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amorphous ice matrices, evolve from molecular clouds through star-forming regions to planetary systems. Laboratory simulations under astrophysically relevant conditions will provide key insights
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conducting a pilot temporal and regional assessment of exposure dynamics. The candidate will also investigate the statistical associations between carcinogens concentration in the different biological matrices
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. Science 352, 208–212 (2016). In ICE-EEVOLVE, we seek to unravel how chiral organic molecules, trapped in amorphous ice matrices, evolve from molecular clouds through star-forming regions to planetary
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complex matrices [1-5]. To achieve this objective, the production of calcium carbonate grease will be replicated on a laboratory scale to reproduce the particle morphology. This system will be coupled with
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performance. The impact of this process will be investigated, considering its impact on the compressibility and transfer properties of the mixtures. Successful candidate will engage in interdisciplinary
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, such waste is more reactive than massive parts. The debris and powders are likely to react significantly by redox reaction with the water contained in the porous network of the cementitious matrices, thus
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, such as X-ray crystal structure determination and solidstate photophysical studies, is essential. Experience in embedding molecular materials into polymer matrices would be a plus, as well as in quantum
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water/loose rock matrices such as fine gravels and coarse sands. In a first step, it will be a matter of studying and optimizing the vectorization as well as the ranges of action and influence of chemical