Influence of Substitutional Atoms on the Solubility Limit of Carbon in B.c.c. Iron

Hajime Saitoh; Kohsaku Ushioda; Naoki Yoshinaga

doi:10.4028/www.scientific.net/MSF.706-709.2348

Paper Titles

Kinetics of Grain Refinement by Warm Deformation of 304-Type Stainless Steel
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Effect of Bake-Hardening Treatment on the Mechanical Properties of High Strength Bainitic Steel Produced by Thermomechanical Processing
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Microstructure Control of a Low Carbon Martensitic Stainless Steel by Quenching and Partitioning Heat Treatment
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Influence of Matrix Structure and Hard Carbide on Abrasive Resistance of Steel Plates
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Influence of Substitutional Atoms on the Solubility Limit of Carbon in B.c.c. Iron
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On the Methodology of Thermal Desorption Spectroscopy to Evaluate Hydrogen Embrittlement
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Fatigue Property of a 2.8GPa Grade Maraging Steel
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Effect of Electric Current Direction on Texture Evolution in a Cold Rolled Fe-3%Si Steel under Electric Current Pulses Treatment
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Effects of Magnetic Field Intensity on Carbon Diffusion in Pure Iron in the Single-Phase Austenite Region
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Influence of Substitutional Atoms on the Solubility Limit of Carbon in B.c.c. Iron

Abstract:

No clear-cut information is available with regard to the effect of foreign atoms on the solubility limit of C in b.c.c. iron despite many previous studies. Against this backdrop, the influence of substitutional atoms (Mn, Cr, P, Si, Al) on the solubility limit of C in b.c.c. iron in equilibrium with cementite was investigated in low-carbon steels at a temperature of 700°C. In detail, the C solubility limit was determined from internal friction measurements combined with infrared analysis of C using a high-frequency combustion technique. It has been clarified that Mn, Cr, and Al hardly change the C solubility limit, whereas P and Si increase it. The thermodynamical calculation indicates that, under para equilibrium Si increases the C solubility limit and Mn hardly changes it, while under ortho equilibrium Mn and Si decrease it. However, the present experimental condition was verified to be close to ortho form. The discrepancy between the experiments and the calculations seems to come from the fact that: 1) single solute C atoms and the C atoms combined as Substitute-C complex are not distinguished experimentally, and 2) in the regular solution model, the non-uniform distribution of C atoms around alloying atoms is not introduced into the entropy term, which is something that should be studied further in the future.