The austenite–ferrite transformation of ultralow-carbon Fe–C alloy; transition from diffusion- to interface-controlled growth

The kinetics of the isochronal austenite (γ) → ferrite (α) transformation of ultralow-carbon Fe–C alloy were investigated for cooling rates in the range 5–20 K min −1 by high-resolution dilatometry and differential thermal analysis. The starting temperature of the transformation decreases with incre...

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Bibliographic Details
Published in:Acta materialia 2006-07, Vol.54 (12), p.3383-3393
Main Authors: Liu, Y.C., Sommer, F., Mittemeijer, E.J.
Format: Article
Language:English
Subjects:
Annealing
Applied sciences
Austenite–ferrite transformation
Cooling rate
Diffusion
Dilatometer
Dilatometry
Exact sciences and technology
Ferrite
Ferrous alloys
Growth
Interstitial Fe-based alloys
Iron and steel making
Maxima
Metals. Metallurgy
Transformations
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Summary:The kinetics of the isochronal austenite (γ) → ferrite (α) transformation of ultralow-carbon Fe–C alloy were investigated for cooling rates in the range 5–20 K min −1 by high-resolution dilatometry and differential thermal analysis. The starting temperature of the transformation decreases with increasing cooling rate. The transformation kinetics, as characterized by the formation rate of product (ferrite) phase, varies greatly with cooling rate. At a small cooling rate of 5 K min −1 the transformation rate curve has a multiple-peaked nature. Upon increasing the cooling rate from 5 to 20 K min −1, the first transformation rate maxima vanish gradually, and finally so-called normal transformation behavior, characterized by the (remaining) one maximum in the transformation rate curve, is observed. On the basis of microstructural analysis and thermodynamic and kinetic reasoning, it is shown that the first transformation rate maxima pertain to diffusion-controlled ferrite growth, whereas the later single, main transformation rate maximum is due to interface-controlled, massive transformation.
ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2006.03.029