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Field
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mechanical membrane. Compared to former strategies, here, a spatial light modulator is used to spatially shape the wavefront of the light beam. Such a modulation enables to exert simultaneously adapted optical
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generated via resonant dispersive wave (RDW) emission in a hollow-core fiber, where, under appropriate conditions, energy from the pump beam is transferred to the DUV range, enabling the generation of tunable
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promising imaging technology is proton-acoustics, relying on detecting acoustic waves generated by proton-tissue interaction for real-time in-vivo 3D proton beam imaging and dosimetry. However, proton
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, there is an urgent demand for accurate data on ion-beam collisions with atomic and molecular targets for the development and maintenance of fusion reactors, treatment planning in hadron therapy, and
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with direct emission in 400-500 nm wavelength range are highly demanded in industry and science. Compared to laser diodes, solid-state lasers offer clear advantages such as a better beam quality, energy
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reproducible processes, which is rarely achieved in practice. In this context, we propose to exploit the potential of molecular beam epitaxy (MBE) assisted by coupled in situ and real-time characterization
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morphology with its performance (reactivity, selectivity, efficiency) and degradation under realistic long term deployment conditions Coordination and execution of in-house beam times Collaboration with other
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. in Physics, Materials Science, Electrical Engineering, or a related field by the start date. Preferred Qualifications: Hands-on experience in nanofabrication techniques (e.g., electron-beam lithography
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Institut National des Sciences Appliquées de Lyon | Villeurbanne, Rhone Alpes | France | 14 days ago
focuses on applications in air — including sonic black holes in air-filled ducts [2, 3] and structural ABHs embedded in beams, plates and shells [4, 5] for vibration damping — the case of hydraulic piping
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PhD student at ILL: studying In situ neutron diffraction for green steel and functional metal oxides
particle accelerator produces intense X-ray beams that are used by thousands of scientists each year for experiments in diverse fields such as biology, medicine, environmental sciences, cultural heritage