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Antunes IV - Work Plan / Goals to be achieved: Support for Activities 2 and 3 of the Olivaqua project. Study of the interaction mechanisms between phenolic compounds and adsorbent materials Development of a
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cycling. The successful candidate will have the opportunity to work with existing datasets on (ground-, soil-)water chemistry and carbon in cold climate zones (e.g. permafrost regions in Finnmark) and to
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development of blood malignancies and other solid cancers. Our research bridges basic, translational, and clinical studies to uncover mechanisms linking inflammation, DNA damage, and stem cell aging to cancer
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exploration across controlled data-generating processes, explicitly designed to probe the assumptions underlying common unsupervised workflows. This exploration will include synthetic settings with known ground
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investigate molecular mechanisms that regulate heat stress memory, which is a vital mechanism for plant resilience. The aim is to understand the role of naturally occurring short tandem repeat polymorphisms in
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solid oxide fuel cells. The project will span length scales, from materials discovery, including with computational approaches, through mechanical properties and microstructure optimisation
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on (ground-, soil-)water chemistry and carbon in cold climate zones (e.g. permafrost regions in Finnmark) and to expand hydrogeological observations during upcoming field campaigns. Potential methods include
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hot-melt extrusion formulations and selecting optimal operating conditions using rheology, with the objective of producing amorphous-solid-dispersions. You will validate the developed processing space
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solid oxide fuel cells. The project will span length scales, from materials discovery, including with computational approaches, through mechanical properties and microstructure optimisation
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engineering, and develop an individual research strategy and profile in icing science and engineering. About You You will hold a PhD (or close to completion) in aerospace engineering, mechanical engineering, or