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into different atmospheric layers. Numerical model to describe the temporal and spatial dispersion behaviour of ablated gases in the atmosphere. Derivation of parameters necessary for the calculation of regional
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underexplored. Coupled numerical models of the tunnel and surrounding soil will be developed, combining finite element with boundary element and perfectly matched layer formulations. These models will be used
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models. Expected Results: Ability to assess the influence of demise process on the release of emissions into different atmospheric layers. Numerical model to describe the temporal and spatial dispersion
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physics https://www.tuni.fi/en/about-us/computational-physics Modeling and simulations have an increasing role in fundamental sciences and they are also pivotal in the analysis, interpretation and
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fabrication of chiral nanostructures. Numerical modelling (typically, FDTD). Optical characterization (microscopy, near-field imaging, fluorescence lifetime measurements, etc.). Writing scientific articles
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of emissions of greenhouse gases. The reason for most of this uncertainty is that clouds are especially challenging to represent in numerical models of the atmosphere. Clouds affect the Earth’s radiation
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advanced research in structural health monitoring, including hardware development. Perform numerical studies and model testing. Analyze and interpret data to provide recommendations for system design and
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, specifically in numerical hydrological modelling and hydrological field measurements. The successful candidate will work on competitive research projects and knowledge transfer contracts involving hydrology
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models. Dr. Gao's lab advances foundational and system-level language technologies with the goal of enabling reliable, efficient, and clinically meaningful real-world applications, particularly in medicine
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: Perform high-fidelity thermal and mechanical numerical simulations for metal additive manufacturing. Develop and implement PIML models for analysis and optimization of metal additive manufacturing