This chapter highlights the effect of G and v on the
secondary dendrite arm spacing (SDAS) in purely diffusion circumstances,
analysed the thermal data of the experiments in detail, and take into account
the macrosegregation caused by the diffusion of Si from the initial mushy zone
during the homogenization step of experiments. During the solidification of
hypoeutectic alloy (like Al-7% Si), density difference develops in the melt
generated by concentration and temperature difference. On Earth, as an effect
of this density difference, the melt can flow due to gravity affecting the
solidified microstructure. The developing meso- and micro-structures are also
significantly affected by the melt flow occurring during the solidification
processes in different casting technologies. This melt flow can be eliminated
in a microgravity environment, which then makes it possible to examine the
solidification process under conditions of pure diffusion. In the Materials
Science Lab (MSL) on board the International Space Station (ISS), four
solidification experiments were conducted on grain refined and non-grain
refined Al-7wt% Si alloy to investigate the effects of the solidification
parameters (solid/liquid front velocity
v, temperature gradient G) on the dendritic microstructures and the grain
structure. A detailed analysis of the grain structure was conducted in a few
previous articles. The macrosegregation was calculated by the Finite Different
Method. Because the steady-state solidification conditions were never reached,
the solidification process was characterized by the average front velocity and
temperature gradient. It is shown that steady-state solidification conditions
are never reached. At a given sample position, the velocity of the solid/liquid
S/L) and the eutectic/liquid (E/L) fronts and the temperature gradient at the
two fronts are different. Then, the solidification process can be characterized
by the average front velocity and average temperature gradient.
András Roósz,
HUN REN- University of Miskolc, Materials Science Research Group, Hungary and Institute of Physical Metallurgy, Metal Forming, and Nanotechnology, University of Miskolc, Hungary.
Arnold Rónaföldi,
HUN REN- University of Miskolc, Materials Science Research Group, Hungary and Institute of Physical Metallurgy, Metal Forming, and Nanotechnology, University of Miskolc, Hungary.
Yuze Li,
School of Physical Science and Technology, Northwestern Polytechnical University, Xi’an, 710100, China.
Nathalie Mangelinck-Noël,
Aix Marseille University, Université de Toulon, CNRS, IM2NP, 13013 Marseille, France.
Gerherd Zimmermann,
ACCESS e.V., Intzestrasse 5, Aachen, Germany.
Henri Nguyen-Thi,
Aix Marseille University, Université de Toulon, CNRS, IM2NP, 13013 Marseille, France.
Mária Svéda,
HUN REN- University of Miskolc, Materials Science Research Group, Hungary.
Zsolt Veres,
HUN REN- University of Miskolc, Materials Science Research Group, Hungary and Institute of Physical Metallurgy, Metal Forming, and Nanotechnology, University of Miskolc, Hungary.
Please see the link here: https://stm.bookpi.org/EMMSMFMSA/article/view/13079
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