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21	The microstructure of thin film cadmium telluride photovoltaic materials Abbas, Ali January 2014 (has links) In this work cadmium telluride thin film photovoltaic devices have successfully been produced using a novel closed-field magnetron sputtering technique. This technique offers the possibility of producing cells in an all-in-one vacuum process with the potential to provide a new lower cost production route. The sputtered cadmium telluride layers were characterised in detail using a range of advanced microscopy based techniques both in the as deposited and after the cadmium chloride treated state, a treatment that is necessary to produce a working cell. In the as deposited condition the cadmium telluride layer was seen to have a fine-grained columnar structure containing a high density of stacking faults. After the cadmium chloride treatment these grains recrystallized and the new grains were equiaxed with a much lower density of intragranular defects. Similar effects were also observed in samples prepared using close space sublimation. To understand this recrystallization behaviour during the cadmium chloride treatment, the key treatment parameters were systematically varied. Chemical analysis in Scanning Transmission Electron Microscopy (STEM) showed that chlorine travelled down the cadmium telluride grain boundaries and accumulated adjacent to the cadmium telluride/cadmium sulphide interface. This interface is where the cadmium telluride grains were found to recrystallise first during interrupted cadmium chloride treatments. The nature of the stacking faults was examined using High Resolution Transmission Electron Microscopy (HR-TEM). This showed that in localised regions up to one plane of atoms per sequence was missing based on the expected zinc blende structure. This changed the packing of the atoms such that a local change in crystal structure occurred. This local change in phase was successfully mapped using Electron Backscatter Diffraction in planar section produced using Focused Ion Beam milling. This was subsequently studied in more detail using Transmission Electron Backscatter Diffraction in the Scanning Electron Microscope, where the intra-granular arrangement of the phases was observed. HR-TEM was used to quantitatively measure the linear defects in the cadmium telluride layer after thermal annealing with and without the cadmium chloride present. This showed that annealing alone resulted in only a modest reduction in the density of linear defects and grain recrysallisation only occurred in the presence of cadmium chloride. Cadmium magnesium telluride (CMT) was successfully grown epitaxially onto the cadmium telluride as an electron reflector layer to improve cell performance. During deposition the cell experienced high temperatures and this caused the stacking faults to return in a cell that had been previously cadmium chloride treated. This resulted in a reduction in cell efficiency, providing another link between linear defects and a degradation in cell performance. 621.31
22	A Segmented Silicon Strip Detector for Photon-Counting Spectral Computed Tomography Xu, Cheng January 2012 (has links) Spectral computed tomography with energy-resolving detectors has a potential to improve the detectability of images and correspondingly reduce the radiation dose to patients by extracting and properly using the energy information in the broad x-ray spectrum. A silicon photon-counting detector has been developed for spectral CT and it has successfully solved the problem of high photon flux in clinical CT applications by adopting the segmented detector structure and operating the detector in edge-on geometry. The detector was evaluated by both the simulation and measurements. The effects of energy loss and charge sharing on the energy response of this segmented silicon strip detector with different pixel sizes were investigated by Monte Carlo simulation and a comparison to pixelated CdTe detectors is presented. The validity of spherical approximations of initial charge cloud shape in silicon detectors was evaluated and a more accurate statistical model has been proposed. A photon-counting energy-resolving application specific integrated circuit (ASIC) developed for spectral CT was characterized extensively by electrical pulses, pulsed laser and real x-ray photons from both the synchrotron and an x-ray tube. It has been demonstrated that the ASIC performs as designed. A noise level of 1.09 keV RMS has been measured and a threshold dispersion of 0.89 keV RMS has been determined. The count rate performance of the ASIC in terms of count loss and energy resolution was evaluated by real x-rays and promising results have been obtained. The segmented silicon strip detector was evaluated using synchrotron radiation. An energy resolution of 16.1% has been determined with 22 keV photons in the lowest flux limit, which deteriorates to 21.5% at an input count rate of 100 Mcps mm−2. The fraction of charge shared events has been estimated and found to be 11.1% for 22 keV and 15.3% for 30 keV. A lower fraction of charge shared events and an improved energy resolution can be expected by applying a higher bias voltage to the detector. / <p>QC 20121123</p> photon counting spectral computed tomography silicon strip detector ASIC energy resolution cadmium telluride charge sharing Monte Carlo simulation synchrotron
23	Synthesis And Characterization Of Semiconductor Nanowires Via Electrochemical Technique Dogan, Bahadir 01 December 2009 (has links) (PDF) This thesis aims to investigate structural, optical and photoelectrochemical behavior of CdS nanowires and their heterojunctions with CdTe and polypyrrole nanowires. In the first part, CdS nanowires have been synthesized via electrochemical template-based route. It has been observed that synthesis conditions, such as bias voltage and deposition time, affect the morphology, optical and photoelectrochemical characteristics of CdS nanowires. Depending on the deposition time, length of the CdS nanowires changed from 100-200 nm to 3-4 m. Also the diameter of the nanowires increased with increasing the deposition time. Structure of the CdS nanowires has been confirmed by X-ray diffraction spectrometry and EDX analysis. Phototelectrochemical performances of the CdS nanowires have been changed dramatically with bias voltage and deposition time.In the second part of this thesis, CdTe nanostructures have been deposited on CdS nanowires. Change in optical and photoelectrochemical behavior of CdS nanowires after CdTe deposition has been investigated. Organic semiconductors and their composites with inorganic materials have been gaining attention due to tunable optical, electrical and magnetic properties. Also, ease of fabrication techniques, and therefore, low cost made these materials attractive for lots of applications including photovoltaic devices and flexible electronics. In the last part of this thesis, heterojunctions of CdS and Polypyrrole (Ppy) nanowires have been synthesized. Like CdS/CdTe heteronanostructures, first the CdS nanowires have been electrochemically deposited in anodized alumina template and then Ppy has been successfully deposited on CdS nanowires. In order to investigate the effects of polypyrrole synthesis conditions on CdS/Ppy heteronanostructures, CdS nanowire synthesis conditions have been kept constant. It has been observed that morphology and photoelectrochemical behavior of the Ppy nanowires has been affected from Ppy synthesis conditions. The photoelectrochemical performance changes of CdS/Ppy heteronanostructures have been also investigated in this part. QD Chemistry 1-999
24	INVESTIGATIONS OF CuInTe2 / CdS & CdTe / CdS HETEROJUNCTION SOLAR CELLS Gutta, Venkatesh 01 January 2011 (has links) Thin film solar cells of Copper Indium Telluride and Cadmium Sulfide junctions were fabricated on plain ITO glass slides and also on those coated with intrinsic Tin Oxide. CdS was deposited through chemical bath deposition and CIT by electrodeposition. Both compounds were subjected to annealing at temperatures between 350°C and 500°C which produced more uniform film thicknesses and larger grain sizes. The CIT/ CdS junction was characterized after performing XRD and spectral absorption of individual compounds. Studies were also made on CdS / CdTe solar cells with respect to effect of annealing temperatures on open circuit voltages. NP acid etch, the most important process to make the surface of CdTe tellurium rich, was also studied in terms of open circuit voltages. Thermally evaporated CdS of four different thicknesses was deposited on Tin Oxide coated ITO and inferences were drawn as to what thickness of CdS yields better results. Copper Indium Telluride (CIT) Electrodeposition Chemical Bath Deposition Cadmium Sulfide Cadmium Telluride Thermal Evaporation Electrical and Computer Engineering Engineering
25	Amorphous Silicon Contacts for Silicon and Cadmium Telluride Solar Cells January 2018 (has links) abstract: Achieving high efficiency in solar cells requires optimal photovoltaics materials for light absorption and as with any electrical device—high-quality contacts. Essentially, the contacts separate the charge carriers—holes at one terminal and electrons at the other—extracting them to an external circuit. For this purpose, the development of passivating and carrier-selective contacts that enable low interface defect density and efficient carrier transport is critical for making high-efficiency solar cells. The recent record-efficiency n-type silicon cells with hydrogenated amorphous silicon (a-Si:H) contacts have demonstrated the usefulness of passivating and carrier-selective contacts. However, the use of a-Si:H contacts should not be limited in just n-type silicon cells. In the present work, a-Si:H contacts for crystalline silicon and cadmium telluride (CdTe) solar cells are developed. First, hydrogen-plasma-processsed a-Si:H contacts are used in n-type Czochralski silicon cell fabrication. Hydrogen plasma treatment is used to increase the Si-H bond density of a-Si:H films and decrease the dangling bond density at the interface, which leads to better interface passivation and device performance, and wider temperature-processing window of n-type silicon cells under full spectrum (300–1200 nm) illumination. In addition, thickness-varied a-Si:H contacts are studied for n-type silicon cells under the infrared spectrum (700–1200 nm) illumination, which are prepared for silicon-based tandem applications. Second, the a-Si:H contacts are applied to commercial-grade p-type silicon cells, which have much lower bulk carrier lifetimes than the n-type silicon cells. The approach is using gettering and bulk hydrogenation to improve the p-type silicon bulk quality, and then applying a-Si:H contacts to enable excellent surface passivation and carrier transport. This leads to an open-circuit voltage of 707 mV in p-type Czochralski silicon cells, and of 702 mV, the world-record open-circuit voltage in p-type multi-crystalline silicon cells. Finally, CdTe cells with p-type a-Si:H hole-selective contacts are studied. As a proof of concept, p-type a-Si:H contacts enable achieving the highest reported open-circuit voltages (1.1 V) in mono-crystalline CdTe devices. A comparative study of applying p-type a-Si:H contacts in poly-crystalline CdTe solar cells is performed, resulting in absolute voltage gain of 53 mV over using the standard tellurium contacts. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2018 Electrical engineering Materials Science Plasma physics amorphous silicon cadmium telluride contact crystalline silicon hydrogen plasma solar cell
26	Application of rotating magnetic fields to the travelling heater method growth of GaSb and the synthesis of CdTe Roszmann, Jordan D. 01 April 2009 (has links) Understanding and control of the flow structures in metallic fluids is important for the development of optimal crystal growth processes. One of the techniques used to control flow structures is the application of a rotating magnetic field (RMF) in the plane perpendicular to the growth direction, which induces two magnetic body force components; one in the radial direction and the other one in the circumferential direction. These two body force components alter the fluid flow in the growth system, leading to enhanced mixing, flatter growth interface, and more homogeneous crystal composition. The application of RFM was therefore considered in three separate projects: 1) the zone refining of cadmium and tellurium, 2) the synthesis of cadmium telluride (CdTe) by the travelling heater method (THM), and 3) the THM growth of gallium antimonide (GaSb). In the zone refining of tellurium, the objective was to enhance the transport of selenium in the melt since the selenium segregation coefficient is close to unity. A magnetic field with intensity of 0.6 mT and frequency of 100 Hz was selected based on the results of earlier numerical simulations. Due to the very low electrical conductivity of tellurium, the numerical simulations predicted a very small effect of RMF on selenium transport. The designed zone refining experiments for the tellurium system have verified this numerical simulation result. On the other hand, cadmium is an electric conductor, and thus the numerical simulations predicted a notable effect of RMF. However, experiments on the cadmium system could not be carried out because of the instability of molten zones caused by cadmium’s very high thermal conductivity. The commercial synthesis of CdTe is presently done by THM, which produces materials with much better stoichiometry than other techniques, but very slow process speeds make THM very costly. An application of RMF was considered in order to improve the speed of the process. A 1.3 mT, 0.5 Hz field was applied during the THM synthesis of CdTe. Under the experimental conditions employed, the examination of samples has shown that the application of RMF did not increase the maximum synthesis speed. The use of higher intensity RMF was not possible with the present system, but it is thought that higher fields might worsen the mixing of Cd and Te to produce non-stoichiometry. The objective of the third project was to carry out preliminary THM growth experiments for GaSb under RMF in order to prepare a basis for future THM growth experiments aimed at reducing the cost of THM by using higher growth rates and smaller seeds with tapered ampoules. The substantially redesigned THM furnace permits rotation of the growth ampoule, better control of the experimental environment, and a stronger temperature gradient at the growth interface. Two crystals have been grown at 25 mm diameter with and without the application of a magnetic field of 0.6-mT intensity and 100-Hz frequency. These preliminary experiments have shown that the system can be used for the planned THM experiments; however, further experiments are required to attribute any effect to RMF. Travelling Heater Method Crystal Growth Gallium Antimonide Cadmium Telluride Magnetic Fields Zone Refining
27	Vlastnosti bodových defektů v CdTe při teplotách 300 - 600 K / Properties of point defects in CdTe at temperatures of 300 - 600 K Korcsmáros, Gabriel January 2019 (has links) The thermal stability of p-type CdTe crystals by using conductivity and Hall-effect measurements have been studied at room and slightly increased temperatures. It was observed that thermal changes often implicate an anomalous behavior of the hole density characterized by reversible decrease/increase in a heating/cooling regime. This anomaly was explained by a transfer of fast diffusing donors between Te inclusions and the bulk of the sample. Sodium and potassium were determined by the Secondary Ion Mass Spectroscopy (SIMS) as the most probable diffusing species. To verify this behavior samples were also treated in saturated NaCl solution for different time intervals in order to examine the influence of the oxide layer and sodium on the surface of the sample. To determine the structure of the surface the sample was characterized by ellipsometric and X-ray photoelectron spectroscopy (XPS) and SIMS. Very low determined diffusion coefficient of Na was explained by trapping of Na in Cd sublattice
28	Improving Performance in Cadmium Telluride Solar Cells: From Fabrication to Understanding the Pathway Towards 25% Efficiency Liyanage, Geethika Kaushalya January 2021 (has links) No description available. Physics Materials Science Cadmium Telluride TCO/emitter alignment front contact alignment band bending back-buffer initial Fermi level offset conduction band offset back-contact barrier
29	Charge Carrier Processes in Photovoltaic Materials and Devices: Lead Sulfide Quantum Dots and Cadmium Telluride Roland, Paul Joseph January 2015 (has links) No description available. Physics Solid State Physics Temperature-dependence Charge Carrier Transport Semiconductor Point Defects Lead Sulfide Quantum Dots Cadmium Telluride Photoluminescence Time Correlated Single Photon Counting Photovoltaics
30	Development of Deposition and Characterization Systems for Thin Film Solar Cells Cimaroli, Alexander J. January 2016 (has links) No description available. Solid State Physics Zinc Phosphide Cadmium Telluride Thin Film Solar Cell Photovoltaic Close-space Sublimation Hysteresis Perovskite Maximum Power Point Tracking

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