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, silicides hold promise for realization of coherent superconducting quantum circuits, enabling scalability with minimal additional cost and reduced complexity in technology transfer. Successful realization
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Description The International Max Planck Research School for Ultrafast Imaging and Structural Dynamics in Hamburg, Germany, offers a structured PhD program focusing on ultra-fast phenomena, X-ray
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/InstituteInternational Max Planck Research School for Ultrafast Imaging and Structural DynamicsCountryGermanyCityHamburgGeofield Contact Website http://academiceurope.com E-Mail IMPRS.UFAST@mpsd.mpg.de STATUS: EXPIRED X
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. This position is part of the recently awarded NSF EPSCoR Ge-STAR Project (Germanium Science and Technology for Advanced Research – https://ge-star.org ) and offers an outstanding opportunity to join a nationally
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. This position is part of the recently awarded NSF EPSCoR Ge-STAR Project (Germanium Science and Technology for Advanced Research – https://ge-star.org ) and offers an outstanding opportunity to join a nationally
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. This position is part of the recently awarded NSF EPSCoR Ge-STAR Project (Germanium Science and Technology for Advanced Research – https://ge-star.org ) and offers an outstanding opportunity to join a nationally
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limitations in terms of accuracy, speed, and adaptability across various use cases. This project aims to develop a compact, scalable, and cost-effective microscope system based on coherent diffractive imaging
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universities, as well as industrial partners in the field. The successful candidate will be joining the Atomic Quantum Optics group led by Prof. Dr. Morgan Mitchell. The group uses the extraordinary coherence
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materials and we utilise these non-absorbed X-rays to massively increase image contrast and reduce radiation exposure using coherent synchrotron radiation. We have developed these “phase contrast” and “dark
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universities, as well as industrial partners in the field. The successful candidate will be joining the Atomic Quantum Optics group led by Prof. Dr. Morgan Mitchell. The group uses the extraordinary coherence