1 research outputs found
A Generic Hybrid Model for Bulk Elastodynamics, With Application to Ultrasonic Nondestructive Evaluation
Monolayer
two-dimensional transitional metal dichalcogenides, such as MoS<sub>2</sub>, WS<sub>2</sub>, and WSe<sub>2</sub>, are direct band gap
semiconductors with large exciton binding energy. They attract growing
attentions for optoelectronic applications including solar cells,
photodetectors, light-emitting diodes and phototransistors, capacitive
energy storage, photodynamic cancer therapy, and sensing on flexible
platforms. While light-induced luminescence has been widely studied,
luminescence induced by injection of free electrons could promise
another important applications of these new materials. However, cathodoluminescence
is inefficient due to the low cross-section of the electron–hole
creating process in the monolayers. Here for the first time we show
that cathodoluminescence of monolayer chalcogenide semiconductors
can be evidently observed in a van der Waals heterostructure when
the monolayer semiconductor is sandwiched between layers of hexagonal
boron nitride (hBN) with higher energy gap. The emission intensity
shows a strong dependence on the thicknesses of surrounding layers
and the enhancement factor is more than 500-fold. Strain-induced exciton
peak shift in the suspended heterostructure is also investigated by
the cathodoluminescence spectroscopy. Our results demonstrate that
MoS<sub>2</sub>, WS<sub>2</sub>, and WSe<sub>2</sub> could be promising
cathodoluminescent materials for applications in single-photon emitters,
high-energy particle detectors, transmission electron microscope displays,
surface-conduction electron-emitter, and field emission display technologies