Electronic Theses and Dissertations (Masters)

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Browsing Electronic Theses and Dissertations (Masters) by SDG "SDG-7: Affordable and clean energy"

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    Solar cell simulation using ab initio methods
    (University of the Witwatersrand, Johannesburg, 2024) Zdravkovi´c, Milica; Quand, Alexander; Warmbier, Robert
    Solar cells are a great source of renewable energy, but they are yet to reach their thermodynamic efficiency limits. Common commercial solar cells run at approximately 20% power conversion efficiency, and almost all efficiency loss comes from thermalisation. Ab initio simulations can reduce the need for physical experiments to quantify these losses while also providing insights into the quantum mechanical properties of materials. Note that density functional theory reformulates the expression for the ground state energy of a many particle system such that it is a functional of the electron density, thereby allowing the electronic energy to be solved for numerically. But the underlying mechanism behind thermalisation is the electron-phonon interaction. Using the theory of Green’s functions, the electron-phonon interaction self-energy and charge-carrier life times can be calculated. A method of approximating the charge-carrier lifetimes using the hydrostatic deformation potential interaction, which is only valid for longitudinal acoustic phonons, is presented. Deformation potentials of -10.125eV for Silicon and 18.663eV for Gallium Arsenide, commonly used solar cell materials, are calculated in good agreement with literature. Furthermore, the electron-phonon interaction life- times were calculated to be in the order of 2.0 × 10−15s for Si and 4.0 × 10−16s for GaAs, which could have indications that the optimal thickness of a GaAs absorption layer is much thinner than for Si. Thus the deformation potential method provides a satisfactory approximation for the electron-phonon quasiparticle lifetimes based on ab initio methods
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    The development of a burn-in test station for the ATLAS Tile Calorimeter Low Voltage Power Supplies for phase II upgrades
    (University of the Witwatersrand, Johannesburg, 2022) Lepota, Thabo James; Mellado, Bruce
    It is planned that the High Luminosity (HL) function of the Large Hadron Collider (LHC) will begin operation in 2027 with an integrated luminosity of 4000 fb−1.By using the HL-LHC scientists will be able to investigate new physics beyond the Standard Model (SM), examine electroweak symmetry in more detail, and examine the characteristics of the Higgs boson. The ATLAS Tile Calorimeter’s on and off detector electronics will be completely redesigned during phase II upgrade, run 3. Due to the high radiation levels, trigger rates, and high pile-up conditions associated with the HL-LHC era, it will be necessary to accommodate its acquisition system. The Institute of Collider Particle Physics is responsible for developing and manufacturing over a thousand transformer-coupled buck converters, known as Bricks, for the Low Voltage Power Supply (LVPS) system. The LVPS is critical to the TileCAL on detector electronics as it powers them by converting 200 V high voltage to 10 V. The Bricks are located within the inner barrel, they can only be accessed once a year. If an LVPS box fails, it can be down for up to a year, causing the Front-End electronics it supports to remain offline for the same amount of time. As a result, the Bricks’ reliability is of critical concern that must be addressed throughout their manufacturing process. In addition to the burn-in test station, the Bricks that pass the quality assurance tests are sent to the European Organization for Nuclear Research (CERN), to be installed in the ATLAS detector. In this manuscript, we show how we programmed the Peripheral Interface Controller (PIC) firmware, which is an integral part of the Brick Interface board functionality in the burn-in test station. We further give detail as to how the software framework (LabVIEW) used as a control program was modified and used to operate the burn-in test station during the burn-in process. The purpose of the test results discussed is to demonstrate the burn-in test station is functional according to the preliminary protocols prescribed for Bricks