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to the viscoelastic behavior of polymeric foams under large deformations dynamic loadings. The objective is to simulate, using the finite element method, the response of these porous microstructures under complex
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simulation software modelling the dynamic behavior of dislocations (DDD) in 3 dimensions, coupled with a spectral solver based on FFT. The procedures must analyze the simulated 3D microstructures to compare
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Antarctica Ice Sheet. By combining high-resolution chemical mapping with detailed microstructural analyses—encompassing crystal shape and orientation, as well as bubble size and distribution—across basal ice
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the microstructure of these semi-crystalline polymers, alongside in-depth characterization to elucidate their structure-property relationships and enhance their performance in various energy-related applications
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, energy, transportation, and construction. The laboratory focuses on describing the relationships between processing, microstructure, and properties, using both experimental and modeling/simulation
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thermal stresses. Moreover, being able to correlate these properties with each other and link them to the microstructure of the fibers is an essential element for the development of new materials. Objective