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Field
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research opportunity focuses on advancing large-scale additive manufacturing using metal wire as feedstock and electric arc as the heat source. The project aims to develop an innovative and efficient method
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nanoagents aim at converting optical energy into heat to induce hyperthermia and a stress response in targeted biological tissues. From an external optical excitation, the energy is absorbed by the nanoagents
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carbide (SiC) materials with high-temperature properties. The dissertation will focus on the preparation of silicon carbide ceramics using a novel approach without traditional sintering additives and at a
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spectroscopy with this equipment. Photothermal therapeutic nanoagents aim at converting optical energy into heat to induce hyperthermia and a stress response in targeted biological tissues. From an external
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of the complex physics governing the interaction between the heat source and the material. Additionally, it seeks to develop an efficient modelling approach to accurately predict and control the temperature field
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Institute of Low Temperature and Structure Research Polish Academy of Sciences | Poland | 9 days ago
emission color. This feature not only allows for intuitive, visual readout, but also provides high sensitivity and precision in identifying the maximal experienced temperature. Despite their significant
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, geothermal heat, and industrial waste heat all play critical roles. One promising solution for harnessing these energy sources is the supercritical CO2 (sCO2) Brayton cycle, which offers high thermodynamic
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of experienced researchers from CNRS, UL, Arts et métiers, IMT and CEA, as well as several PhD students and post-doctoral researchers, working on high-throughput material characterization and micromechanical
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high cycle efficiency, compact equipment size and their applicability to the exploitation of industrial waste heat sources. In project REVCO2, four research laboratories (CETHIL, Lafset, LMFA and LUSAC
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the melting of the metal wire by a concentrated electric arc to the droplet-by-droplet deposition of material into the molten pool generated by the same electric arc heat source. In situ and ex situ