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functionalities across a broad spectral range (from UV to mid-infrared), with applications ranging from classical optical systems to emerging quantum technologies. We offer a vibrant, international research
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in silicon and 2) interface them with optical circuits to process the emitted photons. The tasks will involve designing and testing components in silicon photonics to interface with quantum emitters
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of Biomedical Engineering (BME) is situated within https://www.lerner.ccf.org/ ). 2025, over 1,800 people (including about 235 principal investigators and 650 trainees) participate in research programs focusing
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Institut of Mineralogy, Physics of Materials and Cosmochemistry | Paris 15, le de France | France | about 1 month ago
category: Contrat doctoral PhD funded by Institut des matériaux de Sorbonne Université (iMat) PHD title: Doctorat de Physique PHD Country: France Where to apply Website https://www.abg.asso.fr/fr
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Job Purpose You will contribute to an EC project entitled: “Quantum-optic Silicon as a Commodity: Extending the Trust Continuum Till the Edge of ICT Networks” with Dr Ross Millar and Prof Douglas
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of Sr atoms Task 1: Within the Quantum Flagship project iqClock, we set up an apparatus for an active optical superradiant clock with sequential loading. The Doctoral Candidate (DC) will finalize
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essential. Teaching responsibilities will include participation in and development of graduate courses and strong engagement with Tsinghua SIGS’s core curriculum. Supervision of PhD and MSc students and
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dynamics, molecular physics, optical physics, plasma physics, precision measurements, quantum information; Green chemistry and materials science: green chemistry, materials science; Curiosity-driven
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Academic Job Category Faculty Non Bargaining Job Title Research Associate - Ultrafast Optical Spectroscopy Department Research | Quantum Matter Institute | Faculty of Science (Marcel Franz) Posting
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highly accurate measurements of collision-perturbed shapes of the molecular optical resonances using cavity-enhanced techniques. This will allow us to validate the quantum calculations (both our quantum