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from Silicon Photomultipliers, to Single Photon Avalanche Diodes up to Superconducting Nanowire Single Photon Detectors. These techniques will be used for non-invasive in vivo characterisation
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nanoscience and are structured around six cross-cutting themes, as indicated on its website: https://w3.insp.upmc.fr This project aims to develop a conductive thermal diode driven by the heat generated by
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in a label-free manner. In this project, we will develop a novel label-free SMDT that can synergistically detect both charge and conformation of biomolecules based on nanopore and nanowire field-effect
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(packaging, plastic bags, textiles…). Thanks to their high specific surface area, it has been shown that ZnO nanowires (NWs) are promising candidates for water treatment, whether for soluble pollutants [6,7
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thermoelectric properties of materials across thin films, nanowires, 2D systems, and nanostructures, with a strong focus on nanoscale heat transport and energy conversion. We design, synthesize, and characterize
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across the vesicle bilayer will be achieved with protein nanowires, ionophores and pore-forming proteins. The project will involve protein purification, protein engineering, spectroscopy, photochemistry
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telecom lasers, a wide variety of detectors including superconducting nanowire single photon detectors. Spectroscopy is performed with Teledyne spectrometers with Nirvana InGaAs and Pixis silicon-based
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at the 'Group of Smart Nanoengineered Materials, Nanomechanics and Nanomagnetism -Gnm3' (https://jsort-icrea.uab.cat/) of the Universitat Autònoma de Barcelona (UAB). The position is in the framework
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design, fabricate, and test high efficiency superconducting nanowire single-photon detectors (SNSPDs) and detector arrays optimized for mid-infrared spectroscopy. The goal of this work is to develop both
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that overcomes the yield limitations of existing betavoltaic sources. The aim of the contract is to develop GaN or AlGaN nanowires with a high form factor using a top-down approach, this step being key