Your search keyword '"Girgel, Ionut"' showing total 7 results

1. Development of InGaN/GaN core-shell light emitters

Author

Girgel, Ionut and Shields, Philip

Subjects

621.32, semiconductor compounds, Gallium nitride, Core-shell, Light emitting diodes, Epitaxial growth, plasma etching, Nanorods, device designs, photoluminescence

Abstract

Gallium nitride (GaN) and its related semiconductor alloys are attracting tremendous interest for their wide range of applications in blue and green LEDs, diode lasers, high-temperature and high-power electronics. Nanomaterials such as InGaN/GaN core-shell three-dimensional nanostructures are seen as a breakthrough technology for future solid-state lighting and nano-electronics devices. In a core-shell LED, the active semiconductor layers grown around a GaN core enable control over a wide range of wavelengths and applications. In this thesis the capability for the heteroepitaxial growth of a proof-of-principle core-shell LED is advanced. A design that can be applied at the wafer scale using metalorganic vapor phase epitaxy (MOVPE) crystal growth on highly uniform GaN nanorod (NR) structures is proposed. This project demonstrates understanding over the growth constraints of active layers and dopant layers. The impact of reactor pressure and temperature on the morphology and on the incorporated InN mole fraction was studied for thick InGaN shells on the different GaN crystal facets. Mg doping and effectiveness of the p-n junction for a core-shell structure was studied by extensive growth experiments and characterization. Sapphire and Si substrates were used, and at all the stages of growth and fabrication. The structures were optimized to achieve geometry homogeneity, high-aspect-ratio, incorporation homogeneity for InN and Mg dopant. The three-dimensional nature of NRs and their light emission provided ample challenges which required adaptation of characterization and fabrication techniques for a core-shell device. Finally, an electrically contacted core-shell LED is demonstrated and characterized. Achieving a proof-of-principle core-shell device could be the starting point in the development of nanostructure-based devices and new physics, or in solving technical problems in planar LEDs, such as the polarization of emitted light, the quantum-confined Stark effect, efficiency droop, or the green gap.

Published

2017

2. Evolution of the m-plane Quantum Well Morphology and Composition within a GaN/InGaN Core-Shell Structure

Author

Coulon, Pierre-Marie, Vajargah, Shahrzad hosseini, Bao, An, Edwards, Paul R., Le Boulbar, Emmanuel D., Girgel, Ionut, Martin, Robert W., Humphreys, Colin J., Oliver, Rachel A., Allsopp, Duncan W. E., and Shields, Philip A.

Subjects

QD, QC

Abstract

GaN/InGaN core–shell nanorods are promising for optoelectronic applications due to the absence of polarization-related electric fields on the sidewalls, a lower defect density, a larger emission volume, and strain relaxation at the free surfaces. The core–shell geometry allows the growth of thicker InGaN shell layers, which would improve the efficiency of light emitting diodes. However, the growth mode of such layers by metal organic vapor phase epitaxy is poorly understood. Through a combination of nanofabrication, epitaxial growth, and detailed characterization, this work reveals an evolution in the growth mode of InGaN epitaxial shells, from a two-dimensional (2D) growth mode to three-dimensional (3D) striated growth without additional line defect formation with increasing layer thickness. Measurements of the indium distribution show fluctuations along the directions, with low and high indium composition associated with the 2D and 3D growth modes, respectively. Atomic steps at the GaN/InGaN core–shell interface were observed to occur with a similar frequency as quasi-periodic indium fluctuations along [0001] observed within the 2D layer, to provide evidence that the resulting local strain relief at the steps acts as the trigger for a change of growth mode by elastic relaxation. This study demonstrates that misfit dislocation generation during the growth of wider InGaN shell layers can be avoided by using pre-etched GaN nanorods. Significantly, this enables the growth of absorption-based devices and light-emitting diodes with emissive layers wide enough to mitigate efficiency droop.

Published

2017

3. Structural and optical emission uniformity of m-plane InGaN single quantum wells in core-shell nanorods

Author

Le Boulbar, Emmanuel, Hosseini-Vajargah, Shahrzad, Edwards, Paul R., Coulon, Pierre-Marie, Girgel, Ionut, Griffiths, Ian, Cherns, David, Martin, Robert W., Humphreys, Colin, Bowen, Christopher, Allsopp, Duncan, and Shields, Philip

Published

2016

4. Investigation of InGaN facet-dependent non-polar growth rates and composition for core-shell LEDs

Author

Girgel, Ionut, Edwards, Paul R., Le Boulbar, Emmanuel, Coulon, Pierre-Marie, Sahonta, Suman-Lata, Allsopp, Duncan, Martin, Robert W., Humphreys, Colin, and Shields, Philip

Published

2016

5. Development of InGaN/GaN Core-Shell Light Emitters

Author

Girgel, Ionut

Subjects

semiconductor compounds, Core-shell, device designs, plasma etching, Gallium nitride, Physics and Astronomy(all), Light emitting diodes, Materials Science(all), Epitaxial growth, Nanorods, photoluminescence, Engineering(all)

Abstract

Gallium nitride (GaN) and its related semiconductor alloys are attracting tremendous interest for their wide range of applications in blue and green LEDs, diode lasers, high-temperature and high-power electronics. Nanomaterials such as InGaN/GaN core-shell three-dimensional nanostructures are seen as a breakthrough technology for future solid-state lighting and nano-electronics devices. In a core-shell LED, the active semiconductor layers grown around a GaN core enable control over a wide range of wavelengths and applications.In this thesis the capability for the heteroepitaxial growth of a proof-of-principle core-shell LED is advanced. A design that can be applied at the wafer scale using metalorganic vapor phase epitaxy (MOVPE) crystal growth on highly uniform GaN nanorod (NR) structures is proposed. This project demonstrates understanding over the growth constraints of active layers and dopant layers. The impact of reactor pressure and temperature on the morphology and on the incorporated InN mole fraction was studied for thick InGaN shells on the different GaN crystal facets. Mg doping and effectiveness of the p-n junction for a core-shell structure was studied by extensive growth experiments and characterization. Sapphire and Si substrates were used, and at all the stages of growth and fabrication. The structures were optimized to achieve geometry homogeneity, high-aspect-ratio, incorporation homogeneity for InN and Mg dopant. The three-dimensional nature of NRs and their light emission provided ample challenges which required adaptation of characterization and fabrication techniques for a core-shell device.Finally, an electrically contacted core-shell LED is demonstrated and characterized. Achieving a proof-of-principle core-shell device could be the starting point in the development of nanostructure-based devices and new physics, or in solving technical problems in planar LEDs, such as the polarization of emitted light, the quantum-confined Stark effect, efficiency droop, or the green gap.

Published

2016

6. Investigation of facet-dependent InGaN growth for core-shell LEDs

Author

Girgel, Ionut, additional, Edwards, Paul R., additional, Le Boulbar, Emmanuel, additional, Allsopp, Duncan W., additional, Martin, Robert W., additional, and Shields, Philip A., additional

Published

2015

7. Investigation of facet-dependent InGaN growth for core-shell LEDs

Author

Chyi, Jen-Inn, Fujioka, Hiroshi, Morkoç, Hadis, Girgel, Ionut, Edwards, Paul R., Le Boulbar, Emmanuel, Allsopp, Duncan W., Martin, Robert W., and Shields, Philip A.

Published

2015