Ground-Based Diffusion Experiments on Liquid Sn-In Systems Using the Shear Cell Technique of the Satellite Mission Foton-M1

: This study reported in this paper was aimed at testing the shear cell that was developed for the satellite mission Foton‐M1 to measure diffusion coefficients in liquid metals under microgravity (μg)‐conditions. Thick Layer diffusion experiments were performed in the system Sn90In10 versus Sn under...

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Bibliographic Details
Published in:Annals of the New York Academy of Sciences 2004-11, Vol.1027 (1), p.169-181
Main Authors: SUZUKI, SHINSUKE, KRAATZ, KURT-HELMUT, FROHBERG, GÜNTER
Format: Article
Language:English
Subjects:
Capillaries
Diffusion
Foton
ground experiment
Indium - chemistry
liquid metal
Macromolecular Substances
microgravity
Models, Theoretical
Physics - methods
shear cell
Sn-In
Space Flight
Spacecraft
Stress, Mechanical
Systems Theory
Temperature
Time Factors
Tin - chemistry
Weightlessness
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Summary:: This study reported in this paper was aimed at testing the shear cell that was developed for the satellite mission Foton‐M1 to measure diffusion coefficients in liquid metals under microgravity (μg)‐conditions. Thick Layer diffusion experiments were performed in the system Sn90In10 versus Sn under 1 g‐conditions. For this system several μg‐diffusion results are available as reference data. This combination provides a low, but sufficiently stable, density layering throughout the entire experiment, which is important to avoid buoyancy‐driven convection. The experimental results were corrected for the influences of the shear‐induced convection and mixing after the final shearing, both of which are typical for the shear cell technique. As the result, the reproducibility and the reliability of the diffusion coefficients in the ground‐based experiments were within the limits of error of μg‐data. Based on our results we discuss the necessary conditions to avoid buoyancy‐driven convection.
ISSN:0077-8923
1749-6632
DOI:10.1196/annals.1324.016