Theses

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A long essay or dissertation or thesis involving personal research, written by postgraduates of University of Ghana for a university degree.

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    Mechanical measurements of pure and kaolin reinforced hydroxyapatite-derived scaffolds: A comparative study
    (Materials Today: Proceedings, 2020) Obada, D.O.; Dodoo-Arhin, D.; Dauda, E.T.; et al.
    This study describes the mechanical properties of pure hydroxyapatite (HAp) and kaolin-reinforced hydroxyapatite (K-HAp) is produced from non-separated animal bones using compression pressure under different sintering regimes. The HAp microparticles were synthesized separately using a facile heat treatment method and reinforced with 15 wt% of beneficiated kaolin (HAp/15 wt% BK) using the sol-gel method. The HAp and K-HAp-derived scaffolds were fabricated by cold pressing with a compaction pressure of 500 Pa. Next, the scaffolds were sintered at 900 C, 1000 C, and 1100 C with a 2 h dwell time in the air atmosphere. Subsequently, the mechanical properties of the scaffolds were examined. The effect of sintering temperature and compaction pressure on the hardness and the compressive strength of the pure and reinforced HAp showed that at all points of measurement (with and without compaction pressure), the mechanical properties increased with an increase in sintering temperature, and the most significant mechanical properties were obtained at 1100 C. The values of hardness at the maximum sintering temperature (1100 C) are 0.93 and 1.09 GPa with and without the application of compaction pressure, respectively, for pure HAp-derived scaffolds and 0.74 and 0.78 GPa with and without the application of compaction pressure, for K-HAp-derived scaffolds. The compressive strength for K HAp had the value of 7.84 MPa as compared with 0.69 MPa for the non-reinforced HAp matrix with the application of compaction pressure (500 Pa). The findings show that the mechanical properties of the synthesized kaolin-reinforced HAp about the scaffolds produced with the low compaction pressure of 500 Pa are suitable for human trabecular bone. 2020 The Authors. Published by Elsevier Ltd. This is an open-access article under the CC BY-NC-ND license (https://creativecommons.org/licenses/by nc-and/4.0) Selection and Review under the responsibility of the scientific committee of the International. Conference & Exposition on Mechanical, Material, and Manufacturing Technology.
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    Potentials of fabricating porous ceramic bodies from kaolin for catalytic substrate applications
    (Applied Clay Science, 2016) Obada, D.O.; Dodoo-Arhin, D.; Dauda, M.; et al.
    In this work, the suitability of using kaolin–styrofoam, sawdust, and high-density polyethylene to produce porous ceramic bodies was experimentally investigated. The kaolin samples (raw and beneficiated) were characterized by the XRD, SEM, TGA/DSC, and FTIR methods. Batch formulations of the samples including the kaolin and pore formers were formed into green bodies and fired to 1150 °C. The porosities of sintered bodies were calculated and given the following: apparent porosity: 28.63%–67.13% for all the samples investigated. Samples with high-density polyethylene (HDPE) pore formers showed minor surface cracks after firing but exhibited the highest porosity levels while samples with styrofoam and saw dust exhibited uniform surface characteristics with pores, thermal stability, and no visible surface cracks. It can be concluded that formulations containing 80% kaolin can be used for the production of ceramics with porosities as high as 67% if the right pore formers are used.