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Field
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Challenge: Understanding how micromobility affects pedestrian stress and comfort Change: Leveraging XR simulations to explore real-world pedestrian interactions. Impact: Guiding urban policy toward
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mathematics, for example mapping out disease processes using single cell data, and using mathematics to simulate gigantic ash plumes after a volcanic eruption. In other words: there is plenty of room
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adaptation to new EO tasks such as disaster response, biodiversity monitoring or land-use change detection; support generative EO applications such as synthetic data creation, gap-filling, and simulation
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postdoc, your research will be aimed at further developing ultrafast photoacoustics for overlay metrology. You will perform simulations and experiments to explore the feasibility of the approach on basic
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mathematics, for example mapping out disease processes using single cell data, and using mathematics to simulate gigantic ash plumes after a volcanic eruption. In other words: there is plenty of room
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develops and analyses behavioural experiments (reaction times, eye fixations) and EEG data. The computational strand simulates behavioural and neural data related to processing and memory retrieval. As a
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seasonal surveys, develop hydrological models to simulate the system's hydrological and geomorphic behavior, and engage with stakeholders to identify opportunities for system improvement. Floodplain System
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technologies—and eager to accelerate their discovery with machine learning and materials theory? Are you passionate about linking atomistic processes to device performance through computer simulations? Are you
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. Demonstrable experience in developing analytical and numerical models for dynamic systems (e.g. FEM, multiphysics simulations, etc.). Strong critical thinking, problem-solving, and inventive skills, with
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simulations including heat pumps, buffer storage, and building demand. Using monitoring data from the experimental façade at TU Delft’s Green Village to calibrate and validate models. Investigating control