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- Wetsus - European centre of excellence for sustainable water technology
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will work on the project: Quantifying lithium partitioning between rock-forming minerals and silicate melt. Your job Lithium has various industrial applications, with the electrification of transport
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Earth Sciences, Inorganic Chemistry, Material Sciences or other appropriate fields. You will work on the project: Quantifying lithium partitioning between rock-forming minerals and silicate melt. Your job
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PhD: Quantifying lithium partitioning in rock-forming minerals Faculty: Faculty of Geosciences Department: Department of Earth Sciences Hours per week: 36 to 40 Application deadline: 20 October
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use biophysical tools combined with cell-free protein synthesis. A microfluidics system with freestanding lipid bilayers will enable the electrical monitoring of ion channels while a mechanical load is
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project that will use biophysical tools combined with cell-free protein synthesis. A microfluidics system with freestanding lipid bilayers will enable the electrical monitoring of ion channels while a
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specific type of solid-state emitters, rare-earth ions (REIs) in host crystals, are particularly interesting. Because of their internal atomic structure, REIs can serve as excellent qubits, with long
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sensors. To build such quantum networks, nodes based on solid-state emitters are promising contenders. One specific type of solid-state emitters, rare-earth ions (REIs) in host crystals, are particularly
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Wetsus - European centre of excellence for sustainable water technology | Netherlands | about 1 month ago
ion selectivity—either through ex-situ treatment or in-situ modification during operation. Advanced ED with monovalent-selective and modified membranes can selectively separate ions under controlled
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scalable solutions. We utilize a variety of polymeric and ceramic ion-conducting materials to couple renewable energy-driven processes with applications such as water electrolysis, nitrogen and carbon
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utilize a variety of polymeric and ceramic ion-conducting materials to couple renewable energy-driven processes with applications such as water electrolysis, nitrogen and carbon dioxide fixation.