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, such as agricultural by-products including manure, crop residues, and other residual materials. Depending on their composition, amendments may provide variable concentrations and ratios of nutrients such as
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simulation techniques based on finite element and multibody dynamics formulations. Your tasks involve developing new elements tailored to the multi-physical effects seen in high-performance mechatronics
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operational performance. Based on feedwater composition (salinity, monovalent/divalent ion ratios, and valuable elements), you will model and design ED configurations that produce tailored concentrate streams
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adaptation and learning from their experiences. Using a combination of theory, numerical experiments and precision desktop experiments, we will create 3D materials with self-adapting elastic elements
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industry. Our work spans the full spectrum from material and component development to the design and operation of laboratory-scale systems, with the overarching goal of developing scalable solutions. We
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electrification of the chemical industry. Our work spans the full spectrum from material and component development to the design and operation of laboratory-scale systems, with the overarching goal of developing
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hydrodynamic mixing plasma energy density (power, frequency, volumetric flow) voltage waveform, electrode number, shape and material gas phase composition (air, N2, Ar, or mixtures) water chemistry (pH
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disciplines to answer research questions. We offer you the opportunity to set up your own composite research to deepen your knowledge and provide society with answers through applied research.
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machine learning solutions to optimize the component lifecycle directly contributing to a more circular economy. Information In the manufacturing landscape, determining whether a component should be
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investigate how 3D printed clay systems—columns, claddings, and related architectural elements—can function as materially driven climate regulators, providing passive environmental comfort while also advancing