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quote Vacancy ID 179246 on all correspondence. Contact Person: Tessa Krages Contact Email: hr@humanities.ox.ac.uk
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biological, and live cell fluorescence imaging experiments. Associated structural analysis of the proteins by cryo-electron microscopy will be undertaken via collaboration with other workers. This full-time
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nonlinear aspects. Previous experience in developing advanced constitutive models, particularly for rubber-like materials, is desirable. Informal inquiries may be addressed to Laurence Brassart (email
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Health, Geography, Global Affairs, or a related field, possess sufficient specialist knowledge in the discipline to work within established research programmes, experience writing computer code in Stata
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velocities can reach relativistic values in the tail of the momentum distribution. Understanding how these relativistic electrons are transported through the plasma is a complex multi-scale problem
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targets, by leveraging high-dimensional big data (e.g. electronic health records, multi-omics and phenotypic) from large prospective biobanks including China Kadoorie Biobank (CKB) and UK Biobank (UKB), and
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of chromatin or obstacles on the DNA. To do so, you will design and employ novel biophysical instrumentation (e.g. optical tweezers, single-molecule fluorescence, microfluidics, cryo-electron microscopy) and
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a single email in one pdf file to the Faculty HR Team,recruitment@law.ox.ac.uk . The closing date for applications is 12 noon, midday on Monday 2 June 2025. Interviews will be held, in-person
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, atomic-scale point defects in wide-bandgap solids can exhibit a deterministic interaction between emitted photons and electronic and nuclear spins that enables photon mediated entanglement for distributed