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contact and thus minimize friction and damage to the surfaces for improved energy efficiency [5,6]. To characterize these different polymer brushes, atomic force microscopy (AFM) is used, which in its
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Brillouin microscopy on cells and tissues to perform AFM in force spectroscopy mode and to compare AFM and Brillouin results in order to build a new theory of viscoelasticity modification due to acquisition
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material characterisation, including: AFM (including PFM or other nanoscale electromechanical modes) SEM/TEM Confocal microscopy Rheology FTIR, XRD, XPS Evaluate degradation profiles, electroactive behaviour
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using atomic force microscopy (AFM), Raman spectroscopy, X-ray diffraction, X-ray photoemission spectroscopy (XPS) and Rutherford backscattering spectroscopy (RBS), • the transfer of 2D materials and van
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techniques to assess process outcomes, material quality, and device performance, including optical microscopy, photoluminescence, scanning electron microscopy (SEM), atomic force microscopy (AFM), x-ray
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conjunction with imaging techniques (TEM, SEM, and AFM). This research project falls within CERMAV's key research areas and is being carried out within the “Self-assembly and Physicochemistry of Glycopolymers
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functionalisation strategies, and cutting-edge characterisation techniques (including Manchester Met’s unique in-situ electrochemical-AFM-nanoRaman (TERS) system) to optimise sensor performance. The research will
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deposition) to the study of optoelectronic properties (current-voltage measurements, capacitive measurements, C-AFM, external quantum efficiency). The ultimate goal will be to produce a photosensitive device
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pathways. The goal is to design bio-instructive materials that actively direct immune and bone cells toward regeneration. These will be characterised using AFM and rheology, followed by immune–osteogenic co
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of the treated fibres using advanced characterization methods (e.g. AFM, XPS, ToF‑SIMS, DVS, tensile testing, X‑ray tomography). Analyse and correlate processing parameters, microstructure and properties, and