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decision-making. Examples include crowd management and large-scale communication networks based on cellular or wireless sensors. For instance, during mass gatherings such as the sport matches (e.g
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Materials, Bioinspired Materials and Sustainable Materials. For more details, please view https://www.ntu.edu.sg/mse/research . We are seeking a dedicated and interdisciplinary scientist to join a
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sensing, and new applications of extreme sensors. One major theme of our research is the study of quantum effects in atomic systems and the light that is used to measure them. At the most fundamental level
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about the Shih Lab: Learn more about the innovative work led by Dr. William Shih here: https://www.shih.hms.harvard.edu/ . What you’ll do: Develop DNA-based sensors that seed crisscross assembly of single
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orbital sensors (e.g., ECOSTRESS, VIIRS, Landsat/MODIS) to build pre- and post-fire structural and functional diagnostics. Develop recovery chronosequences from multi-sensor time series and quantify
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. Optimal sensor placement, identified through adjoint-based sensitivity analysis to improve assimilation efficiency. By embedding physical laws into data assimilation, these methods bridge the gap between
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to demonstrate real-world feasibility. The overarching goal is to bridge high-level algorithmic innovation with energy-aware hardware deployment, enabling intelligent sensor systems that act as autonomous micro
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. Work Plan Currently, IPFN is involved in the development of diagnostics for the DEMO tokamak. These diagnostics include (but are not limited to) the reflectometers and the magnetic sensors. The candidate
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, around an existing plasmonic sensor. This role requires an engineer with a broad, practical skillset and demonstrable experience in building and troubleshooting physical prototype instruments, ideally in
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data to characterize machine performance, times series sensor data, and all other relevant machine settings and field conditions. Acts as liaison with industry, government, educational, and research