The spectrum of two-dimensional (2D) and layered materials 'beyond graphene' offers a remarkable platform to study new phenomena in condensed matter physics. Among these materials, layered hexagonal boron nitride (hBN), with its wide bandgap energy (∼5.0-6.0 eV), has clearly established that 2D nitrides are key to advancing 2D devices. A gap, however, remains between the theoretical prediction of 2D nitrides 'beyond hBN' and experimental realization of such structures. Here we demonstrate the synthesis of 2D gallium nitride (GaN) via a migration-enhanced encapsulated growth (MEEG) technique utilizing epitaxial graphene. We theoretically predict and experimentally validate that the atomic structure of 2D GaN grown via MEEG is notably different from reported theory. Moreover, we establish that graphene plays a critical role in stabilizing the direct-bandgap (nearly 5.0 eV), 2D buckled structure. Our results provide a foundation for discovery and stabilization of 2D nitrides that are difficult to prepare via traditional synthesis.
Atomically thin two-dimensional
(2D) materials face significant
energy barriers for synthesis and processing into functional metastable
phases such as Janus structures. Here, the controllable implantation
of hyperthermal species from pulsed laser deposition (PLD) plasmas
is introduced as a top-down method to compositionally engineer 2D
monolayers. The kinetic energies of Se clusters impinging on suspended
monolayer WS2 crystals were controlled in the <10 eV/atom
range with in situ plasma diagnostics to determine
the thresholds for selective top layer replacement of sulfur by selenium
for the formation of high quality WSSe Janus monolayers at low (300
°C) temperatures and bottom layer replacement for complete conversion
to WSe2. Atomic-resolution electron microscopy and spectroscopy
in tilted geometry confirm the WSSe Janus monolayer. Molecular dynamics
simulations reveal that Se clusters implant to form disordered metastable
alloy regions, which then recrystallize to form highly ordered structures,
demonstrating low-energy implantation by PLD for the synthesis of
2D Janus layers and alloys of variable composition.
We report here details of steady-state and time-resolved spectroscopy of excitonic dynamics for Janus transition metal dichalcogenide monolayers, including MoSSe and WSSe, which were synthesized by low-energy implantation of Se into transition metal disulfides. Absorbance and photoluminescence spectroscopic measurements determined the room-temperature exciton resonances for MoSSe and WSSe monolayers. Transient absorption measurements revealed that the excitons in Janus structures form faster than those in pristine transition metal dichalcogenides by about 30% due to their enhanced electron−phonon interaction by the built-in dipole moment. By combining steady-state photoluminescence quantum yield and time-resolved transient absorption measurements, we find that the exciton radiative recombination lifetime in Janus structures is significantly longer than in their pristine samples, supporting the predicted spatial separation of the electron and hole wave functions due to the built-in dipole moment. These results provide fundamental insight in the optical properties of Janus transition metal dichalcogenides.
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