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Lysevych, Mykhaylo
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Topics
Publications (13/13 displayed)
- 2023Core-shell GaN/AlGaN nanowires grown by selective area epitaxycitations
- 2022Nonpolar Al xGa1−xN/Al yGa1−yN multiple quantum wells on GaN nanowire for UV emissioncitations
- 2022Far-Field Polarization Engineering from Nonlinear Nanoresonatorscitations
- 2022Selective Area Growth of GaN Nanowirecitations
- 2021Narrow-Bandgap InGaAsP Solar Cell with TiO2 Carrier-Selective Contactcitations
- 2020Forward and Backward Switching of Nonlinear Unidirectional Emission from GaAs Nanoantennascitations
- 2019Second-harmonic generation in (111) gallium arsenide nanoantennas
- 2019 Ultrathin Ta 2 O 5 electron-selective contacts for high efficiency InP solar cells citations
- 2019InGaAsP as a Promising Narrow Band Gap Semiconductor for Photoelectrochemical Water Splittingcitations
- 2019Ultrathin Ta2O5 electron-selective contacts for high efficiency InP solar cellscitations
- 2018Indium phosphide based solar cell using ultra-thin ZnO as an electron selective layercitations
- 2017Improved photoelectrochemical performance of GaN nanopillar photoanodescitations
- 2017Void evolution and porosity under arsenic ion irradiation in GaAs1-xSbx alloyscitations
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article
Core-shell GaN/AlGaN nanowires grown by selective area epitaxy
Abstract
<p>GaN/AlGaN core-shell nanowires with various Al compositions have been grown on GaN nanowire array using selective area metal organic chemical vapor deposition technique. Growth of the AlGaN shell using pure N<sub>2</sub> carrier gas resulted in a smooth surface for the nonpolar m-plane sidewalls with superior optical properties, whereas, growth using a mixed N<sub>2</sub>/H<sub>2</sub> carrier gas resulted in a striated surface similar to the commonly observed morphology in the growth of nonpolar III-nitrides. The Al compositions in the AlGaN shells are found to be less than the gas phase input ratio. The systematic reduction in efficiency of Al incorporation in the AlGaN shells with increasing the Al molar flow in the gas phase is attributed to geometric loss, strain-limited Al incorporation, and increased gas phase parasitic reactions. Defect-related luminescence has been observed for AlGaN shells with Al content ≥ 30% and the origin of the defect luminescence has been determined as the (V<sub>III</sub>-2O<sub>N</sub>)<sup>1−</sup> complex. Microstructural analysis of the AlGaN shells revealed that the dominant defects are partial dislocations. Growth of the nonpolar m-plane Al<sub>x</sub>Ga<sub>1−x</sub>N/Al<sub>y</sub>Ga<sub>1−y</sub>N quantum wells on the sidewalls of the GaN nanowires produced arrays with excellent morphology and optical emission, which demonstrated the viability of such a growth scheme for large area efficient ultraviolet LEDs as well as for next generation ultraviolet micro-LEDs.</p>