Hot-Carrier-Mediated Photon Upconversion in Metal-Decorated Quantum Wells

Manipulating the frequency of electromagnetic waves forms the core of many modern technologies, ranging from imaging and spectroscopy to radio and optical communication. The process of converting photons from higher to lower energy is easily accomplished and technologically widespread. However, upco...

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Bibliographic Details
Published in:Nano letters 2017-08, Vol.17 (8), p.4583-4587
Main Authors: Naik, Gururaj V, Welch, Alex J, Briggs, Justin A, Solomon, Michelle L, Dionne, Jennifer A
Format: Article
Language:English
Subjects:
electrodes - solar
materials and chemistry by design
NANOSCIENCE AND NANOTECHNOLOGY
optics
phonons
RADIATION CHEMISTRY, RADIOCHEMISTRY, AND NUCLEAR CHEMISTRY
solar (photovoltaic)
SOLAR ENERGY
solid state lighting
synthesis (novel materials)
synthesis (self-assembly)
thermal conductivity
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Summary:Manipulating the frequency of electromagnetic waves forms the core of many modern technologies, ranging from imaging and spectroscopy to radio and optical communication. The process of converting photons from higher to lower energy is easily accomplished and technologically widespread. However, upconversion, which is the process of converting lower-energy photons into higher-energy photons, is still a growing field of study with nascent applications and burgeoning interest. Here, we experimentally demonstrate a new photon upconversion technique mediated by hot carriers in plasmonic nanostructures. Hot holes and hot electrons generated via plasmon decay in illuminated metal nanoparticles are injected into an adjacent semiconductor quantum well where they radiatively recombine to emit higher-energy photons. Using GaN/InGaN quantum wells decorated with gold and silver nanoparticles, we show photon upconversion from 2.4 to 2.8 eV. The process scales linearly with illumination power and enables both geometry- and polarization-based tunability. The conversion of plasmonic losses into upconverted optical emission has the potential to impact bioimaging, on-chip wavelength conversion, and high-efficiency photovoltaics.
ISSN:1530-6984
1530-6992
DOI:10.1021/acs.nanolett.7b00900