posted on 2021-10-26, 17:51authored byZhehao Ge, Dillon Wong, Juwon Lee, Frederic Joucken, Eberth A. Quezada-Lopez, Salman Kahn, Hsin-Zon Tsai, Takashi Taniguchi, Kenji Watanabe, Feng Wang, Alex Zettl, Michael F. Crommie, Jairo Velasco
Experimental
realizations of graphene-based stadium-shaped quantum
dots (QDs) have been few and have been incompatible with scanned probe
microscopy. Yet, the direct visualization of electronic states within
these QDs is crucial for determining the existence of quantum chaos
in these systems. We report the fabrication and characterization of
electrostatically defined stadium-shaped QDs in heterostructure devices
composed of monolayer graphene (MLG) and bilayer graphene (BLG). To
realize a stadium-shaped QD, we utilized the tip of a scanning tunneling
microscope to charge defects in a supporting hexagonal boron nitride
flake. The stadium states visualized are consistent with tight-binding-based
simulations but lack clear quantum chaos signatures. The absence of
quantum chaos features in MLG-based stadium QDs is attributed to the
leaky nature of the confinement potential due to Klein tunneling.
In contrast, for BLG-based stadium QDs (which have stronger confinement)
quantum chaos is precluded by the smooth confinement potential which
reduces interference and mixing between states.