Compositional Variants of Cu-rich Precipitate in Thermally Aged Ferritic Steel

doi:10.1007/s40195-017-0661-9

Abstract

Abstract:

Atom probe tomography was utilized to investigate Cu precipitation in a high-strength low-alloy steel isothermally aged at 500 °C for 1, 4, 16, and 64 h after water-quenching from 900 °C. With prolonged aging time, the Cu-rich precipitates (CRPs) increased in size and decreased in number density, and gradually evolved from spheroidal to elliptical in morphology. The small CRPs were rich in a high amount of Fe and a certain amount of Ni and Mn at their early nucleation stage. The large CRPs with increased size due to extensive aging contained less Fe and more Cu at their later growth stage. Additionally, Ni and Mn were both readily to segregate at the CRP/matrix heterophase interfaces, and Mn was higher in content than Ni in the precipitate interior especially when the CRPs were large in size.

Key words: High-strength low-alloy steel, Thermal aging, Cu-rich precipitate, Atom probe tomography

Qingdong Liu, Yihua Chen, Chuanwei Li, Jianfeng Gu. Compositional Variants of Cu-rich Precipitate in Thermally Aged Ferritic Steel[J]. Acta Metallurgica Sinica (English Letters), 2018, 31(5): 465-470.

Figures/Tables 5

Fig. 1 APT reconstructed 3D distribution map of CRPs delineated by 10 at.% Cu isoconcentration surfaces in the steel samples isothermally aged at 500 °C for a 1 h, b 4 h, c 16 h, d 64 h. The CRPs marked by arrow are selected for further composition analysis

Fig. 2 Size distribution integrated with the average diameter (D p), number density (N v) of the CRPs in the steel samples quenched and aged at 500 °C for a 1 h, b 4 h, c 16 h,d 64 h

Fig. 3 Proxigram concentration profiles for Fe, Cu, Ni, and Mn with respect to 10 at.% Cu isoconcentration surfaces of the selected CRPs marked by arrow in Fig. 1, integrated with the APT reconstructed 3D atom maps, equivalent diameters, Dp, and composition of the separate CRPs. Steel samples aged at 500 °C for a 1 h, b 4 h, c 16 h, d 64 h

Fig. 4 a APT reconstructed 3D atom distribution map of Cu, Ni, Mn, C, Cr, Mo, Si, and Fe atoms in and around a selected CRP with elongated rod-shaped marked green rectangle in Fig. 1d. b Composition profile of the CRP along Z direction (blue line) in a, showing the redistribution behavior of the solute atoms across the precipitate. Sample tempered at 500 °C for 64 h

Fig. 5 Schematic illustration of compositional evolution of CRPs showing the distribution of Cu (red), Fe (gray), Ni (green), and Mn (blue) in the CRPs approaching their equilibrium composition

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