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, to thermoelectric and electronic transport measurements. The project also incorporates a theoretical component, including theoretical predictions of material stability and properties, carried out in collaboration
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transition metal dichalcogenides (TMDs), has gained significant attention over the past few decades for their use in optoelectronics. Despite this interest, the photophysical properties of these materials and
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of their biological counterparts. This project aims to overcome these limitations through a synergistic circuit–device co-design that jointly optimizes both circuit architectures and component properties, ensuring
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chemistry component. Doctoral students are normally engaged for some teaching at undergraduate and graduate level. Previous experience from teaching/mentoring, even from environments outside the school
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fundamental design principles for next-generation sustainable catalytic systems. The outcomes will contribute to developing green synthetic methodologies that replace rare-metal catalysts, enhance reaction
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rare earth elements, as well as synthesis and characterization of new magnetic materials. The work is supervised by Professor Martin Sahlberg within the Inorganic Chemistry research program at