Nucleation Analysis of Variant Transformed from Austenite with Σ3 Boundary in High-Strength Low-Alloy Steel

doi:10.1007/s40195-020-01118-9

Abstract

Abstract:

We elucidate here the effects of annealing twins on phase transformation products based on electron back-scatter diffraction analysis and corresponding microstructure visualization and quantification methods. Martensite and bainite were obtained by rapid continuous cooling and isothermal processing at different temperatures, respectively, which were designed to study variants formed in austenite with Σ₃ boundary. The isothermal transformation near martensite start (M_s) temperature was most conducive in obtaining the highest content of twin-related V₁/V₂ variant pair. Based on the classical nucleation theory of martensite and bainite, respectively, the role of austenite Σ₃ boundary in martensite and bainite transformation is illustrated.

Key words: Steel, Austenite Σ ₃ boundary, Variant, Phase transformation, Martensite, Bainite

Bin-Bin Wu, Zhi-Quan Wang, Cheng-Jia Shang, Yi-Shuang Yu, Devesh Misra. Nucleation Analysis of Variant Transformed from Austenite with Σ₃ Boundary in High-Strength Low-Alloy Steel[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(4): 523-533.

Figures/Tables 11

Fig. 1 Transition temperatures during rapid continuous cooling (100 °C/s) a, schematic diagram showing the heat treatment process b

Fig. 2 SEM micrographs and band contrast (BC) maps depicting boundary distribution: a, e quenching, b, f 400 °C, c, g 450 °C, d, h 500 °C (white line: 15°>θ>5°, black line: 45°>θ>15°, yellow line: θ>45°)

Fig. 3 Dilatation versus temperature during the whole transformation process of isothermal process: a 400 °C, b 450 °C, c 500 °C

Table 1 Hardness of isothermal transformation

Sample	Quenching	Isothermal treatment at 400 °C	Isothermal treatment at 450 °C	Isothermal treatment at 500 °C
Hardness (HV)	325 (±16)	305 (±7)	285 (±3)	273 (±11)

Table 2 Average orientation relationships (ORs)

Sample	OR
Quenching	119.9°, 9.0°, 196.6°
400 °C	120.6°, 9.2°, 196.0°
450 °C	122.1°, 9.2°, 194.6°
500 °C	117.4°, 8.6°, 198.7°

Fig. 4 Length fraction of inter-variant boundaries

Fig. 5 Inverse pole figure (IPF) showing coinciding variants a, band contrast map b, corresponding experimental and theoretical pole figure c of Quenching sample (white line: 15°>θ>5°, black line: θ>15°)

Fig. 6 IPF figure showing coinciding variants a, band contrast map b and corresponding experimental and theoretical pole figure c of 450 °C isothermal transformation sample (white line: 15°>θ>5°, black line: θ>15°)

Fig. 7 IPF figure showing coinciding variants a, band contrast map b and corresponding experimental and theoretical pole figure c of 500 °C isothermal transformation sample (white line: 15°>θ>5°, black line: θ>15°)

Fig. 8 Band contrast map a showing coinciding variants and grain boundary distribution and corresponding experimental b and theoretical pole figure c of 400 °C isothermal process (white line: 15°>θ>5°, black line: θ>15°)

Fig. 9 Schematic diagram a, experimental observation b of grain boundary nucleation for bainite transformation and schematic diagram of nucleation at the austenite Σ3 boundary for 450 c and 500 °C d isothermal transformation

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Nucleation Analysis of Variant Transformed from Austenite with Σ₃ Boundary in High-Strength Low-Alloy Steel

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