4,856 research outputs found
Growth and optical characterisation of multilayers of InGaN quantum dots
We report on the growth (using metal-organic vapour phase epitaxy) and optical
characterization of single and multiple layers of InGaN quantum dots (QDs), which were formed by
annealing InGaN epilayers at the growth temperature in nitrogen. The size and density of the
nanostructures have been found to be fairly similar for uncapped single and three layer QD samples if
the GaN barriers between the dot layers are grown at the same temperature as the InGaN epilayer. The
distribution of nanostructure heights of the final QD layer of three is wider and is centred around a
larger size if the GaN barriers are grown at two temperatures (first a thin layer at the dot growth
temperature, then a thicker layer at a higher temperature). Micro-photoluminescence studies at 4.2 K
of capped samples have confirmed the QD nature of the capped nanostructures by the observation of
sharp emission peaks with full width at half maximum limited by the resolution of the spectrometer.
We have also observed much more QD emission per unit area in a sample with three QD layers, than in
a sample with a single QD layer, as expected
The effects of Si-doped prelayers on the optical properties of InGaN/GaN single quantum well structures
In this paper, we report on the effects of including Si-doped (In)GaN prelayers on the low temperature optical properties of a blue-light emitting InGaN/GaN single quantum well. We observed a large blue shift of the photoluminescence peak emission energy and significant increases in the radiative recombination rate for the quantum well structures that incorporated Si-doped prelayers. Simulations of the variation of the conduction and valence band energies show that a strong modification of the band profile occurs for the quantum wells on Si-doped prelayers due to an increase in strength of the surface polarization field. The enhanced surface polarization field opposes the built-in field across the quantum well and thus reduces this built-in electric field. This reduction of the electric field across the quantum well reduces the Quantum Confined Stark Effect and is responsible for the observed blue shift and the change in the recombination dynamics.This work was carried out with the financial support of
the United Kingdom Engineering and Physical Sciences
Research Council under Grant Nos. EP/I012591/1 and EP/
H011676/1.This is the accepted manuscript version of the article. The final version is available from AIP at http://scitation.aip.org/content/aip/journal/apl/105/9/10.1063/1.4894834
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Morphological changes of InGaN epilayers during annealing assessed by spectral analysis of atomic force microscopy images
A comparison of the optical properties of InGaN/GaN multiple quantum well structures grown with and without Si-doped InGaN prelayers
In this paper, we report on a detailed spectroscopic study of the optical properties of InGaN/GaN multiple quantum well structures, both with and without a Si-doped InGaN prelayer. In photoluminescence and photoluminescence excitation spectroscopy, a 2nd emission band, occurring at a higher energy, was identified in the spectrum of the multiple quantum well structure containing the InGaN prelayer, originating from the first quantum well in the stack. Band structure calculations revealed that a reduction in the resultant electric field occurred in the quantum well immediately adjacent to the InGaN prelayer, therefore leading to a reduction in the strength of the quantum confined Stark effect in this quantum well. The partial suppression of the quantum confined Stark effect in this quantum well led to a modified (higher) emission energy and increased radiative recombination rate. Therefore, we ascribed the origin of the high energy emission band to recombination from the 1st quantum well in the structure. Study of the temperature dependent recombination dynamics of both samples showed that the decay time measured across the spectrum was strongly influenced by the 1st quantum well in the stack (in the sample containing the prelayer) leading to a shorter average room temperature lifetime in this sample. The room temperature internal quantum efficiency of the prelayer containing sample was found to be higher than the reference sample (36% compared to 25%) which was thus attributed to the faster radiative recombination rate of the 1st quantum well providing a recombination pathway that is more competitive with non-radiative recombination processes.This work was carried out with the financial support of the United Kingdom Engineering and Physical Sciences Research Council under Grant Nos. EP/I012591/1 and EP/ H011676/1.This is the final version of the article. It first appeared from AIP Publishing via http://dx.doi.org/10.1063/1.494132
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The ABC model of recombination reinterpreted: Impact on understanding carrier transport and efficiency droop in InGaN/GaN light emitting diodes
The efficiency of light emitting diodes remains a topic of great contemporary interest due to their potential to reduce the amount of energy consumed in lighting. The current consensus is that electrons and holes distribute themselves through the emissive region by a drift-diffusion process which results in a highly non-uniform distribution of the light emission and can reduce efficiency. In this paper the measured variations in external quantum efficiency of a range of InGaN/GaN LEDs with different numbers of quantum wells are shown to compare closely with the predictions of a revised ABC model in which it is assumed that the electrically injected electrons and holes are uniformly distributed through the multi-quantum well region, or nearly so, and hence carrier recombination occurs equally in all the quantum wells. The implications of the reported results are that drift-diffusion plays a far lesser role in
cross-well carrier transport than previously thought; that the dominant cause of efficiency droop is intrinsic to the quantum wells and that reductions in the density of non-radiative recombination centers in the MQW would enable the use of more QWs and thereby reduce Auger losses by spreading carriers more evenly across a wider emissive region
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Microstructural dependency of optical properties of m -plane InGaN multiple quantum wells grown on 2° misoriented bulk GaN substrates
A non-polar m-plane structure consisting of five InGaN/GaN quantum wells (QWs) was grown on ammonothermal bulk GaN by metal-organic vapor phase epitaxy. Surface step bunches propagating through the QW stack were found to accommodate the 2° substrate miscut towards the -c direction. Both large steps with heights of a few tens of nanometres and small steps between one and a few atomic layers in height are observed, the former of which exhibit cathodoluminescence at longer wavelengths than the adjacent m-plane terraces. This is attributed to the formation of semi-polar facets at the steps on which the QWs are shown to be thicker and have higher Indium contents than those in the adjacent m-plane regions. Discrete basal-plane stacking faults (BSFs) were occasionally initiated from the QWs on the main m-plane terraces, but groups of BSFs were frequently observed to initiate from those on the large steps, probably related to the increased strain associated with the locally higher indium content and thickness.This project is funded by the European Research Council under the European Community's Seventh Framework Programme (FP7/2007-2013)/ERC grant agreement no 279361 (MACONS) and in part by the EPSRC (Grant Nos. EP/H047816/1 and EP/J001627/1).This is the author accepted manuscript. The final version is available from AIP via http://dx.doi.org/10.1063/1.492872
The consequences of high injected carrier densities on carrier localization and efficiency droop in InGaN/GaN quantum well structures
There is a great deal of interest in the underlying causes of efficiency droop in
InGaN/GaN quantum well light emitting diodes, with several physical mechanisms
being put forward to explain the phenomenon. In this paper we report on the
observation of a reduction in the localisation induced S-shape temperature
dependence of the peak photoluminescence energy with increasing excitation power
density. This S-shape dependence is a key fingerprint of carrier localisation. Over
the range of excitation power density where the depth of the S shape is reduced we
also observe a reduction in the integrated photoluminescence intensity per unit
excitation power, i.e. efficiency droop. Hence the onset of efficiency droop occurs at
the same carrier density as the onset of carrier delocalisation. We correlate these
experimental results with the predictions of a theoretical model of the effects of
carrier localisation due to local variations in the concentration of the randomly
distributed In atoms on the optical properties of InGaN/GaN quantum wells. On the
basis of this comparison of theory with experiment we attribute the reduction in the Sshape
temperature dependence to the saturation of the available localised states. We
propose that this saturation of the localised states is a contributory factor to efficiency
droop whereby non localised carriers recombine non-radiatively
Family Caregivers Who Would Be Unwilling to Provide Care at the End of Life Again: Findings from the Health Survey for England Population Survey
BACKGROUND: Family caregivers provide significant care at the end of life. We aimed to describe caregiver characteristics, and of those unwilling to repeat this role under the same circumstances.METHODS: Observational study of adults in private households (Health Survey for England [HSE]). Caregiving questions included: whether someone close to them died within past 5 years; relationship to the deceased; provision, intensity and duration of care; supportive/palliative care services used; willingness to care again; able to carry on with life. Comparison between those willing to care again or not used univariable analyses and an exploratory multiple logistic regression. A descriptive comparison with Health Omnibus Survey (Australia) data was conducted.FINDINGS: HSE response was 64%. 2167/8861 (25%) respondents had someone close to them die in the previous 5 years. Some level of personal care was provided by 645/8861 (7.3%). 57/632 (9%) former caregivers would be unwilling to provide care again irrespective of time since the death, duration of care, education and income. Younger age (≤65; odds ratio [OR] 2.79; 95% CI 136, 5.74) and use of palliative care services (odds ratio: 1.95, 95% CI: 1.09, 3.48) showed greater willingness to provide care again. Apart from use of palliative care services, findings were remarkably similar to the Australian data.CONCLUSIONS: A significant group of caregivers would be unwilling to provide care again. Older people and those who had not used palliative care services were more likely to be unwilling to care again. Barriers preventing access for disadvantaged groups need to be overcome
Effect of growth temperature and V/III-ratio on the surface morphology of MOVPE-grown cubic zincblende GaN
The influence of growth temperature and V/III-ratio on the surface morphology of (001) cubic zincblende GaN epilayers during metal organic vapour phase epitaxy growth has been investigated using atomic force microscopy and transmission electron microscopy. The zincblende phase purity as determined by X-ray diffraction was found to be above 98% for most GaN epilayers studied. As the growth temperature was increased from 850 °C to 910 °C and as the V/III-ratio was separately increased from 38 to 300, surface features were found to be elongated in the [1-10] direction, and the ratio of the length to width of such surface features was found to increase. Faceting was observed at V/III-ratios below 38 and above 300, which in the latter case was accompanied by a reduction of the zincblende phase purity. An explanation for these morphological trends is proposed based on effects such as the reduced symmetry of the top monolayer of the (001)-oriented zincblende GaN lattice, diffusion of Ga and N adatoms on such a surface, and the relative energies of the crystal facets.We would like to thank Innovate UK for the financial support within the Energy Catalyst Round 2 - Early Stage Feasibility scheme (Ref. 132135) and Energy Catalyst Round 4 - Mid Stage Feasibility scheme (Ref. 102766). We acknowledge the support of EPSRC through grant no. EP/M010589/1 and grant no. EP/R01146X/1. DJW would like to thank the support of EPSRC through grant no. EP/N01202X/1
Recombination from polar InGaN/GaN quantum well structures at high excitation carrier densities
In this paper we report on the emergence of a high energy band at high optically excited carrier densities in the low temperature photoluminescence spectra from polar InGaN/GaN single quantum well structures. This high energy band emerges at carrier densities when the emission from the localized ground states begins to saturate. We attribute this high energy band to recombination involving higher energy less strongly localized electron and hole states that are populated once the localized ground states become saturated; this assignment is supported by the results from an atomistic tight-binding model. A particular characteristic of the recombination at the high carrier densities is that the overall forms of the photoluminescence decay curves bear great similarity to those from semiconductor quantum dots. The decay curves consist of plateaus where the photoluminescence intensity is constant with time as a result of Pauli state blocking in the high energy localized states followed by a rapid decrease in intensity once the carrier density is sufficiently low that the states involved are no longer saturated
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