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, our research in mineral processing consists of three pillars: material characterization (mineralogical and particle analyses), unit operations (such as comminution and separation processes) as
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build the sustainable companies and societies of the future. In line with the green transition and the striving for a sustainable supply of critical raw materials, our research in mineral processing
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mineral and metal-bearing raw materials more efficiently and to recycle them in an environmentally friendly way. The Group Geometallurgy and Particle Based Process Modelling is looking for a PhD Student (f
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to mineral dissolution followed by the precipitation of secondary minerals. From a fluid dynamics perspective, the newly formed solids can be regarded as particles suspended within the pore-scale flow
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technical processes of energy and raw material extraction. An important goal is a better understanding of fundamental processes that influence the transport and the accumulation of radiotoxic elements in
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-zero target for 2050. However, injection of CO2 into deep saline aquifers initiate a series of geochemical reactions leading to mineral dissolution followed by the precipitation of secondary minerals
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– Adsorption and reaction of small gaseous non-metal oxides on model mineral particles under light illumination. The position is for four years of doctoral studies, including participation in research and
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chain. Currently this possibility is hindered by the lack of automated end-to-end modelling workflows for risk and sensitivity assessment. Although many steps in the process can be currently automated
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into their conditions of formation. The mineral phases can indeed be used to trace significant geodynamic processes, such as orogenesis, rifting or subduction. In metallic materials, the development of multiple phases is
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coexisting phases, one can model their distribution during magmatic processes, and crucially the locations within pegmatite mineral systems that are predisposed to form lithium mineralisation. We currently