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and patient outcomes. The work will combine in vivo biology and advanced imaging with materials science and polymer engineering. Project background The Hydrophobic Effect as a Danger Signal in Foreign
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the interrogation of chiral systems down to the nanometer scale. Project background Chirality describes whether an object is non-superimposable with its mirror image. Despite being a purely geometric property
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prognostic markers in histological images through neuronal networks. Job description The successful candidate will play a central role in generating and analyzing spatial transcriptomics and image datasets
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: Lastname_Firstname_Portfolio.pdf), to include: images/graphic content illustrating projects relevant to the job short descriptions of the projects included short research articles (if existing and relevant) 4) Research Statement (3
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-lapse microscopy and automated image analysis to quantitatively track single-cell gene expression in controlled dynamic environments. A unique feature of our lab is the tight interaction between our lab's
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biology or advanced imaging are encouraged to apply. The use of multi-disciplinary approaches and research topics that complement those of existing research groups is an asset. The successful candidate is
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research environment to perform collaborative research on mesoscopic physics in Kagome Lattice and vdW 2D systems by magnetic imaging using scanning probe microscopy such as MFM (magnetic force microscopy
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imaging, proteomics, genomics and bioinformatics platforms. The successful candidate will receive installation credit as well as an annual research and consumable endowment in a dynamic research environment
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, which is part of the ICON-ART (ICOsahedral Nonhydrostatic – Aerosols and Reactive Trace gases) modeling system. The goal is to better understand the environmental pathways of selenium - from its emission
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structures, domain walls, and topological defects govern macroscopic functionality. In this project, we will employ cutting-edge synchrotron-based 3D imaging techniques to directly visualize ferroic order at