Palladium
diselenide (PdSe2), a peculiar noble metal
dichalcogenide, has emerged as a new two-dimensional material with
high predicted carrier mobility and a widely tunable band gap for
device applications. The inherent in-plane anisotropy endowed by the
pentagonal structure further renders PdSe2 promising for
novel electronic, photonic, and thermoelectric applications. However,
the direct synthesis of few-layer PdSe2 is still challenging
and rarely reported. Here, we demonstrate that few-layer, single-crystal
PdSe2 flakes can be synthesized at a relatively low growth
temperature (300 °C) on sapphire substrates using low-pressure
chemical vapor deposition (CVD). The well-defined rectangular domain
shape and precisely determined layer number of the CVD-grown PdSe2 enable us to investigate their layer-dependent and in-plane
anisotropic properties. The experimentally determined layer-dependent
band gap shrinkage combined with first-principle calculations suggest
that the interlayer interaction is weaker in few-layer PdSe2 in comparison with that in bulk crystals. Field-effect transistors
based on the CVD-grown PdSe2 also show performances comparable
to those based on exfoliated samples. The low-temperature synthesis
method reported here provides a feasible approach to fabricate high-quality
few-layer PdSe2 for device applications.
Monolayer transition metal dichalcogenides offer an appropriate
platform for developing advanced electronics beyond graphene. Similar
to two-dimensional molecular frameworks, the electronic properties
of such monolayers can be sensitive to perturbations from the surroundings;
the implied tunability of electronic structure is of great interest.
Using scanning tunneling microscopy/spectroscopy, we demonstrated
a bandgap engineering technique in two monolayer materials, MoS2 and PtTe2, with the tunneling current as a control
parameter. The bandgap of monolayer MoS2 decreases logarithmically
by the increasing tunneling current, indicating an electric-field-induced
gap renormalization effect. Monolayer PtTe2, by contrast,
exhibits a much stronger gap reduction, and a reversible semiconductor-to-metal
transition occurs at a moderate tunneling current. This unusual switching
behavior of monolayer PtTe2, not seen in bulk semimetallic
PtTe2, can be attributed to its surface electronic structure
that can readily couple to the tunneling tip, as demonstrated by theoretical
calculations.
Plumbene, with a structure similar to graphene, is expected to possess a strong spin-orbit coupling and thus enhances its superconducting critical temperature (T c ). In this work, a buckled plumbene-Au Kagome superstructure grown by depositing Au on Pb(111) is investigated. The superconducting gap monitored by temperature-dependent scanning tunneling microscopy/spectroscopy shows that the buckled plumbene-Au Kagome superstructure not only has an enhanced T c with respect to that of a monolayer Pb but also possesses a higher value than what owned by a bulk Pb substrate. By combining angle-resolved photoemission spectroscopy with density functional theory, the monolayer Au-intercalated low-buckled plumbene sandwiched between the top Au Kagome layer and the bottom Pb(111) substrate is confirmed and the electron-phonon coupling-enhanced superconductivity is revealed. This work demonstrates that a buckled plumbene-Au Kagome superstructure can enhance superconducting T c and Rashba effect, effectively triggering the novel properties of a plumbene.
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