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addition to technical models allowing to assess technical scaling and an optimal operation. The optimal plant design is identified by considering the energy supply system, the choice of capture technology, the DAC
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preparation Deriving insights for film and device fabrication based on the above described workflow Your Profile: Masters degree in physics, materials science, physical chemistry, electrical engineering and
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collaboration with leading international research partners within the EU project Your Profile: Masters degree or comparable degree in mechanical engineering, electrical engineering, environmental engineering
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membranes. You will develop theoretical models and employ computational methods to describe the coupling between ionic nanofluidics, electric double-layer charging, and interfacial reactivity in electrolyte
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(Masters) in Electrical Engineering, Mechanical Engineering, Electronic Engineering, Physics or a comparable field Strong mathematical background Excellent knowledge and experience in programming (e.g
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for memristive circuit measurements and experimental data analysis interact with cross-disciplinary experts (e.g. neuroscientists and device physicists) Your Profile: Master’s degree in electrical/electronic
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Your Job: Join the EU funded SAGELi project to develop and advance battery chemistries by introducing new functionalities into an existing battery technology to achieve ultra-high performant
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PhD Position - Modeling and simulation of memristive devices for application in neuromorphic systems
degree in physics, electrical engineering or in a related subject Interest in theoretical and interdisciplinary work Experience in device physics and numerical simulations is desirable Fluent in English
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quantum mechanical models Your Profile: Scientific Master degree or comparable degree in electrical engineering, computer science, physics, or similar field Basic knowledge in (integrated) circuit design
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optimization techniques for direct in-situ use in quantum dot experiments Model and characterize major sources of environmental and coherent error stemming from material properties and spin-charge dynamics Your