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Optical Studies of InGaN/GaN Quantum Well Structures
[Thesis]. Manchester, UK: The University of Manchester; 2014.
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Abstract
In this thesis I present and discuss the results of optical spectroscopy performed on InGaN/GaN single and multiple quantum well (QW) structures. I report on the optical properties of InGaN/GaN single and multiple QW structures, measured at high excitation power densities. I show a correlation exists between the reduction in PL efficiency at high excitation power densities, the phenomenon so-called ``efficiency-droop'', and a broadening of the PL spectra. I also show a distinct change in recombination dynamics, measured by time-resolved photoluminescence (PL), which occurs at the excitation power densities for which efficiency droop is measured. The broadening of the PL spectra at high excitation power densities is shown to occur due to a rapidly redshifting, short-lived high energy emission band. The high energy emission band is proposed to be due to the recombination of weakly localised/delocalised carriers occurring as a consequence of the progressive saturation of the local potential fluctuations responsible for carrier localisation, at high excitation power densities. I report on the effects of varying threading dislocation (TD) density on the optical properties of InGaN/GaN multiple QW structures. No systematic relationship exists between the room temperature internal quantum efficiency (IQE) and the TD density, in a series of nominally identical InGaN/GaN multiple QWs deposited on GaN templates of varying TD density. I also show the excitation power density dependence of the PL efficiency, at room temperatures, is unaffected for variation in the TD density between 2 x107 and 5 x109 cm-2. The independence of the optical properties to TD density is proposed to be a consequence of the strong carrier localisation, and hence short carrier diffusion lengths. I report on the effects of including an InGaN underlayer on the optical and microstructural properties of InGaN/GaN multiple QW structures. I show an increase in the room temperature IQE occurs for the structure containing the InGaN underlayer, compared to the reference. I show using PL excitation spectroscopy that an additional carrier transfer and recombination process occurs on the high energy side of the PL spectrum associated with the InGaN underlayer. Using PL decay time measurements I show the additional recombination process for carriers excited in the underlayer occurs on a faster timescale than the recombination at the peak of the PL spectrum. The additional contribution to the spectrum from the faster recombination process is proposed as responsible for the increase in room temperature IQE.
Keyword(s)
Carrier localisation; Crystal defects; Efficiency droop; GaN; Gallium nitride; InGaN; Indium gallium nitride; Internal quantum efficiency; Photoluminescence; Photoluminescence excitation; Piezoelectric field screening; Prelayer; Quantum Wells; Recombination dynamics; Semiconductors; Threading dislocations; Time resolved photoluminescence; Underlayer
Bibliographic metadata
- InGaN
- GaN
- Quantum Wells
- Semiconductors
- Time resolved photoluminescence
- Photoluminescence
- Recombination dynamics
- Efficiency droop
- Threading dislocations
- Underlayer
- Prelayer
- Photoluminescence excitation
- Carrier localisation
- Internal quantum efficiency
- Gallium nitride
- Indium gallium nitride
- Crystal defects
- Piezoelectric field screening