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of surface acoustic waves coupled to a high mobility electron gas through the acoustoelectric effect, in view of developing non-linear integrated photonic-phononic circuits. We will use a well known material
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-qubit gates using intra-cavity Rydberg superatoms for photonic quantum computing. The post-doctoral researcher will develop new protocols for quantum engineering of light using cold interacting atoms, and
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, spanning quantum physics, chemistry, materials science, photonics, and computer science. The CESQ provides a collaborative, innovative environment that bridges cutting-edge experimental and theoretical
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shift a critical part of the spatial and photophysical information into the temporal domain, in order to drastically reduce the number of photons and the acquisition time required for image reconstruction
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validation. The postdoctoral researcher will work within the Metasurface Team at CRHEA, in close interaction with permanent researchers, postdoctoral fellows, PhD students, engineers, and external
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validation. The postdoctoral researcher will work within the Metasurface Team at CRHEA, in close interaction with permanent researchers, postdoctoral fellows, PhD students, engineers, and external
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)-electrochemical cell, Photon-to-Current Efficiency (IPCE) measurement with an action-spectra analysis (tuneable from the UV to the NIR), UV-visible spectroscopy (for solid and liquid) and FTIR spectrometer. Where
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should hold a PhD diploma in the fields of photonics or applied physics, with theoretical and experimental skills on optics, laser physics and/or ultrafast/non-linear optics. The research involves design
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project (“Gamma photon sources as a path for strong-field QED experiments”). The primary goal of this postdoctoral position is to implement and conduct experiments aimed at advancing strong-field QED