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Field
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of ice crystals can dehydrate air in the upper troposphere and lower stratosphere (UTLS) region, thereby influencing the water vapor budget of this region. Aerosols and cirrus are important to the global
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workflows for descriptor based microstructure reconstruction to identify material parameters for crystal plasticity simulations from experimental data through inverse analysis to establish structure–property
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, altermagnets, and new classes of compensated spin-split systems. These materials exhibit magnetic order without conventional ferromagnetism, offering new routes to functional behaviour rooted in crystal symmetry
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proximity readout. This combination enables sub-100 ps time-of-flight (TOF) precision and millimetre-scale spatial resolution, surpassing the limits of conventional crystal-based scanners. The Xe-LAr offers
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the QuantERA project " Collective quantum phenomena in dissipative systems – towards time-crystal applications in sensing and metrology (CoQuaDis)". The CoQuaDis project aims to study many-body phases in open
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unstudied new 2D materials, synthesise them and understand the full range of their properties. This means subjecting crystals of interesting new compounds to ultra-high pressures and magnetic fields, all
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or local plasticity effects. The austenite transformation into martensite, induced either thermally or mechanically, brings along a 3% volume expansion of the crystal lattice. Such a transformation could
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developing better models for fragmentation of metals that include a consideration of the structure at the micro-scale, linking this to fragment formation at the macro-level. This will build on work in crystal
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on fatigue damage in metallic materials. We will employ 3-D crystal plasticity models in order to understand the role of compositional changes in fatigue damage. We will correlate these changes with a
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Institute of Low Temperature and Structure Research Polish Academy of Sciences | Poland | 5 days ago
an increase in crystal field strength. This compression raises the energy of the 4T2 level, thereby reducing the spin-orbit coupling between the 2E and 4T2 levels. Consequently, the luminescence kinetics