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controlled power electronics to optimize the overall efficiency of electromechanical conversion. Ultimately, the system will be integrated into two thermal energy conversion cycles: a thermochemical cycle and
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. Secondly, we will evaluate the potential of a cladding-pumped Raman amplifier, once again seeking to optimize efficiency and gain equalization in the various cores by designing special optical fibers.Planned
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. Brinkmann) • Ink formulation and printing process optimization: IETR Rennes (Maxime Harnois, Emanuel Jacques and Fabien LUCAS) The research will focus on: • Formulating and optimizing dopant inks for printed
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prospects for improving energy efficiency and decentralization (adaptation to local energy sources). There is no universally optimal cycle; optimality depends on precise specifications defining the objectives
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(zeolite structure, texture, composition) that optimize the properties of the photocatalysts and to demonstrate their efficiency in solar-to-hydrogen conversion. Main missions • Design the setup
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flavonoids, using supercritical CO₂ (scCO₂). Operational conditions will be optimized to preserve their bioactivity while reducing environmental impact. This approach will be compared with more conventional or
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and a lifetime compatible with operation at 1450°C (≈2700F) for long periods for internal engine components. The main objective of this thesis project carried out at IRCER is to optimize the PIP
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value-added materials. Objectives of the PhD The PhD candidate will focus on designing and optimizing green spinning processes for lignin-based fibers, relying exclusively on enzymes and water, avoiding
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and optimize specific functions. The ICMCB carries out fundamental research on model materials and/or materials with potential applications. The ICMCB is a UMR with an average of 280 agents (permanent
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mechanical motion into electricity; - An intelligent electronic control system, enabling optimized regulation of the thermodynamic cycle. Within the CALIFORCE3 framework, the REMLA system will be integrated