posted on 2021-08-19, 20:40authored byKenan Elibol, Clemens Mangler, David D. O’Regan, Kimmo Mustonen, Dominik Eder, Jannik C. Meyer, Jani Kotakoski, Richard G. Hobbs, Toma Susi, Bernhard C. Bayer
Single atoms and
few-atom nanoclusters are of high interest in
catalysis and plasmonics, but pathways for their fabrication and placement
remain scarce. We report here the self-assembly of room-temperature-stable
single indium (In) atoms and few-atom In clusters (2–6 atoms)
that are anchored to substitutional silicon (Si) impurity atoms in
suspended monolayer graphene membranes. Using atomically resolved
scanning transmission electron microscopy (STEM), we find that the
symmetry of the In structures is critically determined by the three-
or fourfold coordination of the Si “anchors”. All structures
are produced without electron-beam induced materials modification.
In turn, when activated by electron beam irradiation in the STEM,
we observe in situ the formation, restructuring,
and translation of the Si-anchored In structures. Our results on In–Si-graphene
provide a materials system for controlled self-assembly and heteroatomic
anchoring of single atoms and few-atom nanoclusters on graphene.