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at the ETH Zürich and ZHdK, combining expertise in computational design, sound composition, acoustic simulation, virtual reality, psychoacoustics and the history of architecture. The project relies
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Ph.D. students to overcome this challenge using intelligent micromechanical systems. In the same way that automatic Swiss watches power themselves from the motion of the wearer, we will design and make
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, we combine computer-aided molecular and process design to optimize molecules and processes simultaneously. To holistically evaluate the environmental impacts of chemicals and energy systems, we develop
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flexibility in the design of the meta-material, it is also a relatively slow process. To overcome this limitation, this project explores an alternative approach inspired by nature, namely emerging
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pharmacodynamic data analysis. Project background The project's main objective is to extract and analyze large amounts of pharmacodynamic data from various sources and design a user-friendly database. Through
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already established at the Quantum Device Lab for superconducting qubits to enhance the readout of spin qubits. To achieve this, we plan to utilize well-designed Purcell filters, strongly coupled readout
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shock wave lithotripsy. You will be part of an exciting collaboration between ETHZ and ESRF. You will design your experimental setup by exploiting the state-of-the-art ultra-high-speed imaging, optical