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Field
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resonances when the metal's electrons oscillate in phase with an exciting electromagnetic wave. These Localized Surface Plasmon Resonances (LSPR) are currently studied in many different research fields
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reactions with solar radiation. In this project we propose to combine the unique features of plasmonic metal nanoparticles as photocatalysts[1] with asymmetric reactivity, aiming at performing heterogeneous
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miniaturized optical circulator based on a novel plasmonic-hybrid concept, within a recently granted European project CIRCULIGHT. Within the project, TU/e is responsible for the photonic platform development and
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integrated and miniaturized optical circulator based on a novel plasmonic-hybrid concept, within a recently granted European project CIRCULIGHT. Within the project, TU/e is responsible for the photonic
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numerically demonstrated in Cimphonie Team (C2N) in 2021 [3]. The principle, called magneto-biplasmonic, explores the TMOKE enhanced by both the surface plasmon polaritons and coupled modes system in a slot
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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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molecular-plasmonic systems. For recent work see (see https://www.np.phy.cam.ac.uk ). Project: Photoconductivity of self-assembled plasmonic nanocavities This project will continue our work building nanoscale
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the use of classical silver and gold nanocubes (known-how in the team), then moving towards the development of new plasmonic systems with structures that can be activated or modified by light, or even
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The School of Chemistry, Chemical Engineering and Biotechnology (CCEB) invites applications for the position of Project Officer. Key Responsibilities: Development of novel plasmonic materials and
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of novel nanophotonic and plasmonically structured substrates and metasurfaces. Optimisation of nanostructures for enhanced light matter interactions, beam shaping and spectral response. Design, simulate and