Size dependent light absorption modulation and enhanced carrier transport in germanium quantum dots devices

Quantum confinement in closely packed arrays of Ge quantum dots (QDs) was studied for energy applications. In this work, we report an efficient tuning mechanism of the light harvesting and detection of Ge QDs. Thin films of SiGeO alloys, produced by rf-magnetron sputtering, were annealed at 600°C in...

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Bibliographic Details
Published in:Solar energy materials and solar cells 2015-04, Vol.135, p.22-28
Main Authors: Cosentino, S., Barbagiovanni, E.G., Crupi, I., Miritello, M., Nicotra, G., Spinella, C., Pacifici, D., Mirabella, S., Terrasi, A.
Format: Article
Language:English
Subjects:
Approximation
Devices
Germanium
Harvesting
Light absorption
Photovoltaic cells
Photovoltaics
Quantum confinement
Quantum dots
Solar cells
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Summary:Quantum confinement in closely packed arrays of Ge quantum dots (QDs) was studied for energy applications. In this work, we report an efficient tuning mechanism of the light harvesting and detection of Ge QDs. Thin films of SiGeO alloys, produced by rf-magnetron sputtering, were annealed at 600°C in N2 to induce precipitation of small amorphous Ge QDs into the oxide matrix. Varying the Ge content, the QD size was tailored between 2 and 4nm, as measured by high resolution transmission electron microscopy. X-ray photoelectron spectroscopy (XPS) measurements indicate the formation of pure SiO2, as well as the presence of a sub-stoichiometric Ge oxide shell at the QD interface. Light absorption spectroscopy shows a clear size-dependent shift of the QD optical bandgap (Eg), between 1.4 and 2.1eV, and was modeled using the standard effective mass approximation (EMA) or a spatially dependent effective mass approximation (SPDEM) model. The reported quantum confinement effect was exploited to enhance light harvesting capability in Ge QDs-based devices. Metal–insulator–semiconductor devices with Ge QDs in the insulating layer exhibit a significant photo-response under reverse bias. Whereby, we demonstrate a large photoconductive gain (up to 1500%) that is tunable with QD size and is based on a preferential trapping of photo-generated holes by QDs, which enhances the charge carrier collection. Our results provide a new route for the application of Ge QDs in light harvesting devices and solar cells. •We investigated the light absorption of Ge quantum dots (QDs).•The role of QD size and structural properties on the spectral response was evaluated.•Light harvesters based on Ge QDs exhibit a large photoconductive gain, tunable with QD size.
ISSN:0927-0248
1879-3398
DOI:10.1016/j.solmat.2014.09.012