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Field
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models, in-house laboratory tests in a wind-wave-current flume (https://research.ncl.ac.uk/amh/ ) and numerical methodology to quantify biofouling impacts on flow-induced vibration phenomena, structural
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sensitivity, interference contrast, and phase stability. • Assess performance in low-flux, photon-noise-dominated conditions analogous to Mars. • Conduct tolerance analyses, especially regarding optical
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(e.g. locking oscillators to a common source) but also hybrid methods Analysis of target Signal-to-Noise Ratio (SNR) achievable through effective signal synchronisation against use cases
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library of models covering various physical phenomena (e.g., damped vibrations, wave propagation, thermal diffusion). This harmonized library will serve as a reference framework for this upcoming project
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January 2026 Details Quantum error correction by combating noise in quantum systems, is an enabler of various quantum technologies. For the purpose of near term application, there are several competitive
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determine the mass flowrate based on the phase shift of vibration of one or more flow tubes. However, the coupling effect of flow performance and vibration of structure, as the underlying mechanism of CMF
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together with a postdoctoral fellow, who will focus on the effect of vibrations on thermal catalysis and on developing X-ray operando characterisation methods. Your work will contribute to a new research
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biofouling impacts on flow-induced vibration phenomena, structural responses and operational performance of dynamic cables, and to evaluate sustainable antifouling materials, structural design, optimisation
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for fine-tuning and deployment of large-scale models. What’s more, multimodal models are particularly vulnerable to data uncertainty, modality dropout, and noise propagation, which can degrade robustness and
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activation reactions using operando characterisation method. You will work in a team together with a postdoctoral fellow, who will focus on the effect of vibrations on thermal catalysis and on developing X-ray