Abstract
Here, we demonstrate a bias-driven superluminescent point light-source based on an optically pumped molecular junction (gold substrate/self-assembled molecular monolayer/gold tip) of a scanning tunneling microscope, operating at ambient conditions and providing almost three orders of magnitude higher electron-to-photon conversion efficiency than electroluminescence induced by inelastic tunneling without optical pumping. A positive, steadily increasing bias voltage induces a step-like rise of the Stokes shifted optical signal emitted from the junction. This emission is strongly attenuated by reversing the applied bias voltage. At high bias voltage, the emission intensity depends non-linearly on the optical pump power. The enhanced emission can be modelled by rate equations taking into account hole injection from the tip (anode) into the highest occupied orbital of the closest substrate-bound molecule (lower level) and radiative recombination with an electron from above the Fermi level (upper level), hence feeding photons back by stimulated emission resonant with the gap mode. The system reflects many essential features of a superluminescent light emitting diode.
Highlights
The emission of photons from the gap of a scanning tunneling microscope (STM) has been a focus of interest for more than twenty years [1,2] and has been used for acquiring spectroscopic information with ultra-high spatial resolution [3]
We demonstrate a bias-driven superluminescent point light-source based on an optically pumped molecular junction of a scanning tunneling microscope, operating at ambient conditions and providing almost three orders of magnitude higher electron-to-photon conversion efficiency than electroluminescence induced by inelastic tunneling without optical pumping
When a positive bias voltage is applied at the tunneling junction and steadily increased while the tunneling current of 1 nA is kept constant, the negatively charged part of the molecules experiences an increasing attractive force towards the positively charged tip
Summary
The emission of photons from the gap of a scanning tunneling microscope (STM) has been a focus of interest for more than twenty years [1,2] and has been used for acquiring spectroscopic information with ultra-high spatial resolution [3]. The enhanced emission can be modelled by rate equations taking into account hole injection from the tip (anode) into the highest occupied orbital of the closest substrate-bound molecule (lower level) and radiative recombination with an electron from above the Fermi level (upper level), feeding photons back by stimulated emission resonant with the gap mode.
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