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of Nano Particles at Empa and also matriculate in ETH Zürich. Position starting from July 2025 or upon agreement. The research focuses on developing innovative plasmonic materials. Surface plasmon resonance
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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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novel applications of plasmonic picocavities in fields ranging from plasmon enhanced photochemistry to exciton dynamics in molecular ensembles. Where to apply E-mail ofertas_euraxess@icmm.csic.es
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This PhD project investigates ultrafast optical switching in plasmonic nanogaps, leveraging their exceptional ability to confine electromagnetic fields into sub-nanometer volumes [1-5]. Plasmonic
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Moléculaires in Bordeaux and the CEA in Saclay. The SUNRISE project aims at exploiting plasmonic interactions to selectively modify the interaction between light and chromophores on a nanometric scale. In this
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. Project background Position starting from May 2025 or upon agreement. Job description The research focuses on probing biomolecular interactions with plasmonic sensing. Surface plasmon resonance (SPR) and
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of these objects for a variety of thermo-and photo-catalytic reactions. Alloying plasmonic metals (Cu, Ag or Au) with transition metals is recognized as an appealing strategy to create nanostructures in which
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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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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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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