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Field
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-ion battery materials. The focus is to develop atomic layer processing methods to tailor the surface properties of lithium ion battery electrodes using nanoscale thin films and surface treatments
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, and functional properties of synthesized thin films, including atomic oxygen (ATOX) resistance Investigation of plasma–surface interactions relevant to composition and structural control Correlation
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campaigns using advanced synchrotron X-ray techniques to generate quantitative, AI-ready datasets that reveal defect-mediated mechanisms governing the stability, adhesion, and transport behavior of thin films
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. Develop microfabrication processes of versatile dielectric thin films ranging from electroformed memristors (non-volatile memories) to defect-free high-K gate oxides. Develop and fabricate devices based
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circuits in thin-film lithium niobate (TFLN) [Zhu2021] and tantalate (TFLT) [Powell2024]. Using the ultrafast Pockels effect in TFLN/TFLT, you will build high-speed cavity-based components [Larocque2024
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incorporating the molecular systems for strong light–matter coupling. The successful candidate will: Develop thin-film deposition and cavity fabrication processes, including spin coating, polymer matrix blending
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weight of the PHUs to enable the production of stable thin-film capacitors. • These bio-based polymers will be later integrated into sustainable energy-harvesting devices by a PhD student working in close
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. These applications will rely on stimulated Brillouin scattering in various waveguide platforms, including but not limited to thin-film lithium niobate. Fabrication of these chips will be done by you in the renowned
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-completed PhD with strong background in Materials Science or Physics (within the last 5 years) Considerable experience in understanding magnetic-domain physics in thin film and/or nanostructured materials
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structure, strain, and chemistry in superconducting and semiconducting thin films and heterostructures. Correlate structural and chemical features with superconducting and electronic properties. Develop and