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You will use advanced AI-driven cell tracking methods to elucidate the remarkable self-organization of cells in mammary gland organoids. The mammary gland is one of the most dynamic tissues in
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of molecular events that underlie chaperone functions, and are invisible with other methods. Here you will focus on a new frontier: how chaperones and ribosomes work together to synthesize and fold multi-protein
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single-molecule biophysics (Nat Commun 2021, 2023) and microfabrication (Angewandte, 2020). Qualifications You are an experimental (bio)chemist or molecular biologist with a strong interest in synthetic
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such systems can learn. The aim of one project is to develop and analyze new methods by which diverse dynamical systems are able to learn. Our goal is to connect these ideas to real-life biological learning
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by prof. Wim Noorduin focuses on the dynamic interplay between chemical reactions and crystallization phenomena to control the emergence of complexity in the solid state. In particular, the group aims
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methods. While the work will mainly focus on theory and simulation, for both projects promising Fano-resonant metasurfaces will be manufactured and measured. In project 1 you will demonstrate the limits
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electromagnetic design and optimization, and demonstrate concepts in optical experiments Can we realize programmable, trainable and dynamically reconfigurable metasurfaces? Can you switch between metasurface
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temporal resolution. This enables us to study excitations and localized modes of plasmons, 2D semiconductors, and a wide range of optical metamaterials. We study excitation dynamics through time-resolved
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resolution. This enables us to study excitations and localized modes of plasmons, 2D semiconductors and a wide range of optical metamaterials. We study excitation dynamics through time-resolved spectroscopy