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-metallic clusters that combine plasmonic and catalytic metals These clusters will be deposited with high control over size and composition using cluster beam deposition on morphologically engineered TiO2
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the Laboratory of Nano Particles at Empa and also matriculate in ETH Zürich. The research focuses on developing innovative plasmonic materials. Surface plasmon resonance (SPR) and localized surface
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The proposed 2D photocatalysts are expect to change the traditional way of design artificial photocatalysts. Expected outcomes of this project include fabrication of soft 2D plasmonic photocatalyst
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design and characterize disordered optical metasurfaces. Main focus will be theoretical and experimental understanding of the complex optics of plasmonic disordered metasurfaces as well as optical
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A PhD studentship is available at the intersection of quantum optics, nanophotonics, plasmonics and molecular spectroscopy. How to confine, control and manipulate light at atomic scales has been
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catalytically active metals to drive chemical reactions with light [3-4]. The specific goals of this PhD project are to 1) understand how plasmonic Mg nanoparticles and their surface oxide layer attract and
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the foundations of ultrasensitive molecular manipulations techniques within microfluidic environments. What You Will Do Design and conduct thermofluidic manipulation experiments using plasmonic substrates Work with
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or surface plasmon resonance), mass spectrometry, analysis of protein structures or enzymology • Be able to demonstrate a high level of expertise and success in the previous research areas, e.g. by
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single molecule detection is of advantage. The successful candidate will conduct cutting-edge thermofluidic manipulation experiments utilizing plasmonic substrates, functionalized quantum dots, and single
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the synthesis of nanoformulation of virtually any material or the combination of seemingly unimaginable materials in one nanoformulation (e.g., plasmonic-semiconductor, plasmonic-magnetic, etc.). In addition