Light Emission from Direct Bandgap Hexagonal Silicon Germanium
ORAL
Abstract
Efficient light emission from Si and Ge has been a holy grail due to their indirect bandgap nature. Recently, Ge- rich alloys, with a hexagonal structure have been theoretically predicted to exhibit a direct band gap nature. Density functional theory (DFT) calculations predict a 0.3 eV bandgap for hex- Ge, which can be tuned up to 0.9 eV by alloying with Si1. Yet, the fundamental bottleneck is that Ge and its alloys crystallize naturally in the cubic structure which is optically inactive due to its indirect bandgap nature.
We have realized hex- SiGe by utilizing wurtzite GaAs nanowire cores as a template to transfer the crystal structure to the SiGe shells in a core-shell geometry2. We demonstrate photoluminescence of hex-Ge at 3.5 µm at low temperatures and up to room temperature. In addition, we validate the tunability of the wavelength between 1.8 µm and 3.5 µm via alloying Ge with to up 30% Si. These results reveal the potential of this new material system for SiGe based light emitting devices.
References
1C. Rödl et al. Phys.Rev.B, 2015, 92, 045207
2I. Hauge et al., Nano Lett., 2017, 17 (1), pp 85–90
We have realized hex- SiGe by utilizing wurtzite GaAs nanowire cores as a template to transfer the crystal structure to the SiGe shells in a core-shell geometry2. We demonstrate photoluminescence of hex-Ge at 3.5 µm at low temperatures and up to room temperature. In addition, we validate the tunability of the wavelength between 1.8 µm and 3.5 µm via alloying Ge with to up 30% Si. These results reveal the potential of this new material system for SiGe based light emitting devices.
References
1C. Rödl et al. Phys.Rev.B, 2015, 92, 045207
2I. Hauge et al., Nano Lett., 2017, 17 (1), pp 85–90
*This project is funded from the European Union’s Horizon 2020 research and innovation program under grant agreement No. 735008
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Presenters
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Elham Fadaly
- Applied Physics, Eindhoven University of Technology