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on autogenous grinding as a low-energy alternative for liberating indurated phosphates stored in mining waste deposits (MATs). This project integrates mineralogical and mechanical characterization, pilot-scale
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motivated candidate with a PhD from a recognized University who is passionate about developing innovations that have direct impacts on farmers in arid lands. The candidate will participate in evaluating plant
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to scientific publications and project reporting Candidate Profile PhD in electrochemistry, chemical engineering, materials science, or a related field. Hands-on experience with electrodialysis, electrochemical
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coatings, to protect the LFP particles while optimizing their performance in high-energy-density applications. The coated LFP materials should exhibit superior mechanical and chemical resilience, ensuring
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into the fundamental reaction mechanisms and kinetics involved. Investigate thermodynamics-electrode/electrolyte interfacial structure-property relationships to gain deeper insights into material behavior. Develop
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candidate will be expected to: Design and implement advanced decision-making model for mining activity planning, considering field constraints and performance objectives. Propose mechanisms for dynamically
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-renowned universities in its fields. The University is engaged in economic and human development and puts research and innovation at the forefront of African development. A mechanism that enables it to
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work on include: Design and synthesize novel inorganic electrode/electrolyte materials, and search into the fundamental reaction mechanisms and kinetics involved. Investigate thermodynamics-electrode
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synthesis and characterization with a PhD and demonstrated experience in Materials Science, Materials Chemistry, Inorganic chemistry, catalysis, and related disciplines. The candidate should also have
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, FactSage) to simulate vanadium phase behavior and guide process improvements. Performing advanced characterization of vanadium-bearing materials to understand their transformation and recovery mechanisms