Theses and Dissertations from UMD

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New submissions to the thesis/dissertation collections are added automatically as they are received from the Graduate School. Currently, the Graduate School deposits all theses and dissertations from a given semester after the official graduation date. This means that there may be up to a 4 month delay in the appearance of a give thesis/dissertation in DRUM

More information is available at Theses and Dissertations at University of Maryland Libraries.

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Author: search.filters.author.Khan, Muhammad Raziuddin A.Subject: search.filters.subject.Electrical engineering

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    DEVELOPMENT OF GALLIUM NITRIDE AND INDIUM GALLIUM PHOSPHIDE BETAVOLTAIC AND ALPHAVOLTAIC DEVICES FOR CONTINUOUS POWER GENERATION
    (2023) Khan, Muhammad Raziuddin A.; Iliadis, Agis; Electrical Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Betavoltaic devices are p-n/p-i-n junction diodes that use the kinetic energy of beta (electron) particles emitted by beta isotopes to create electron-hole pairs and generate electrical power in a similar way as photovoltaic devices use photons energy to generate electrical power. Unlike photovoltaic devices (solar cells), betavoltaic devices can generate electrical power day and night continuously for decades (12 years with 3H (tritium) and 100 years with Ni63 (nickel-63)), enabling new capabilities that are not possible with photovoltaic devices or current state of the art chemical batteries. New capabilities include decade-long continuous power for unattended sensor, tagging/tracking devices, and other electronics placed in remote areas (underwater, polar region, space, etc) where change/charge of batteries is highly inconvenient or impossible. It is expected that wide band gap semiconductors like GaN with an energy gap of 3.4 eV may provide a better performance in terms of output power and stability under beta radiations. However, GaN semiconductor technology is still maturing in terms of growth and fabrication techniques. InGaP has a moderately wide bandgap of 1.86 eV, but it is well advanced in terms of crystal growth and fabrication techniques. Therefore, our study and research focused on the development (design, fabrication, evaluation) and comparison of a wide band gap (GaN) and a moderately high band gap InGaP, that are considered very promising in betavoltaic applications. Betavoltaic devices were fabricated on three GaN p-i-n structures with different i-layer thicknesses (600 nm, 700 nm and 1 µm). Two GaN p-i-n structures were grown on top of a sapphire substrate and the third GaN structure was grown on top of a bulk GaN substrate. InGaP devices were fabricated on an InGaP n-i-p structure grown on top of a gallium arsenide (GaAs) substrate. Devices were characterized using current - voltage (IV) measurements in the dark, using a UV light source, and under an electron beam stimulus to mimic their performance under real beta isotopes. Dark IV measurements confirmed good quality diodes with low leakage currents, and IV curves under the UV light (365nm, 3.40 eV) source showed a clear photo-response. IV curves under the electron beam irradiation at 16 KeV (average energy emission of Ni63 beta source at 250 mCi/cm2) resulted in the output powers of 3.01 µW/cm2 with an efficiency of 12.63 % for the InGaP device, and 3.32 µW/cm2 with an efficiency of 13.2% for the GaN device. InGaP and GaN devices were also exposed under a 4.5 MeV alpha beam to determine their suitability for an alphavoltaic power source (Direct energy conversion). Both InGaP and GaN devices showed degradation in their MPPs under the direct alpha beam exposure. We also investigated an indirect alpha-photovoltaic (APV) power source by employing ZnS phosphor as an intermediate layer to limit this degradation. This ZnS layer absorbs all the alpha energy and converts it into photons to create EHPs in the semiconductor device to generate electrical output power via indirect energy conversion. We determined that even though APV approach prevented radiation damage in the semiconductor device but the degradation rate of ZnS phosphor is faster compared to the degradation rate of GaN and InGaP devices under direct alpha beam exposure.
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    Design and Characterization of p-i-n Devices for Betavoltaic Microbatteries on Gallium Nitride
    (2015) Khan, Muhammad Raziuddin A.; Iliadis, Agis A.; Electrical Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Betavoltaic microbatteries convert nuclear energy released as beta particles directly into electrical energy. These batteries are well suited for electrical applications such as micro-electro-mechanical systems (MEMS), implantable medical devices and sensors. Such devices are often located in hard to access places where long life, micro-size and lightweight are required. The working principle of a betavoltaic device is similar to a photovoltaic device; they differ only in that the electron hole pairs (EHPs) are generated in the device by electrons instead of photons. In this study, the performance of a betavoltaic device fabricated from gallium nitride (GaN) is investigated for beta particle energies equivalent to Tritium (3H) and Nickel-63 (N63) beta sources. GaN is an attractive choice for fabricating betavoltaic devices due to its wide band gap and radiation resistance. Another advantage GaN has is that it can be alloyed with aluminum (Al) to further increase the bandgap, resulting in a higher output power and increased efficiency. Betavoltaic devices were fabricated on p-i-n GaN structures grown by metalorganic chemical vapor deposition (MOCVD). The devices were characterized using current - voltage (IV) measurements without illumination (light or beta), using a laser driven light source, and under an electron beam. Dark IV measurements showed a turn on-voltage of ~ 3.4 V, specific-on-resistance of 15.1 m Ω-cm2, and a leakage current of 0.5 mA at – 10 V. A clear photo-response was observed when IV curves were measured for these devices under a light source at a wavelength of 310 nm (4.0 eV). These devices were tested under an electron beam in order to evaluate their behavior as betavoltaic microbatteries without using radioactive materials. Output power of 70 nW and 640 nW with overall efficiencies of 1.2% and 4.0% were determined at the average energy emission of 3H (5.6 keV) and 63N (17 keV) respectively.