We report the growth of InN quantum dots (QDs) on thick InGaN layers with high In composition (>50) by molecular beam epitaxy. Optimized growth conditions are identified for the InGaN layers at reduced growth temperature and increased active N flux resulting in minimized phase separation and defect generation. The InN QDs grown on top of the optimized InGaN layer exhibit small size, high density, and photoluminescence up to room temperature. The InN/InGaN QDs reveal excellent potential for intermediate band solar cells with the InGaN and InN QD bandgap energies tuned to the best match of absorption to the solar spectrum. © 2013 American Institute of Physics.
Soto Rodriguez, P., Gomez, V., Kumar, P., Calleja, E., Notzel, R. (2013). Near-infrared InN quantum dots on high-In composition InGaN. APPLIED PHYSICS LETTERS, 102(13) [10.1063/1.4800779].
Near-infrared InN quantum dots on high-In composition InGaN
Notzel R.
2013
Abstract
We report the growth of InN quantum dots (QDs) on thick InGaN layers with high In composition (>50) by molecular beam epitaxy. Optimized growth conditions are identified for the InGaN layers at reduced growth temperature and increased active N flux resulting in minimized phase separation and defect generation. The InN QDs grown on top of the optimized InGaN layer exhibit small size, high density, and photoluminescence up to room temperature. The InN/InGaN QDs reveal excellent potential for intermediate band solar cells with the InGaN and InN QD bandgap energies tuned to the best match of absorption to the solar spectrum. © 2013 American Institute of Physics.
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