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or system in question. The research project "UrbanRainChange"will improve resilient climate adaptation in urban water management by developing a framework for projecting changes in rainfall patterns
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convert the energy carried by water and moisture, such as latent heat and chemical potential energy, into electricity through the natural and ubiquitous processes of water evaporation and moisture
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. The aim is to contribute to advancements in wastewater treatment and resource recovery for sustainable water management and food production. We will work in parallel with different areas that all connect
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(greenhouse gases), water harvesting, water purification, catalysis and drug delivery. Within the project there is expertise in the synthesis and optimization of a wide range of porous materials, including
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circular systems and improve the conditions for cultivation in urban environments. The aim is to contribute to advancements in wastewater treatment and resource recovery for sustainable water management and
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the corrosion resistance properties of Mg alloys for bioresorbable or biostable stent applications. Magnesium stents are – by default – out of equilibrium, as they readily degrade in water-based solutions
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. The aim is to contribute to advancements in wastewater treatment and resource recovery for sustainable water management and food production. We will work in parallel with different areas that all connect
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of the FEMTO-ST institute specialises in small-scale robotics (microrobotics). Its researchers develop millimetric and submillimetric robots for medical and industrial applications. At small scales
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pathway prediction technique as compared to the available ones, with a prime focus on two-dimensional (2D) materials and to envisage the catalytic reaction mechanism for H2O and CH4 dissociation on such 2D
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systems and improve the conditions for cultivation in urban environments. The aim is to contribute to advancements in wastewater treatment and resource recovery for sustainable water management and food