Atomically resolved electroluminescence from individual vacancy defects in molybdenum disulfide
Resolving light-matter interaction in crystalline solids at the nano-or even atomic scale can give unprecedented insight into fundamental quasiparticle excitations. Yet many optoelectronic processes occur at length scales far below the diffraction limit of light (≈ 100 nm) making them inaccessibl...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/178447 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Resolving light-matter interaction in crystalline solids at the nano-or even atomic scale
can give unprecedented insight into fundamental quasiparticle excitations.
Yet many optoelectronic processes occur at length scales far below the diffraction
limit of light (≈ 100 nm) making them inaccessible to conventional optical spectroscopy
at an individual level. Examples are atomically confined excitons, bound
to atomic defects or color centers, as well as short-wavelength plasmonic processes
in 2D semimetals such as graphene. Combining scanning tunnelling microscopy
(STM) with optical spectroscopy can provide access to optoelectronic processes
with the true atomic resolution. Here, we demonstrate a setup developed to collect
light emission from a STM tunnel junction. We show that exciting individual sulfur
vacancies in MoS2 with an atomically precise single-charge tunneling current
from an STM tip gives rise to highly localized, to within 1 nm, electroluminescence
with single-photon character and reflecting orbital structure of the defect’s wavefunction.
The single photon character is reflected in a saturation in the photon
emission rate as a function of excitation current and is well described by a two-state
rate equation model. At high bias, each tunneling electron can yield more
than one photon, as evidenced by super-bunching in photon correlation measurements.
We believe that our results have relevance towards realizing electrically
excited on-demand quantum emission using single atomic defects. |
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