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Electromagnetic levitation containerless processing of metallic materials in microgravity: thermophysical properties.

M MohrY DongG P BrackerR W HyersDouglas M MatsonRobert ZborayRuggero FrisonAlex DommannA NeelsXiao XiaoJ BrilloRalf BuschRada NovakovicP SrirangamH-J Fecht
Published in: NPJ microgravity (2023)
Transitions from the liquid to the solid state of matter are omnipresent. They form a crucial step in the industrial solidification of metallic alloy melts and are greatly influenced by the thermophysical properties of the melt. Knowledge of the thermophysical properties of liquid metallic alloys is necessary in order to gain a tight control over the solidification pathway, and over the obtained material structure of the solid. Measurements of thermophysical properties on ground are often difficult, or even impossible, since liquids are strongly influenced by earth's gravity. Another problem is the reactivity of melts with container materials, especially at high temperature. Finally, deep undercooling, necessary to understand nucleus formation and equilibrium as well as non-equilibrium solidification, can only be achieved in a containerless environment. Containerless experiments in microgravity allow precise benchmark measurements of thermophysical properties. The electromagnetic levitator ISS-EML on the International Space Station (ISS) offers perfect conditions for such experiments. This way, data for process simulations is obtained, and a deeper understanding of nucleation, crystal growth, microstructural evolution, and other details of the transformation from liquid to solid can be gained. Here, we address the scientific questions in detail, show highlights of recent achievements, and give an outlook on future work.
Keyphrases
  • solid state
  • molecular dynamics
  • high frequency
  • high temperature
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  • machine learning
  • molecular dynamics simulations
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  • big data
  • electronic health record