Electro-Optical Characterization of Passivated InAsP/InP Quantum Discs-in-Nanowire Heterostructures
(2018) FYSM60 20181Solid State Physics
Department of Physics
- Abstract
- Semiconductor nanowires, with their quasi one-dimension geometry, inherently provide strain relaxation for heterogeneous integration and also strong light mode confinement. Nanowire-based photonic devices have also been demonstrated to offer significantly enhanced quantum efficiency, gain and reduced noise. This project deals with electro-optical investigations of InP nanowires with axially embedded InAsP quantum discs. The advantages of InP/InAsP nanowire-based photodetectors include direct growth on lattice-mismatched silicon platforms due to the small nanowire footprint, significant bandgap tuning, strong confinement in quantum discs and optical resonances providing a large optical absorption despite the small material volume compared... (More)
- Semiconductor nanowires, with their quasi one-dimension geometry, inherently provide strain relaxation for heterogeneous integration and also strong light mode confinement. Nanowire-based photonic devices have also been demonstrated to offer significantly enhanced quantum efficiency, gain and reduced noise. This project deals with electro-optical investigations of InP nanowires with axially embedded InAsP quantum discs. The advantages of InP/InAsP nanowire-based photodetectors include direct growth on lattice-mismatched silicon platforms due to the small nanowire footprint, significant bandgap tuning, strong confinement in quantum discs and optical resonances providing a large optical absorption despite the small material volume compared to a thin film. However, due to the large surface-to-volume ratio of nanowires, surface states can strongly affect the electro-optical performance of nanowire-based heterostructure devices. Surface states can induce e.g. Fermi-level-pinning, non-radiative recombination and significant surface leakage currents which can deteriorate the performance of nanowire-based devices. Despite of all passivation attempts, surface states are still a challenge for InP/InAsP nanowire heterostructures. In this thesis work, the surfaces of InP nanowires, with embedded single- or 20 InAsP quantum discs, were passivated using atomic layer deposition of SiO2 or POx/Al2O3. Single passivated nanowires were optically characterized by photoluminescence and the results were compared with as-grown nanowires. To evaluate the effect of passivation on the corresponding electrical properties of the nanowires, nano-probe current-voltage measurements were carried out on single nanowires still standing on the growth substrate. Our results show that passivation with POx/Al2O3 improves the optical properties of the nanowires. POx/Al2O3 passivation leads to improved electrical characteristics in the nanowires with 20 quantum discs, while SiO2 enhances the electrical properties of nanowires with a single embedded quantum disc. The results will be used for future optimization of photodetectors. (Less)
- Popular Abstract
- Semiconductor nanowires, with their quasi one-dimension geometry, inherently provide strain relaxation for heterogeneous integration and also strong light mode confinement. Nanowire-based photonic devices have also been demonstrated to offer significantly enhanced quantum efficiency, gain and reduced noise. This project deals with electro-optical investigations of InP nanowires with axially embedded InAsP quantum discs. The advantages of InP/InAsP nanowire-based photodetectors include direct growth on lattice-mismatched silicon platforms due to the small nanowire footprint, significant bandgap tuning, strong confinement in quantum discs and optical resonances providing a large optical absorption despite the small material volume compared... (More)
- Semiconductor nanowires, with their quasi one-dimension geometry, inherently provide strain relaxation for heterogeneous integration and also strong light mode confinement. Nanowire-based photonic devices have also been demonstrated to offer significantly enhanced quantum efficiency, gain and reduced noise. This project deals with electro-optical investigations of InP nanowires with axially embedded InAsP quantum discs. The advantages of InP/InAsP nanowire-based photodetectors include direct growth on lattice-mismatched silicon platforms due to the small nanowire footprint, significant bandgap tuning, strong confinement in quantum discs and optical resonances providing a large optical absorption despite the small material volume compared to a thin film. However, due to the large surface-to-volume ratio of nanowires, surface states can strongly affect the electro-optical performance of nanowire-based heterostructure devices. Surface states can induce e.g. Fermi-level-pinning, non-radiative recombination and significant surface leakage currents which can deteriorate the performance of nanowire-based devices. Despite of all passivation attempts, surface states are still a challenge for InP/InAsP nanowire heterostructures. In this thesis work, the surfaces of InP nanowires, with embedded single- or 20 InAsP quantum discs, were passivated using atomic layer deposition of SiO2 or POx/Al2O3. Single passivated nanowires were optically characterized by photoluminescence and the results were compared with as-grown nanowires. To evaluate the effect of passivation on the corresponding electrical properties of the nanowires, nano-probe current-voltage measurements were carried out on single nanowires still standing on the growth substrate. Our results show that passivation with POx/Al2O3 improves the optical properties of the nanowires. POx/Al2O3 passivation leads to improved electrical characteristics in the nanowires with 20 quantum discs, while SiO2 enhances the electrical properties of nanowires with a single embedded quantum disc. The results will be used for future optimization of photodetectors. (Less)
Please use this url to cite or link to this publication:
http://lup.lub.lu.se/student-papers/record/9005607
- author
- Kordi Jazi, Samareh LU
- supervisor
- organization
- course
- FYSM60 20181
- year
- 2018
- type
- H1 - Master's Degree (One Year)
- subject
- language
- English
- id
- 9005607
- date added to LUP
- 2020-02-25 16:15:19
- date last changed
- 2020-03-05 11:44:05
@misc{9005607, abstract = {{Semiconductor nanowires, with their quasi one-dimension geometry, inherently provide strain relaxation for heterogeneous integration and also strong light mode confinement. Nanowire-based photonic devices have also been demonstrated to offer significantly enhanced quantum efficiency, gain and reduced noise. This project deals with electro-optical investigations of InP nanowires with axially embedded InAsP quantum discs. The advantages of InP/InAsP nanowire-based photodetectors include direct growth on lattice-mismatched silicon platforms due to the small nanowire footprint, significant bandgap tuning, strong confinement in quantum discs and optical resonances providing a large optical absorption despite the small material volume compared to a thin film. However, due to the large surface-to-volume ratio of nanowires, surface states can strongly affect the electro-optical performance of nanowire-based heterostructure devices. Surface states can induce e.g. Fermi-level-pinning, non-radiative recombination and significant surface leakage currents which can deteriorate the performance of nanowire-based devices. Despite of all passivation attempts, surface states are still a challenge for InP/InAsP nanowire heterostructures. In this thesis work, the surfaces of InP nanowires, with embedded single- or 20 InAsP quantum discs, were passivated using atomic layer deposition of SiO2 or POx/Al2O3. Single passivated nanowires were optically characterized by photoluminescence and the results were compared with as-grown nanowires. To evaluate the effect of passivation on the corresponding electrical properties of the nanowires, nano-probe current-voltage measurements were carried out on single nanowires still standing on the growth substrate. Our results show that passivation with POx/Al2O3 improves the optical properties of the nanowires. POx/Al2O3 passivation leads to improved electrical characteristics in the nanowires with 20 quantum discs, while SiO2 enhances the electrical properties of nanowires with a single embedded quantum disc. The results will be used for future optimization of photodetectors.}}, author = {{Kordi Jazi, Samareh}}, language = {{eng}}, note = {{Student Paper}}, title = {{Electro-Optical Characterization of Passivated InAsP/InP Quantum Discs-in-Nanowire Heterostructures}}, year = {{2018}}, }