Enhancing the Hydrogen Embrittlement Resistance of Medium Mn Steels by Designing Metastable Austenite with a Compositional Core-shell Structure

doi:10.1007/s40195-022-01483-7

Abstract

Abstract:

Deformation-induced martensite transformation from metastable retained austenite is one of the most efficient strain-hardening mechanisms contributing to the enhancement of strength-ductility synergy in advanced high-strength steels. However, the hard transformation product (often $\alpha^{\prime}$-martensite) and the H redistribution associated with phase transformation essentially decrease materials’ resistance to hydrogen embrittlement. To solve this fundamental conflict, we introduce a new microstructure architecting strategy based on an accurately design of core–shell compositional distribution inside the austenite phase. We employed this approach in a typical medium Mn steel (8 wt.% Mn) with an ultrafine grained austenite-ferrite microstructure. We produced a high Mn content (15–16 wt.%) in the austenite shell region and a low Mn content (~12 wt.%) in the core region, through a thermodynamics-guided two-step austenite reversion treatment. During room-temperature deformation, the austenite core transforms continuously starting from a low strain, providing a high and persistent strain-hardening rate. The transformation of Mn-rich austenite shell, on the other hand, occurs only at the latest regime of the deformation, thus effectively inhibiting the nucleation of H-induced cracks at ferrite/deformation-induced martensite interfaces as well as suppressing their growth and percolation. This step-wise transformation, tailored directly targeted to protect the hydrogen-sensitive microstructure defects (interfaces), results in a significantly enhanced hydrogen embrittlement resistance without sacrificing the mechanical performance in hydrogen-free condition. The design of compositional core–shell structure is expected to be applicable to, at least, other multiphase advanced high-strength steels containing metastable austenite.ss

Key words: Medium Mn steels, Hydrogen embrittlement, Core–shell austenite, Chemical heterogeneity, Deformationinduced martensite transformation

Jun Zhang, Binhan Sun, Zhigang Yang, Chi Zhang, Hao Chen. Enhancing the Hydrogen Embrittlement Resistance of Medium Mn Steels by Designing Metastable Austenite with a Compositional Core-shell Structure[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(7): 1059-1077.

Figures/Tables 15

Fig. 1 Sketch of the processing routes of one-step and two-step ART sample

Fig. 2 a, b Secondary electron (SE) images and EBSD phase-image quality (Phase-IQ) maps of the one-step a and two-step b ART sample; c EBSD inverse pole figure (IPF) map, Phase-IQ map and the corresponding SE image taken at the white box in the Phase-IQ map of b, showing the detailed morphology, phase condition and crystallographic orientation of the core-shell austenite in the two-step ART sample. (For interpretation of the references to color in this figure legend, the reader is referred to the Web version of this article.)

Table 1 Statistical analysis showing the proportion of different types of core-shell austenite grains and the proportion of grains with different shell thickness

Type	Proportion (%)	Thickness of $\gamma$ shell (nm)	Proportion (%)
$\gamma$ core fully enclosed by shell	34.5	< 100	32.0
$\gamma$ core fully enclosed by shell	34.5	100-200	50.4
$\gamma$ core partially enclosed by shell	65.5	200-300	13.4
		300-400	2.5
		> 400	1.7

Fig. 3 Mn distribution in austenite of one-step a, c, e, g and two-step b, d, f, h ART sample measured by AES-EBSD a-d and STEM-EDX e-h. a, b EBSD Phase-IQ maps of the one-step a and two-step b ART sample; c, d profiles of Mn intensity measured along the AES scanning line in a, b, and the insert shows the SEM morphology of the measured austenite grain; e, f STEM bright field (BF) images and the corresponding EDX maps of Mn of one-step e and two-step f ART sample. The white solid and dash closed curves show the core-shell austenite with distinct Mn enrichment in the shell region; g, h profiles of Mn content taken along the arrow in the EDX map

Fig. 4 Electrochemical H permeation curves of the one-step and two-step ART sample

Table 2 H permeation test results of the one-step and two-step ART sample

Sample	Sample thickness (mm)	Lag time (s)	Effective diffusivity (m²/s)	Flux at steady state (mol/m²/s)	Sub-surface H concentration (mol/m³)
One-step ART	0.152	3660	1.05 $\times$ 10^–12	1.42 $\times$ 10^–7	20.6
Two-step ART	0.146	3008	1.18 $\times$ 10^–12	1.41 $\times$ 10^–7	17.5

Fig. 5 a, b Engineering stress–strain curves of the uncharged and H-charged (at current densities of 5 mA/cm2 and 60 mA/cm2) one-step a and two-step b ART sample; c the work hardening rate of the uncharged samples; d HE resistance index (HERI) as a function of current density of H charging, where ${\text{TEL}}_{{\text{H}}}$ and ${\text{TEL}}_{0}$ are the total elongation for the H-charged and uncharged specimen, respectively

Table 3 Slow-strain-rate tensile properties before and after H-charging at current densities of 5 and 60 mA/cm2 of one-step and two-step ART samples

Sample	Current density of H-charging (mA/cm²)	Lower yield strength (MPa)	Tensile strength (MPa)	Yield point elongation (%)	Uniform elongation (%)	Total elongation (%)	HE resistance index (%)
	0	940	1106	11.8	42.0	44.8	-
One-step ART	5	943 $\pm$ 12	993 $\pm$ 6	12.7 $\pm$ 0.5	-	17.6 $\pm$ 0.5	39.3 $\pm$ 1.1
	60	951 $\pm$ 6	950 $\pm$ 5	-	-	3.5 $\pm$ 0.7	7.8 $\pm$ 1.5
	0	931	1092	13.3	41.6	44.3	-
Two-step ART	5	923 $\pm$ 1	1026 $\pm$ 7	14.1 $\pm$ 0.7	-	25.5 $\pm$ 0.4	57.7 $\pm$ 0.8
	60	918 $\pm$ 3	964 $\pm$ 10	13.9 $\pm$ 0.8	-	17.2 $\pm$ 0.2	39.0 $\pm$ 0.5

Fig. 6 SEM images of the fracture surface of one-step a-c and two-step d-f ART samples. a, d Uncharged; b, e near-edge region of H-charged samples; c, f region located at ~ 100 μm away from the edge of H-charged samples. Arrowheads in b, c and e indicate intergranular facets. (The current density of H-charging is 60 mA/cm2.)

Fig. 7 Ex situ EBSD results of one-step ART sample (SEM images, EBSD Phase-IQ maps and IPF ($\gamma$) maps), showing two types of martensite transformation of individual austenite grains: a fully transformed at low strain (~ 12%); b transformation persisted at higher strain

Fig. 8 Ex situ EBSD results of martensite transformation of core–shell austenite grains in the two-step ART sample (SEM images, EBSD Phase-IQ maps and IPF ($\gamma$) maps): a complete transformation of both core and shell region into martensite at low strain (~ 12%); b stepwise transformation with the shell region transformed first; c stepwise transformation with the core region transformed first followed by the shell region; d almost no transformation occurred at analyzed strain levels

Fig. 9 Proportion of different types of martensitic transformation behavior in the one-step and two-step ART sample

Fig. 10 a, b SEM images of the deformed region of H-charged (at current density of 60 mA/cm2) one-step a and two-step b ART sample stretched to a macroscopic strain approximately equal to one fifth of the YPE; c, d SEM images, EBSD Phase-IQ maps and IPF maps of the magnified regions near the main cracks in a, b, showing the formation of micro-cracks in H-charged one-step c and two-step d ART sample. The inset in d2 is the profile of Mn intensity measured along the AES scanning line, showing the Mn enrichment in the austenite shell. $\alpha$ represents ferrite and $\alpha^{\prime}$ stands for $\alpha^{\prime}$-martensite, which is distinguished based on the combination of SEM morphology and EBSD image quality map. PAGB represents prior-austenite grain boundaries

Fig. 11 a Phase-IQ map and the STEM-EDX measurements of the sample subjected to the first ART at 700 °C. The Mn profile is taken along the arrow in the EDX map of the corresponding STEM BF image. The inset in the Phase-IQ map is the setup of the DICTRA simulation; b length change during the first and second ART (note: the cooling stage after the first ART and the reheating stage of the second ART are not simulated here and they should not influence the dilatometry results as no phase transformation is expected during these two stages); c the simulated evolution of Mn profiles during the second ART; d magnified profiles taken at the black-dash rectangular frame in c; e EDX mapping of the two-step ART sample showing the Mn-depleted region in the ${\alpha }$ side near the phase boundary. The Mn profile is taken along the arrow in the EDX map, showing the Mn gradient inside austenite

Fig. 12 Schematic illustration showing the H-induced cracking behavior in one-step ART sample a, sample with randomly-distributed Mn-rich zone inside austenite [26] b and two-step ART sample with core–shell austenite c. With regard to intergranular cracking, only cracking along $\alpha$/$\alpha^{^{\prime}}$-martensite interface is presented for better comparison, as it is the most prevalent cracking behavior in H-charged MMS

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