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a passive backscatter communication system tailored for implantable biosensors. o RF circuit design to efficiently encode and transmit biosensing data based on OECT voltage variations. o Integration
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at the Institute of Cellular and Integrative Neurosciences (INCI, CNRS, Strasbourg), working within the "Pain and Psychopathology" team under the direction of Dr. Ipek YALCIN. Additionally, they will complete
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and algorithms for efficient deep-tissue energy transfer. Experimental Validation – Integrating and testing prototypes in realistic laboratory and clinical settings to demonstrate safe and effective
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work within the GREMAN laboratory (UMR CNRS 7347), which has strong expertise in ferroelectric oxides (from their growth to their integration into devices, including their complete characterization), in
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pulses via nonlinear interactions in liquids, gases or crystals. In parallel, THz systems have been developed using ultra-fast photoconductors (PCs), in which a semiconductor (SC) is integrated with a THz
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the perspective of cell, tissue and organ mechanics/dynamics and mechanical signal transduction. The institute operates according to a fully integrated open laboratory philosophy, with an extensive infrastructure
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, railway or nuclear industry, a failure can create a disaster and asserting structural integrity is thus highly critical. Structural Health Monitoring (SHM) consists in embedding sensors in a structure to
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, focusing on how these interactions lead to the replacement of larval tissues by adult tissues. The ambitious nature of the project lies in its aim to study morphogenesis in an integrated, multi-tissue
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also a new NbN SThM probe developed at the NEEL Institute in Grenoble, - integration of the cryo-SThM into a SEM optimised by the Institute Lumière et Matière in Lyon for in-situ cleaning of the probe