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, University of Groningen (UG)). Two PhD positions are available, one at each institute. The UG candidate will utilize newly developed microscopy methods, including Förster resonance energy transfer-fluorescence
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of energy demand within residential and commercial sectors, models of renewable energy sources, models of energy networks including electricity, heat and gas. On the algorithms side, the management algorithms
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transition. We use a multidisciplinary approach applicable on two key areas, solar fuels for the conversion and storage of renewable energy and nuclear fusion – as a clean source of energy. Additional
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validation of innovative solutions aimed at addressing the challenges posed by increasing renewable energy integration and electrification of various sectors. Key Responsibilities: Conduct comprehensive grid
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to grid standards, and experimental validation of innovative solutions aimed at addressing the challenges posed by increasing renewable energy integration and electrification of various sectors. Key
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an example, consider the energy grid, where companies and prosumers (who produce and consume energy at the same time) try to handle the uncertainty coming from renewable sources and demand imbalances
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. The presence of rich flow structures in the atmosphere and ocean down to the scales of atmospheric convection O (100 m - 10 km) has sparked renewed interest across atmospheric and ocean scientists in recent
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microscopy methods, including Förster resonance energy transfer-fluorescence lifetime imaging (FRET-FLIM), to map SNARE protein trafficking to WPBs. Techniques include FRET-FLIM microscopy, mammalian cell
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will utilize newly developed microscopy methods, including Förster resonance energy transfer-fluorescence lifetime imaging (FRET-FLIM), to map SNARE protein trafficking to WPBs. Techniques include FRET
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they must resist. Maintaining the cultural heritage and at the same time preparing them for the future is a huge challenge. Renewal and/or replacement measurements while in parallel adopt sustainable and