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Field
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. This project will be supervised by Dr Yuanbo (Tony) Tang. This PhD project is an exciting opportunity for a self-driven individual with a passion for advanced manufacturing and metallurgical research. The PhD
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processes. This project is part of this context by developing a new process for optical fibres containing nanoparticles. The potential of this new generation of fibres as lasers and sensors has already been
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industry and science – a Project Apollo of the digital age. EUVL is powered by light that is produced in the interaction of high-energy CO2-gas laser pulses with molten tin microdroplets. The use
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for sustainable manufacturing. The Background Metal additive manufacturing at large scale, such as laser cladding, is a well-established technique to reduce the cost of repairing or regenerating the damaged
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energy. Determining the intricate structure of the polycrystals is a laborious and restrictive task, and only a handful of measurement techniques are capable of fully imaging material microstructure. Laser
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of measurement techniques are capable of fully imaging material microstructure. Laser ultrasonics is one of these techniques and it does this by linking the elasticity of individual crystals and
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monitoring and sensing of the fundamental physical phenomena occurring during laser-material interaction, in order to optimize laser-based material processing techniques for sustainable manufacturing
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Laser Ionization for Applications in the Environment and Health) aims to develop instrumentation based on the coupling of laser ionization to mass separation in order to quantify, separate and purify
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Research Infrastructure? No Offer Description Work Activities In semiconductor device manufacturing, metrology tools are required for wafer alignment, overlay and device inspection. As devices become more
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research facilities include 4 ultrafast lasers, 2 diffraction spectrometers, sample deposition equipment as well as electrochemical capabilities. Our group has received funding by the ERC, the ANR or Rennes