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    <title>DSpace Collection:</title>
    <link>http://ir.mu.ac.ke:8080/jspui/handle/123456789/61</link>
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        <rdf:li rdf:resource="http://ir.mu.ac.ke:8080/jspui/handle/123456789/10353" />
        <rdf:li rdf:resource="http://ir.mu.ac.ke:8080/jspui/handle/123456789/10348" />
        <rdf:li rdf:resource="http://ir.mu.ac.ke:8080/jspui/handle/123456789/10343" />
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    <dc:date>2026-07-16T17:49:39Z</dc:date>
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  <item rdf:about="http://ir.mu.ac.ke:8080/jspui/handle/123456789/10353">
    <title>Techno-economic analysis of local manufacturing of perovskite photovoltaic modules for electricity generation in Ethiopia</title>
    <link>http://ir.mu.ac.ke:8080/jspui/handle/123456789/10353</link>
    <description>Title: Techno-economic analysis of local manufacturing of perovskite photovoltaic modules for electricity generation in Ethiopia
Authors: Meheretu, Getnet; Worku, Ababay Ketema; Yihunie, Moges T.; Koech, Richard K; Wubetu, Getasew A
Abstract: Perovskite solar cells can be potential contenders for future photovoltaic technologies due to their high efficiency, affordability, and simple manufacturing process. This study focuses on the techno-economic analysis of local manufacturing of perovskite solar panels in Ethiopia. The total manufacturing costs were found to be $0.29 /wp or $/69.6/m2. The Minimum Sustainable Price was calculated to be $0.38 /wp or $91.2/m2. Using a Monte Carlo simulation, the techno-economic metrics such as Net Present Value, Pay Back Period, Rate of Return, Profitability Index, and Levelized Cost of Energy were evaluated to determine project viability. The analysis showed a positive Net Present Value, a Payback Period of 7 to 8 years, an Internal Rate of Return of about 12 % with its average rate of return greater than the weighted average cost of capital, and a profitability index of 1.22, indicating project viability. The levelized cost of energy was estimated to be $0.019/kWh, which is lower than the selling price of electricity by the Ethiopian electric power authority, suggesting economic viability.</description>
    <dc:date>2025-10-01T00:00:00Z</dc:date>
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  <item rdf:about="http://ir.mu.ac.ke:8080/jspui/handle/123456789/10348">
    <title>Enhancing stability and efficiency in perovskite solar cells: insights into inorganic HTL deposition and interface defect passivation</title>
    <link>http://ir.mu.ac.ke:8080/jspui/handle/123456789/10348</link>
    <description>Title: Enhancing stability and efficiency in perovskite solar cells: insights into inorganic HTL deposition and interface defect passivation
Authors: Amune, Daniel I.; Koech, Richard; Dahiru, Muhammad Sanni; Botsoa, J.; Anye, Vitalis Chioh; Fidel, W.
Abstract: The perovskite solar cell (PSC) as an emerging and promising type of solar cell has been extensively studied, but instability is still a major challenge. Replacing the hygroscopic organic hole transport layer (HTL) in PSCs can result in an improvement in the device stability. However, it is still difficult to deposit inorganic HTLs onto the underlying perovskite layer without eroding or distorting it in the regular n–i–p architecture, thereby inducing defects at the interface and reducing the performance of the device. In this study, the performance of PSCs with an inorganic HTL is modelled using SCAPS-1D. The perovskite-HTL interface defect density was varied from 1.0 × 1012 to 1.0 × 1020 cm−3. We realized that, for PSCs based on some hole transport materials (HTMs), the effect of interface defect density was not significant. We observed that the HTL/perovskite valence band offset (VBO) plays a significant role in the phenomenon observed. In particular, a zero or slightly positive VBO results in an increase in both the defect tolerance and device efficiency. This information provides insights into the fabrication of PSCs with improved interface defect passivation and also enables the fabrication of perovskite solar cells based on physically deposited inorganic charge transport materials.</description>
    <dc:date>2026-03-01T00:00:00Z</dc:date>
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  <item rdf:about="http://ir.mu.ac.ke:8080/jspui/handle/123456789/10343">
    <title>Mathematical modeling of the amplitude dynamics of saturated sludge in a landslide wave surge</title>
    <link>http://ir.mu.ac.ke:8080/jspui/handle/123456789/10343</link>
    <description>Title: Mathematical modeling of the amplitude dynamics of saturated sludge in a landslide wave surge
Authors: Karugutiang, David Pkiach; Kweyu, Cleophas; Kaneba, Christopher
Abstract: Mathematical model is formulated using Partial differential equations, and analyzed to describe the dynamics of wave propagation with application to landslide. Its occurrence leads to loss of lives of people and their properties. This study aims at understanding the dynamics of landslide wave propagation, in order to make adequate projection in an attempt to mitigate the risks involved in the occurrence. The objective of this study is; to develop a mathematical model to describe the dynamics of a landslide wave propagation. Numerical solutions were carried out using Runge-Kutta algorithm’s inbuilt in MATLAB, to simulate the current and future dynamics of the model. The mathematical model was used to simulate and analyze landslide wave propagation phenomena in affected areas. The results of this study showed that the maximum amplitude of 0.49m is achieved at an inclination of 50° and gradually drops down to 0.45m at a slope of 19.2°. This defines the region where inhabitants should be relocated to avoid loss of lives and destruction of property during the occurrence of landslide. The high amplitude occurs in the wave propagation region, necessitating the implementation of control strategies along the same region.</description>
    <dc:date>2026-04-01T00:00:00Z</dc:date>
  </item>
  <item rdf:about="http://ir.mu.ac.ke:8080/jspui/handle/123456789/10342">
    <title>Mathematical modeling of the amplitude of saturated soil densities on field deformation</title>
    <link>http://ir.mu.ac.ke:8080/jspui/handle/123456789/10342</link>
    <description>Title: Mathematical modeling of the amplitude of saturated soil densities on field deformation
Authors: Karugutiang, David Pkiach; Kweyu, Cleophas; Kaneba, Christopher
Abstract: Landslide-induced surge waves pose significant threats to infrastructure, ecosystems, and human life in mountainous regions characterized by heavy rainfall and terrain instability. This study aims to develop a mathematical model using soil with different densities to generate varying-amplitude waves that describe the dynamics of landslide wave propagation, providing an adequate basis for mitigating the risk of landslides. The objective of this study is to develop a mathematical model to describe the dynamics of a landslide wave propagation. Experimental data are computed using the Runge-Kutta method built into MATLAB to simulate the model's current and future dynamics. The mathematical model is used to simulate and analyze landslide wave propagation phenomena in affected areas. Experimentation results showed that different soil densities generated a maximum amplitude of 0.86m at an incline angle of 500 with other decline angles like 33.20, and 24.20 that gradually decayed to 0. 45m at the far field with a slope of 19.20. These results showed precise prediction of amplitude waves at different zones on the landscape, thereby providing a reliable framework for understanding landslide surge mechanics, recommending its use in early warning systems, infrastructure planning, and necessitating the implementation of control strategies along the same region.</description>
    <dc:date>2026-05-01T00:00:00Z</dc:date>
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