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, simulate and monitor skin wound evolution, with the ultimate aim to treat and even prevent chronic wounds. We will couple an in vitro analytical, omics-based platform to self-care wearables
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thorough understanding of theoretical/numerical methods for simulating optical phenomena, experience in fabrication and/or characterization of micro- or nanostructures, hands-on experience with fiber-optic
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ultra-efficient lasers and all-optical transistors. Our goal is to uncover the elusive physics of strongly interacting polaritons far from equilibrium, bringing the vision of room-temperature superfluid
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environments. Based at Cranfield University, this project investigates how energy is transmitted over long distances in poor weather using electro-optical (EO), infrared (IR), and radar systems, with the goal
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activity of the research group (project meetings, workshops, etc.). To characterize artificial spin systems using lab-based measurement techniques such as magnetic force microscopy, magneto-optic Kerr
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or passive components into organic substrates; has experiences in magnetic components design, optimization and integration; is familiar with the simulation tools such as Ansys (Maxwell, Q3D, Icepak), LTSpice
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dynamic and international research environment. Our research facilities include top-notch optics laboratories and access to a world-class cleanroom. Principal supervisor is Prof. Albert Schliesser (email
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efforts in materials physics and design, quantum optics, sensing and communication, biophysics, plasma physics, and continuum physics. Our research impacts society with new sustainable energy technologies
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develop experimental research performing magneto-optical spectroscopy combined with electronic transport to investigate light-matter interactions in 2D materials. Our goal is to access and control new
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are complex superstructures composed of different nanoparticles, similar to how atoms are linked to molecules. This results in innovative, exceptionally promising optical and electronic properties that go far