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wave enantioselective electron paramagnetic resonance (TWEEPR). The successful candidate will contribute to the development of novel GHz experimental techniques within the Magneto-optics team
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"Phase-space-inspired numerical methods for high-frequency wave scattering: from semiclassical analysis through numerical analysis to implementation". The design of fast and reliable algorithms
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engineers and is divided into a scientific team and two technical teams dedicated to "Waves" and "Particles" instrumentation, respectively. The recruited postdoctoral researcher will be based at the Palaiseau
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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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vortex below an external liquid/gas interface. Quasi-steady solutions will be derived for these configurations, and their stability with respect to long- and short-wave vortex perturbations will be
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, including interactions with waves - Proficiency in coupled ocean/sea ice numerical modeling in coastal Arctic environments - Proficiency in Python and Fortran programming languages Website for additional job
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in silicon ensures compatibility with existing technologies and scalability for quantum communication and computing. Mechanical coupling of spins in silicon, particularly using surface acoustic waves
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singularities of the Euler and Navier-Stokes equations. To access dissipative structures, we are developing two types of optical metrology methods : An innovative Diffusive-Wave Spectroscopy method that allows
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to validate their performances. The second objective will focus on the design, realization and optimization of compact fiber lasers and amplifiers operating in continuous wave regime. Power-scaling and
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wave manipulation) and in the field of spin-to-charge conversion for the creation of broadband THz emitters (e.g. [1]). An indication of the presence of an ultrafast photo-induced spin current can