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Author : Owan Watkins
Release : 2005
Genre : Aluminum foil
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Book Synopsis Characterization of Aluminum Doped Zinc Oxide Thin Films Fabricated Using an Ion-beam Assisted Sputtering Technique by : Owan Watkins
Download or read book Characterization of Aluminum Doped Zinc Oxide Thin Films Fabricated Using an Ion-beam Assisted Sputtering Technique written by Owan Watkins. This book was released on 2005. Available in PDF, EPUB and Kindle. Book excerpt:
Author : Moran Press-Yekymov
Release : 2013
Genre :
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Book Synopsis Characterization of Aluminum Doped Zinc Oxide Thin Films Fabricated by Using Rectangular Filtered Vacuum Arc Deposition on Large Flat Area Glass Substates by : Moran Press-Yekymov
Download or read book Characterization of Aluminum Doped Zinc Oxide Thin Films Fabricated by Using Rectangular Filtered Vacuum Arc Deposition on Large Flat Area Glass Substates written by Moran Press-Yekymov. This book was released on 2013. Available in PDF, EPUB and Kindle. Book excerpt:
Author : Bojanna P. Shantheyanda
Release : 2010
Genre : Aluminum
Kind : eBook
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Book Synopsis Characterization of Aluminum Doped Zinc Oxide Thin Films for Photovoltaic Applications by : Bojanna P. Shantheyanda
Download or read book Characterization of Aluminum Doped Zinc Oxide Thin Films for Photovoltaic Applications written by Bojanna P. Shantheyanda. This book was released on 2010. Available in PDF, EPUB and Kindle. Book excerpt: Growing demand for clean source of energy in the recent years has increased the manufacture of solar cells for converting sun energy directly into electricity. Research has been carried out around the world to make a cheaper and more efficient solar cell technology by employing new architectural designs and developing new materials to serve as light absorbers and charge carriers. Aluminum doped Zinc Oxide thin film, a Transparent conductive Oxides (TCO) is used as a window material in the solar cell these days. Its increased stability in the reduced ambient, less expensive and more abundance make it popular among the other TCO's. It is the aim of this work to obtain a significantly low resistive ZnO:Al thin film with good transparency. Detailed electrical and materials studies is carried out on the film in order to expand knowledge and understanding. RF magnetron sputtering has been carried out at various substrate temperatures using argon, oxygen and hydrogen gases with various ratios to deposit this polycrystalline films on thermally grown SiO2 and glass wafer. The composition of the films has been determined by X-ray Photoelectron Spectroscopy and the identification of phases present have been made using X-ray diffraction experiment. Surface imaging of the film and roughness calculations are carried out using Scanning Electron Microscopy and Atomic Force Microscopy respectively. Determination of resistivity using 4-Probe technique and transparency using UV spectrophotometer were carried out as a part of electrical and optical characterization on the obtained thin film. The deposited thin films were later annealed in vacuum at various high temperatures and the change in material and electrical properties were analyzed.
Author :
Release : 2002
Genre : Chemistry
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Book Synopsis Chemical Abstracts by :
Download or read book Chemical Abstracts written by . This book was released on 2002. Available in PDF, EPUB and Kindle. Book excerpt:
Author : Michelle Anne Myers
Release : 2013
Genre :
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Book Synopsis Processing and Characterization of P-Type Doped Zinc Oxide Thin Films by : Michelle Anne Myers
Download or read book Processing and Characterization of P-Type Doped Zinc Oxide Thin Films written by Michelle Anne Myers. This book was released on 2013. Available in PDF, EPUB and Kindle. Book excerpt: Applications of zinc oxide (ZnO) for optoelectronic devices, including light emitting diodes, semiconductor lasers, and solar cells have not yet been realized due to the lack of high-quality p-type ZnO. In the research presented herein, pulsed laser deposition is employed to grow Ag-doped ZnO thin films, which are characterized in an attempt to understand the ability of Ag to act as a p-type dopant. By correlating the effects of the substrate temperature, oxygen pressure, and laser energy on the electrical and microstructural properties of Ag-doped ZnO films grown on c-cut sapphire substrates, p-type conductivity is achieved under elevated substrate temperatures. Characteristic stacking fault features have been continuously observed by transmission electron microscopy in all of the p-type films. Photoluminescence studies on n-type and p-type Ag-doped ZnO thin films demonstrate the role of stacking faults in determining the conductivity of the films. Exciton emission attributed to basal plane stacking faults suggests that the acceptor impurities are localized nearby the stacking faults in the n-type films. The photoluminescence investigation provides a correlation between microstructural characteristics and electrical properties of Ag- doped ZnO thin films; a link that enables further understanding of the doping nature of Ag impurities in ZnO. Under optimized deposition conditions, various substrates are investigated as potential candidates for ZnO thin film growth, including r -cut sapphire, quartz, and amorphous glass. Electrical results indicated that despite narrow conditions for obtaining p-type conductivity at a given substrate temperature, flexibility in substrate choice enables improved electrical properties. In parallel, N+-ion implantation at elevated temperatures is explored as an alternative approach to achieve p-type ZnO. The ion implantation fluence and temperature have been optimized to achieve p-type conductivity. Transmission electron microscopy reveals that characteristic stacking fault features are present throughout the p-type films, however in n-type N-doped films high-density defect clusters are observed. These results suggest that the temperature under which ion implantation is performed plays a critical role in determining the amount of dynamic defect re- combination that can take place, as well as defect cluster formation processes. Ion implantation at elevated temperatures is shown to be an effective method to introduce increased concentrations of p-type N dopants while reducing the amount of stable post-implantation disorder. Finally, the fabrication and properties of p-type Ag-doped ZnO/n-type ZnO and p-type N-doped ZnO/n-type ZnO thin film junctions were reported. For the N-doped sample, a rectifying behavior was observed in the I-V curve, consistent with N-doped ZnO being p-type and forming a p-n junction. The turn-on voltage of the device was -2.3 V under forward bias. The Ag-doped samples did not result in rectifying behavior as a result of conversion of the p-type layer to n-type behavior under the n- type layer deposition conditions. The systematic studies in this dissertation provide possible routes to grow p-type Ag-doped ZnO films and in-situ thermal activation of N-implanted dopant ions, to overcome the growth temperature limits, and to push one step closer to the future integration of ZnO-based devices. The electronic version of this dissertation is accessible from http://hdl.handle.net/1969.1/149354
