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CO2 captu Apply for this job See advertisement This is NTNU NTNU is a broad-based university with a technical-scientific profile and a focus in professional education. The university is located in three
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functioning; ii) CO2 and CH4, chiefly influencing coastal gas emissions and altering coastal carbonate chemistry; and iii) Black or Pyrogenic Carbon, produced by the incomplete combustion of biomass and fossil
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details can be found at https://www.net-zero-fibe-cdt.eng.cam.ac.uk/ The project is funded in collaboration with Ramboll and Buro Happold who work across diverse projects with key clients focused
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. Multiphysics modelling of electrochemistry: connecting nanoscale electrochemical phenomena to whole device behaviour. Publications from Prof Unwin and Prof Macpherson (google scholar): https
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in sustainable technologies, such as water- and CO2-electrolyzers, as well as fuel cells. Your main responsibilities include: Synthesis and characterization of catalyst particles for electrochemical
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with engineered redox enzymes. The nanoscale confinement provided by the viral capsid will facilitate electron flux between PSI and the redox enzymes and thermodynamically drive efficient reduction of CO2
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structure on small scales, ranging from the micrometer to the nanometer scale. The investigated materials and systems play a crucial role in sustainable technologies, such as water- and CO2-electrolyzers, as
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and carbon dioxide (CO2) storage. This PhD project aims to address the issue of mineralization in the context of geological CO2 storage by leveraging cutting-edge experimental tools like micromodels
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of greenhouse gases including CO2 and CH4. The PhD project is part of the Horizon Europe Marie Sklodowska-Curie Action (MSCA) doctoral network (DN) ELEGANCE (machinE LEarning for inteGrated multi-parAmetric
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well as in the breakdown of greenhouse gases including CO2 and CH4 . The PhD project is part of the Horizon Europe Marie Skłodowska-Curie Action (MSCA) doctoral network (DN) ELEGANCE (machinE LEarning