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PhD Project: 3D-printing next-generation electro-actuators for soft robots and devices Applications are invited for a PhD project within the Faculty of Engineering, in the Centre for Additive
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3-year PhD studentship: Scaling-Up Functional 3D Printing of Devices and Structures Supervisors: Professor Richard Hague1 , Professor Chris Tuck1 , Dr Geoffrey Rivers1 (1 Faculty of Engineering) PhD
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PhD project: 3D-Printing Devices with Responsive Structural Colour Applications are invited for a PhD project within the University of Nottingham’s Faculty of Engineering, in the Centre for Additive
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multiphoton 3D printing, design and utilisation of photonics devices, programming and software engineering is a plus. Our offer A position for four years; a working week of 38 hours and a gross monthly salary
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fabricate (3D print) bespoke equipment tailored to the project's specific needs. Contribute to interdisciplinary research efforts, fostering collaboration between various research groups, and actively
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fabricate (3D print) bespoke equipment tailored to the project's specific needs. Contribute to interdisciplinary research efforts, fostering collaboration between various research groups, and actively
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, carbohydrate-active enzymes, polymer chemistry, spectroscopic methods, material science, 3D-printing, statistical physics and molecular dynamic simulations, formulation technologies. Excellent communication
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of 3D-printed prototypes, which will be tested in wind tunnels to validate the simulation results and assess the practical implications of the porous designs. Both compressible and incompressible flow
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integrates dynamic “smart” materials into 3D-printed structures, opens new frontiers in both bioelectronics and solar energy harvesting. Our goal is to create adaptive electrode architectures. These advanced
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responsibilities include: conducting experimental research on the BLIB, using advanced physical chemistry techniques; designing and building setups with lab equipment and 3D printing; maintaining an electronic lab