular contrast in regions where hydrogen bonding is expected [7,8,9] This is in addition to the scanning tunneling hydrogen microscopy (STHM) technique pioneered by Tautz and Temirov [10,11], which demonstrated similar submolecular and intermolecular contrast.
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