Global ETD Search

161	Understanding of correlation between size and coloration of Copper Gallium Oxide and its application in perovskite solar cell Yu, Yongze, Yu January 2016 (has links) No description available. Chemistry
162	Fabrication of Metal Halide Perovskites via Mist Deposition Method for Solar Cells and X-Ray Detection Applications / ミストデポジション法による金属ハライドペロブスカイトの作製とその太陽電池およびX線検出器への応用 Haruta, Yuki 23 March 2022 (has links) 京都大学 / 新制・課程博士 / 博士(エネルギー科学) / 甲第24010号 / エネ博第446号 / 新制\|\|エネ\|\|84(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー応用科学専攻 / (主査)教授平藤哲司, 教授土井俊哉, 教授藤本仁 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DFAM Perovskites Mist Deposition Solar cell X-ray detection Semiconductor 501
163	Antimony Chalcogenide: Promising Material for Photovoltaics Rijal, Suman 15 September 2022 (has links) No description available. Physics
164	GaInN/GaN Schottky Barrier Solar Cells Chern, Kevin Tsun-Jen 02 June 2015 (has links) GaInN has the potential to revolutionize the solar cell industry, enabling higher efficiency solar cells with its wide bandgap range spanning the entire solar spectrum. However, material quality issues stemming from the large lattice mismatch between its binary endpoints and questionable range of p-type doping has thus far prevented realization of high efficiency solar cells. Nonetheless, amorphous and multi-crystalline forms of GaInN have been theorized to exhibit a defect-free bandgap, enabling GaInN alloys at any indium composition to be realized. But the range of possible p-type doping has not yet been determined and no device quality material has been demonstrated thus far. Nonetheless, a Schottky barrier design (to bypass the p-type doping issue) on single-crystal GaInN can be used to provide some insight into the future of amorphous and micro-crystalline GaInN Schottky barrier solar cells. Through demonstration of a functional single crystalline GaInN Schottky barrier solar cell and comparison of the results to the best published reports for more conventional p-i-n GaInN solar cells, this work aims to establish the feasibility of amorphous and multi-crystalline GaInN solar cells. / Ph. D. GaInN Semiconductor Solar Cell Schottky Diode Transparent Conducting Oxide
165	Impact of Electrical Contacting Scheme on Performance of InGaN/GaN Schottky Solar Cells Jain, Aditya 18 September 2014 (has links) Realization of low-resistance electrical contacts on both sides of a solar cell is essential for obtaining the best possible performance. A key component of a solar cell is a metal contact on the illuminated side of the cell which should efficiently collect carriers. These contacts can be formed using an opaque metal grid/finger pattern. The metal electrode may be used alone or in combination with a broad-area transparent conductive film. This work aims at investigating the impact of the electrical contacting scheme employed in InGaN/GaN Schottky barrier solar cells on their performance. InGaN is a III-V compound semiconductor and has a tunable direct band-gap (0.7 eV to 3.4 eV) which spans most of the solar spectrum; this fact, along with other beneficial material properties, motivates the study of InGaN photovoltaic devices. A number of groups have recently investigated InGaN-based homo-junction and hetero-junction p-i-n solar cells. However, very few groups have worked on InGaN Schottky solar cells. Compared to p-n junctions, Schottky barrier solar cells are cheaper to grow and fabricate; they are also expected to improve the spectral response because of near surface depletion regions in the shorter wavelength regions. In this particular work on InGaN based solar cells, a Schottky diode structure was used to avoid the issue of highly resistive p-type InGaN. In this study, platinum (Pt) is used to form a Schottky barrier with an InGaN/GaN absorber region. Electrical and optical properties of platinum films are investigated as a function of their thickness. InGaN/GaN Schottky solar cells with platinum as the transparent conductive film are reported and their performance is evaluated as a function of the metal thickness. / Master of Science Transparent conductive layer Schottky solar cell Device characterization
166	Design of III-V Multijunction Solar Cells on Silicon Substrate Jain, Nikhil 11 June 2013 (has links) With looming energy crisis across the globe, achieving high efficiency and low cost solar cells have long been the key objective for photovoltaic researchers. III-V compound semiconductor based multijunction solar cells have been the dominant choice for space power due to their superior performance compared to any other existing solar cell technologies. In spite of unmatched performance of III-V solar cells, Si cells have dominated the terrestrial market due to their lower cost. Most of the current III-V solar cells are grown on Ge or GaAs substrates, which are not only smaller in diameter, but are also more expensive than Si substrate. Direct integration of high efficiency III-V solar cells on larger diameter, cheaper and readily available Si substrate is highly desirable for increased density, low-cost and lightweight photovoltaics. However, the polar-on-nonpolar epitaxy, the thermal mismatch and the 4% lattice mismatch makes the direct growth of GaAs on Si challenging, rendering the metamorphic cell sensitive to dislocations. The focus of this work is to investigate and correlate the impact of threading dislocation density on the performance of lattice-mismatched single-junction (1J) GaAs and dual-junction (2J) InGaP/GaAs solar cells on Si substrate. Utilizing our calibrated dislocation-assisted modeling process, we present the design methodology to optimize the structure of 2J InGaP/GaAs solar cell on Si substrate. Our modeling results suggest an optimistic future for integrating III-V solar cell technology on Si substrate and will be useful for future design and prediction of metamorphic III-V solar cell performance on Si substrate. / Master of Science III-V Semiconductors Multijunction Solar Cells Solar Cell Modeling
167	Measurement Of Solar Cell Parameters Using Time Domain Technique Desmukh, Makarand P 01 1900 (has links) (PDF) No description available. Solar Cells Time Domain Studies Solar Cell Parameters Tlme Domain Technique Solar Cell AC Parameters Heat Engineering
168	A Model of the Dye-Sensitized Solar Cell: Solution Via Matched Asymptotic Expansion Gassama, Edrissa 16 September 2014 (has links) No description available. Alternative Energy Applied Mathematics Energy solar cell dye sensitized titanium dioxide solar cell semiconductor boundary layer techniques matched asymptotic expansion
169	Fabrication and Characterization of a Wrinkled Polydimethylsiloxane Thin Film Bilayer System Ingale, Himanshu A. January 2017 (has links) No description available. Engineering Thin film solar cell Surface wrinkling Nano-indentation Elastic moduli of thin films Optical modeling of solar cell Light trapping
170	Series interconnects and charge extraction interfaces for hybrid solar cells Hey, Andrew Stuart January 2013 (has links) This thesis investigates novel hole extraction interfaces and series interconnects for applications in organic photovoltaics, specifically in single junction solid-state dye-sensitized solar cells (DSSCs) and tandem DSSC/polymer bulk heterojunction solar cells. Improvements in hole extraction and device performance by using materials compatible with scalable deposition methods are presented, including tungsten- and molybdenum-disulphide (WS<sub>2</sub> and MoS<sub>2</sub>), and p-type doped spiro-OMeTAD (2,2',7,7'-tetrakis-(N,N-di-p-methoxyphenylamine)9,9'-spirobifluorene) nanoparticle dispersions. WS<sub>2</sub> and MoS<sub>2</sub> hole extraction layers increase averaged short circuit currents by 20% and 16% respectively, and power conversion efficiencies by 19% and 14% respectively when compared with control devices. Similarly, doped spiro-OMeTAD nano-particle layers improved short circuit current densities by 32% and efficiencies by 9%. Tandem device interconnects using these novel hole extraction formats have been fabricated, but although devices did exhibit rectification, overall performance was poor. Possible reasons for their limited success have been analysed. Dye-sensitized solar mini-modules are also reported. In order to assure the scalability of DSSC technology, these larger area devices were constructed using doctor blade coating to deposit the hole transporter material. As well as achieving a respectable maximum power conversion efficiency of 2.6%, it has also been shown that the extent to which hole transporter infiltrates the mesoporous photoanode of these devices may be tuned by altering substrate temperature during deposition. It was found that an optimal coating temperature of 70 degrees C produced the best efficiency, with a corresponding pore-filling fraction of 41%. 621.31244

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