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. The successful candidate will be joining the Atomic Quantum Optics group led by Prof. Dr. Morgan Mitchell, in an experiment on the interaction of single photons and entangled photon pairs with individual trapped
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. The successful candidate will be joining the Ultracold Quantum Gases group led by Prof. Dr. Leticia Tarruell. The interplay of interactions and gauge fields is responsible for some of the most intriguing phenomena
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homolog. These changes affect intermolecular interactions and ultimately reshape condensate mechanics to facilitate neuronal mechanotransduction. The goal of this position is to unravel how pH-dependent
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polarization via exciton population engineering, including nonlinear optical responses relevant for neuromorphic activation functions. Analysis and interpretation of experimental data in close interaction with
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modulation effects, which can be interrogated using on-chip interferometric configurations such as Mach-Zehnder interferometers. By quantifying changes in the guided mode due to the interaction with analytes
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collective phenomena, photodetection, quantum technologies, and strong light-matter interactions, among others. The project has a scientific character but also explores applications (such as single photon
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are interested in exploring a particularly intriguing one: the SU(N) Fermi-Hubbard model. It describes fermions of spin N and SU(N)-symmetric interactions, for which intricate magnetic orders and exotic spin