posted on 2023-11-08, 19:10authored byQiucheng Li, Luqing Wang, Hui Li, Maria K. Y. Chan, Mark C. Hersam
Borophene
nanoribbons (BNRs) are one-dimensional strips of atomically
thin boron expected to exhibit quantum-confined electronic properties
that are not present in extended two-dimensional borophene. While
the parent material borophene has been experimentally shown to possess
anisotropic metallicity and diverse polymorphic structures, the atomically
precise synthesis of nanometer-wide BNRs has not yet been achieved.
Here, we demonstrate the synthesis of multiple BNR polymorphs with
well-defined edge configurations within the nanometer-scale terraces
of vicinal Ag(977). Through atomic-scale imaging, spectroscopy, and
first-principles calculations, the synthesized BNR polymorphs are
characterized and found to possess distinct edge structures and electronic
properties. For single-phase BNRs, v1/6-BNRs and v1/5-BNRs adopt reconstructed
armchair edges and sawtooth edges, respectively. In addition, the
electronic properties of single-phase v1/6-BNRs and v1/5-BNRs are dominated by
Friedel oscillations and striped moiré patterns, respectively.
On the other hand, mixed-phase BNRs possess quantum-confined states
with increasing nodes in the electronic density of states at elevated
biases. Overall, the high degree of polymorphism and diverse edge
topologies in borophene nanoribbons provide a rich quantum platform
for studying one-dimensional electronic states.