Surface Tension and Density of Fe–Mn Melts

The article presents original experimental data on surface tension of the Fe 100 – x Mn x ( x = 4–13 wt %) melts. Surface tension and density of the melt were measured by the sessile drop method at heating from the liquidus temperature to 1780°C and subsequent sample cooling in the atmosphere of hig...

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Bibliographic Details
Published in:Steel in translation 2020, Vol.50 (1), p.16-21
Main Authors: Sinitsin, N. I., Chikova, O. A., V’yukhin, V. V.
Format: Article
Language:English
Subjects:
Chemistry and Materials Science
Cooling
Density
Entropy
Iron
Liquidus
Manganese
Materials Science
Melts
Sessile drop method
Surface tension
Viscosity
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Summary:The article presents original experimental data on surface tension of the Fe 100 – x Mn x ( x = 4–13 wt %) melts. Surface tension and density of the melt were measured by the sessile drop method at heating from the liquidus temperature to 1780°C and subsequent sample cooling in the atmosphere of high-purity helium. Temperature and concentration dependences of surface tension and density of Fe–Mn melts were plotted. Manganese is a surface-active substance in iron melt. The value of surface tension coefficient of Fe–Mn melts decreases as Mn content increases. Experimental data on the surface tension of Fe–Mn melts is consistent with the theoretical dependences (the Pavlov–Popel’ equation and the Shishkovsky equation). During the investigation of Fe–Mn melt microheterogenity, correlation between the values of kinematic viscosity, surface tension, and density is revealed. Fluidity dependence of Fe–Mn melts on their density in the cooling mode has a linear character which indicates satisfaction of the Bachinskii law. Discrepancy in the melt viscosity ratios to the surface tension coefficient obtained from the experimental data and from the empirical formula is discovered. Using the experimental data on viscosity and surface tension of Fe–Mn melts, the entropy change in the melt’s bulk and the change in the melt’s surface entropy, respectively, are studied. The surface entropy and the bulk entropy in the melt decrease in their absolute value with its increasing Mn content. From the study results, it is concluded that there is no destruction of the microheterogeneous structure of Fe 100 – x Mn x ( x = 4–13 wt %) melts when heated up to 1780°C.
ISSN:0967-0912
1935-0988
DOI:10.3103/S0967091220010118