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http://dx.doi.org/10.3365/KJMM.2011.49.4.281

Selective Surface Oxidation of 590MPa TRIP Steel and Its Effect on Hot-Dip Galvanizability  

Kim, Seong-Hwan (Department of Materials Science & Engineering, Korea University)
Im, Jun-Mo (Department of Materials Science & Engineering, Korea University)
Huh, Joo-Youl (Department of Materials Science & Engineering, Korea University)
Lee, Suk-Kyu (POSCO Technical Research Laboratories)
Park, Rho-Bum (POSCO Technical Research Laboratories)
Kim, Jong-Sang (POSCO Technical Research Laboratories)
Publication Information
Korean Journal of Metals and Materials / v.49, no.4, 2011 , pp. 281-290 More about this Journal
Abstract
In order to gain better understanding of the selective surface oxidation and its influence on the galvanizability of a transformation-induced plasticity (TRIP) assisted steel containing 1.5 wt.% Si and 1.6 wt.% Mn, a model experiment has been carried out by depositing Si and Mn (each with a nominal thickness of 10 nm) in either monolayers or bilayers on a low-alloy interstitial-free (IF) steel sheet. After intercritical annealing at $800^{\circ}C$ in a $N_2$ ambient with a dew point of $-40^{\circ}C$, the surface scale formed on 590 MPa TRIP steel exhibited a microstructure similar to that of the scale formed on the Mn/Si bilayer-coated IF steel, consisting of $Mn_{2}SiO_{4}$ particles embedded in an amorphous $SiO_{2}$ film. The present study results indicated that, during the intercritical annealing process of 590 MPa TRIP steel, surface segregation of Si occurs first to form an amorphous $SiO_{2}$ film, which in turn accelerates the out-diffusion of Mn to form more stable Mn-Si oxide particles on the steel surface. During hot-dip galvanizing, particulate $Fe_{3}O_{4}$, MnO, and Si-Mn oxides were reduced more readily by Al in a Zn bath than the amorphous $SiO_{2}$ film. Therefore, in order to improve the galvanizability of 590 TRIP steel, it is most desirable to minimize the surface segregation of Si during the intercritical annealing process.
Keywords
metals; annealing; oxidation; scanning electron microscopy; TRIP steel; hot-dip galvanizing;
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