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11	Post processing Treatment of InGaZnO Thin Film Transistors for Improved Bias-Illumination Stress Reliability January 2013 (has links) abstract: This thesis work mainly examined the stability and reliability issues of amorphous Indium Gallium Zinc Oxide (a-IGZO) thin film transistors under bias-illumination stress. Amorphous hydrogenated silicon has been the dominating material used in thin film transistors as a channel layer. However with the advent of modern high performance display technologies, it is required to have devices with better current carrying capability and better reproducibility. This brings the idea of new material for channel layer of these devices. Researchers have tried poly silicon materials, organic materials and amorphous mixed oxide materials as a replacement to conventional amorphous silicon layer. Due to its low price and easy manufacturing process, amorphous mixed oxide thin film transistors have become a viable option to replace the conventional ones in order to achieve high performance display circuits. But with new materials emerging, comes the challenge of reliability and stability issues associated with it. Performance measurement under bias stress and bias-illumination stress have been reported previously. This work proposes novel post processing low temperature long time annealing in optimum ambient in order to annihilate or reduce the defects and vacancies associated with amorphous material which lead to the instability or even the failure of the devices. Thin film transistors of a-IGZO has been tested for standalone illumination stress and bias-illumination stress before and after annealing. HP 4155B semiconductor parameter analyzer has been used to stress the devices and measure the output characteristics and transfer characteristics of the devices. Extra attention has been given about the effect of forming gas annealing on a-IGZO thin film. a-IGZO thin film deposited on silicon substrate has been tested for resistivity, mobility and carrier concentration before and after annealing in various ambient. Elastic Recoil Detection has been performed on the films to measure the amount of hydrogen atoms present in the film. Moreover, the circuit parameters of the thin film transistors has been extracted to verify the physical phenomenon responsible for the instability and failure of the devices. Parameters like channel resistance, carrier mobility, power factor has been extracted and variation of these parameters has been observed before and after the stress. / Dissertation/Thesis / M.S. Electrical Engineering 2013 Electrical engineering Bias stress Illumination stress Indium Gallium Zinc Oxide Thin Film Transistors
12	Amorphous indium-gallium-zinc oxide planar nanodiodes Fryer, Antony Colin January 2014 (has links) In this thesis work, novel planar nanodiodes (PNDs) using an amorphous indium-gallium-zinc oxide (IGZO) film as the active layer have been electrically characterised for the first time. Simulation techniques and experimental methods, such as e-beam lithography (EBL) and nanoimprint lithography (NIL), have been explored for these devices. In addition, a novel approach was realized that produced self-aligned contacts for the nanostructured devices. A preliminary parameter space for experimentation of the PNDs was ascertained by simulating the devices using a technology computer aided design (TCAD) simulator. In this study Silvaco’s ATLAS default IGZO material system was adopted. These simulations showed device performance to be heavily dependent on the carrier concentration of the film, owing to the high leakage current during the off-state of device operation. Furthermore, device geometry had a significant influence on the device’s electrical response. Channel width, length and trench width were all examined. Experimental characterisation of PNDs were attained by fabricating devices using EBL. These devices are the first to exhbit diode-like DC electrical response from an IGZO-based PND. Full current rectification was obtained with a rectification ratio of 10^4 for devices with a long, narrow channel with a width of 50nm and a length of 4μm. This particular device geometry had a turn-on voltage, Von, of 2.2V and did not breakdown within the −10V bias range tested. An output drive current of 0.1μA at 10V was obtained by the single PND device. It was also demonstrated that by increasing the channel width, Von could be reduced; however, rectification also diminished. It is reasoned that the exposed IGZO surface was subject to contamination from the ambient which changed the device’s electrical response after 17 days. An ultraviolet NIL (UV-NIL) technique was developed to produce the PNDs. This fabrication method offers a suitable route towards high-volume manufacture of these nanodevices, which is critical for them to be incorporated into a low-cost RF energy harvester. A novel NIL process was established in which the contact pads were self-aligned to within ~ 200nm of the channel by patterning both metal and semiconductor layers with a single imprint. DC electrical characterisation of the imprinted PNDs produced high rectifications ratios at a lower Von. The greater number of devices tested allowed a coarse parameter space for channel width and length to determined. PNDs with a channel aspect ratio (length divided by width) of more than 20 exhibited the greatest DC rectification of 10^4. An alumina capping layer was found to eliminate hysteresis in the electrical response; however, the greater permittivity value had no noticeable effect on device performance. Finally, a large-signal RF analysis is carried out on a device which suggest no deterioration in device perfromance up to at least 1GHz. 621.3815
13	The Study of Astronomical Transients in the Infrared January 2019 (has links) abstract: Several key, open questions in astrophysics can be tackled by searching for and mining large datasets for transient phenomena. The evolution of massive stars and compact objects can be studied over cosmic time by identifying supernovae (SNe) and gamma-ray bursts (GRBs) in other galaxies and determining their redshifts. Modeling GRBs and their afterglows to probe the jets of GRBs can shed light on the emission mechanism, rate, and energetics of these events. In Chapter 1, I discuss the current state of astronomical transient study, including sources of interest, instrumentation, and data reduction techniques, with a focus on work in the infrared. In Chapter 2, I present original work published in the Proceedings of the Astronomical Society of the Pacific, testing InGaAs infrared detectors for astronomical use (Strausbaugh, Jackson, and Butler 2018); highlights of this work include observing the exoplanet transit of HD189773B, and detecting the nearby supernova SN2016adj with an InGaAs detector mounted on a small telescope at ASU. In Chapter 3, I discuss my work on GRB jets published in the Astrophysical Journal Letters, highlighting the interesting case of GRB 160625B (Strausbaugh et al. 2019), where I interpret a late-time bump in the GRB afterglow lightcurve as evidence for a bright-edged jet. In Chapter 4, I present a look back at previous years of RATIR (Re-ionization And Transient Infra-Red Camera) data, with an emphasis on the efficiency of following up GRBs detected by the Fermi Space Telescope, before some final remarks and brief discussion of future work in Chapter 5. / Dissertation/Thesis / Doctoral Dissertation Physics 2019 Astrophysics Astronomy gamma-ray bursts indium-gallium-arsenide infrared RATIR time-domain trasient
14	Metastability of copper indium gallium diselenide polycrystalline thin film solar cell devices Lee, Jinwoo, 1973- 09 1900 (has links) xvi, 117 p. ; ill. (some col.) A print copy of this thesis is available through the UO Libraries. Search the library catalog for the location and call number. / High efficiency thin film solar cells have the potential for being a world energy solution because of their cost-effectiveness. Looking to the future of solar energy, there is the opportunity and challenge for thin film solar cells. The main theme of this research is to develop a detailed understanding of electronically active defect states and their role in limiting device performance in copper indium gallium diselenide (CIGS) solar cells. Metastability in the CIGS is a good tool to manipulate electronic defect density and thus identify its effect on the device performance. Especially, this approach keeps many device parameters constant, including the chemical composition, grain size, and interface layers. Understanding metastability is likely to lead to the improvement of CIGS solar cells. We observed systematic changes in CIGS device properties as a result of the metastable changes, such as increases in sub-bandgap defect densities and decreases in hole carrier mobilities. Metastable changes were characterized using high frequency admittance spectroscopy, drive-level capacitance profiling (DLCP), and current-voltage measurements. We found two distinctive capacitance steps in the high frequency admittance spectra that correspond to (1) the thermal activation of hole carriers into/out of acceptor defect and (2) a temperature-independent dielectric relaxation freeze-out process and an equivalent circuit analysis was employed to deduce the dielectric relaxation time. Finally, hole carrier mobility was deduced once hole carrier density was determined by DLCP method. We found that metastable defect creation in CIGS films can be made either by light-soaking or with forward bias current injection. The deep acceptor density and the hole carrier density were observed to increase in a 1:1 ratio, which seems to be consistent with the theoretical model of V Cu -V Se defect complex suggested by Lany and Zunger. Metastable defect creation kinetics follows a sub-linear power law in time and intensity. Numerical simulation using SCAPS-1D strongly supports a compensated donor- acceptor conversion model for the experimentally observed metastable changes in CIGS. This detailed numerical modeling yielded qualitative and quantitative agreement even for a specially fabricated bifacial CIGS solar cell. Finally, the influence of reduced hole carrier mobility and its role in limiting device performance was investigated. / Adviser: J. David Cohen Energy Optics Condensed matter physics Polycrystalline thin films Solar cells Thin films Copper indium gallium diselenide Metastability
15	Design and Characterization of InGaN/GaN Dot-in-Nanowire Heterostructures for High Efficiency Solar Cells Cheriton, Ross 20 July 2018 (has links) Light from the sun is an attractive source of energy for its renewability, supply, scalability, and cost. Silicon solar cells are the dominant technology of choice for harnessing solar energy in the form of electricity, but the designs are approaching their practical efficiency limits. New multijunction designs which use the tunable properties of the more expensive III-V semiconductors have historically been relegated to space applications where absolute power conversion efficiency, resilience to radiation, and weight are more important considerations than cost. Some of the more recent developments in the field of semiconductor materials are the so-called III-nitride materials which mainly use either indium, aluminum or gallium in combination with nitrogen. Indium gallium nitride (InGaN) is one of these III-nitride semiconductor alloys that can be tailored to span the vast majority of the solar spectrum. While InGaN growth traditionally requires expensive substrate materials such as sapphire, three-dimensional nanowire growth modes enable high quality lattice mismatched growth of InGaN directly on silicon without a metamorphic buffer layer. The absorption and electronic properties of InGaN can also be tuned by incorporating it into quantum confined regions in a GaN host material. This opens up a route towards cost-effective, high efficiency devices such as light emitted diodes and solar cells which can operate over a large range of wavelengths. The combination of the two material systems of InGaN/GaN and silicon can marry the low cost of silicon wafers with the desirable optoelectronic properties of III-nitride semiconductors. This thesis investigates the potential for highly nanostructured InGaN/GaN based devices using quantum-dot-in-nanowire designs as novel solar cells which can enable intermediate band absorption effects and multiple junctions within a single nanowire to absorb more of the solar spectrum and operating more efficiently. Such semiconductor nanostructures can in principle reach power conversion efficiencies of over 40\% on silicon, with a cost closer to conventional silicon solar cells as opposed to methods which use non-silicon substrates. In the primary strategy, the nanowires contain InGaN quantum dots which act as photon absorption/carrier generation centres to sequentially excite photons within the large band gap semiconductor. By using this intermediate band of states, large operating voltages between contacts can be maintained without sacrificing the collection of long wavelength solar photons. In this work, we characterize the properties of such nanowires and experimentally demonstrate sub-bandgap current generation in a large area InGaN/GaN dot-in-nanowire solar cell. Experimental characterization of InGaN / GaN quantum dots in nanowires as both LEDs and solar cells is performed to determine the nanowire material parameters to understand how they relate to the nanowire device performance. Multiple microscopy techniques are performed to determine the nanowire morphology and contact effectiveness. Optical characterization of bare and fabricated nanowires is used to determine the anti-reflection properties of nanowire arrays. Photoluminescence and electroluminescence spectroscopy are performed. Illuminated current-voltage characteristics and quantum efficiencies are determined. Specular and diffuse reflectivities are measured as a function of wavelength. Technology computer-aided design (TCAD) software is used to simulate the performance of the overall nanowire device. The contribution from quantum dots or quantum wells is simulated by solving for the carrier wavefunctions and density of states with the quantum structures. The discretized density of states from the quantum dots is modelled and used in a complete drift-diffusion device simulation to reproduce electroluminescence results. The carrier transport properties are modified to demonstrate effects on the overall device performance. An alternate design is also proposed which uses an InGaN nanowire subcell on top of a silicon bottom subcell. The dual-junction design allows a broader absorption of the solar spectrum, increasing the operating voltage through monolithically grown series-connected, current-matched subcells. The performance of such a cell is simulated through drift-diffusion simulations of a dual-junction InGaN/Si solar cell. The effects of switching to a nanowire subcell based on the nanowires studied in this thesis is discussed. solar cells quantum dot nanowire quantum silicon gallium nitride indium gallium nitride efficiency intermediate band quantum well sub-bandgap
16	Engineering III-N Alloys and Devices for Photovoltaic Progress January 2016 (has links) abstract: The state of the solar industry has reached a point where significant advancements in efficiency will require new materials and device concepts. The material class broadly known as the III-N's have a rich history as a commercially successful semiconductor. Since discovery in 2003 these materials have shown promise for the field of photovoltaic solar technologies. However, inherent material issues in crystal growth and the subsequent effects on device performance have hindered their development. This thesis explores new growth techniques for III-N materials in tandem with new device concepts that will either work around the previous hindrances or open pathways to device technologies with higher theoretical limits than much of current photovoltaics. These include a novel crystal growth reactor, efforts in production of better quality material at faster rates, and development of advanced photovoltaic devices: an inversion junction solar cell, material work for hot carrier solar cell, ground work for a selective carrier contact, and finally a refractory solar cell for operation at several hundred degrees Celsius. / Dissertation/Thesis / Doctoral Dissertation Materials Science and Engineering 2016 Materials Science Electrical engineering crystal growth Gallium nitride Indium gallium nitride molecular beam epitaxy photovoltaics solar cells
17	Relaxação do spin em poços quânticos de InGaAs/GaAs dopados com Mn / Spin relaxation of electrons in InGaAs/GaAs quantum wells Mn-doped barriers González Balanta, Miguel Ángel, 1985- 17 August 2018 (has links) Orientador: Maria José Santos Pompeu Brasil / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física "Gleb Wataghin" / Made available in DSpace on 2018-08-17T05:37:13Z (GMT). No. of bitstreams: 1 GonzalezBalanta_MiguelAngel_M.pdf: 3522641 bytes, checksum: 4f38baba120bb574a54a03d7c1ebc335 (MD5) Previous issue date: 2010 / Resumo: Nesta dissertação investigamos os efeitos dos íons de Mn na dinâmica do spin de elétron em poços quânticos de InGaAs/GaAs. Os poços têm um gás de buracos gerado por dopagens em suas barreiras, sendo uma dopagem tipo delta de Mn numa das barreiras e uma dopagem tipo delta de C, na outra. A densidade de buracos foi determinada mediante medidas de transporte e são consistentes com as densidades obtidas das energias de Stokeshift. Utilizamos diversas técnicas ópticas, como a fotoluminescência no modo contínuo (PL-CW) e resolvida no tempo (PL-RT), a fotoluminescência de excitação (PLE-CW), e o efeito Hanle óptico, sempre usando luz circularmente polarizada para excitação e analisando a polarização circular da luz emitida. Comparamos os tempos de vida ( ? ) e de relaxação do spin ( ? s) dos elétrons obtidos através destas técnicas e discutimos as diferenças intrínsecas destes métodos e o significado físico dos parâmetros fornecidos por eles. Analisamos também o efeito da presença dos íons de Mn, que são íons magnéticos, sobre os tempos vida e de spin dos elétrons em uma série de amostras com diferentes quantidades de Mn incluindo a amostra de referencia sem Mn. Os resultados encontrados revelam um limite para a concentração de Mn, para a qual ambos, ? e ? s, apresentam uma queda abruta. Surpreendentemente, esta queda não afeita o grau de polarização CW, pois a razão ?/? s que determina este parâmetro permanece basicamente constante para todas as amostras / Abstract: We have studied the effect of Mn ions on the spin-relaxation of electrons in a InGaAs/GaAs quantum well (QW). The QW has a two-dimensional hole-gas generated by doping the barriers, whereas one of the barriers has a Mn-planar layer and the other one, a C planarlayer. The hole densities were determined by Shubnikov-de-Haas oscillations and are consistent with the Stokes-shift energies obtained by optical measurements. We have performed continuouswave photoluminescence measurements (CW-PL), excitation photoluminescence (CW-PLE), timeresolved (TR-PL), and Hanle effect with circularly polarized excitation and detection. We compare the lifetime ( ? ) and the spin relaxation time ( ? s) obtained using those techniques and we discuss the differences between the various techniques and the physical meaning of those parameters. We also analyze the effect of Mn ions on ? s and ? for the series of samples with different Mn concentrations, including a reference sample with no Mn doping. The results revealed a threshold of Mn concentration at which both, and ? s, show a strong and abrupt fall. Surprisingly, this fall does not affect the CW effective polarization degree, since the ratio s that determines this parameter remains basically constant for all samples / Mestrado / Física da Matéria Condensada / Mestre em Física Spintrônica Semicondutores Poços quânticos Manganês Arsenieto de gálio-índio Arsenieto de gálio Spintronics Semiconductors Quantum wells Manganese Indium gallium arsenide Gallium arsenide
18	Materials Engineering and Control for Advancing High-Efficiency CdSe/CdTe Solar Cells Jamarkattel, Manoj K. 15 June 2023 (has links) No description available. Physics material science thinfilm solarcells sputtering CSS CdTe defects emitter layer Indium Gallium Oxide light soaking carrier recombination device efficiency
19	Amorphous oxide semiconductors in circuit applications McFarlane, Brian Ross 24 September 2008 (has links) The focus of this thesis is the investigation of thin-film transistors (TFTs) based on amorphous oxide semiconductors (AOSs) in two circuit applications. To date, circuits implemented with AOS-based TFTs have been primarily enhancement-enhancement inverters, ring oscillators based on these inverters operating at peak frequencies up to ~400 kHz, and two-transistor one-capacitor pixel driving circuits for use with organic light-emitting diodes (OLEDS). The first application investigated herein is AC/DC rectification using two circuit configurations based on staggered bottom-gate TFTs employing indium gallium oxide (IGO) as the active channel layer; a traditional full bridge rectifier with diode-tied transistors and a cross-tied full-wave rectifier are demonstrated, which is analogous to what has been reported previously using p-type organic TFTs. Both circuit configurations are found to operate successfully up to at least 20 MHz; this is believed to be the highest reported operating frequency to date for circuits based on amorphous oxide semiconductors. Output voltages at one megahertz are 9 V and ~10.5 V, respectively, when driven with a differential 7.07 Vrms sine wave. This performance is superior to that of previously reported organic-based rectifiers. The second AOS-based TFT circuit application investigated is an enhancement-depletion (E-D) inverter based on heterogeneous channel materials. Simulation results using models based on a depletion-mode indium zinc oxide (IZO) TFT and an enhancement-mode IGO TFT result in a gain of ~15. Gains of other oxide-based inverters have been limited to less than 2; the large gain of the E-D inverter makes it well suited for digital logic applications. Deposition parameters for the IGO and IZO active layers are optimized to match the models used in simulation by fabricating TFTs on thermally oxidized silicon and patterned via shadow masks. Integrated IGO-based TFTs exhibit a similar turn-on voltage and decreased mobility compared to the shadow masked TFTs. However, the integrated IZO-based TFTs fabricated to date are found to be conductive and exhibit no gate modulation. Due to the conductive nature of the load, the fabricated E-D inverter shows no significant output voltage variation. This discrepancy in performance between the integrated and shadow-masked IZO devices is attributed to processing complications. / Graduation date: 2009 amorphous oxide semiconductors thin-film transistors oxide electronics RFID Indium Gallium Oxide (IGO) Thin film transistors Amorphous semiconductors Metal oxide semiconductors
20	Optoelectronic simulation of nonhomogeneous solar cells Anderson, Tom Harper January 2016 (has links) This thesis investigates the possibility of enhancing the efficiency of thin film solar cells by including periodic material nonhomogeneities in combination with periodically corrugated back reflectors. Two different types of solar cell are investigated; p-i-n junctions solar cells made from alloys of hydrogenated amorphous silicon (a-Si:H) (containing either carbon or germanium), and Schottky barrier junction solar cells made from alloys of indium gallium nitride (InξGa1-ξN). Material nonhomogeneities are produced by varying the fractions of the constituent elements of the alloys. For example, by varying the content of carbon or germanium in the a-Si:H alloys, semiconductors with bandgaps ranging from 1:3 eV to 1:95 eV can be produced. Changing the bandgap alters both the optical and electrical properties of the material so this necessitates the use of coupled optical and electrical models. To date, the majority of solar cell simulations either prioritise the electrical portion of the simulation or they prioritise the optical portion of the simulation. In this thesis, a coupled optoelectronic model, developed using COMSOL Multiphysics®, was used to simulate solar cells: a two-dimensional finite-element optical model, which solved Maxwell's equations throughout the solar cells, was used to calculate the absorption of incident sunlight; and a finite-element electrical drift-diffusion transport model, either one- or two-dimensional depending on the symmetries of the problem, was used to calculate the steady state current densities throughout the solar cells under external voltage biases. It is shown that a periodically corrugated back reflector made from silver can increase efficiency of an a-Si:H alloy single p-i-n junction solar cell by 9:9% compared to a baseline design, while for a triple junction the improvement is a relatively meagre 1:8%. It is subsequently shown that the efficiency of these single p-i-n junction solar cells with a back reflector can be further increased by the inclusion of material nonhomogeneities, and that increasing the nonhomogeneity progressively increases efficiency, especially in thicker solar cells. In the case of InξGa1-ξN Schottky barrier junction solar cells, the gains are shown to be even greater. An overall increase in efficiency of up to 26:8% over a baseline design is reported.

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