Recent Advances on the Corrosion Resistance of Low-Density Steel: A Review

doi:10.1007/s40195-021-01369-0

Abstract

Abstract:

This paper reviews the previous literature on the alloy composition design of low-density steel (LDS), focusing on the effect of Al, Mn, Ni, and other alloy elements on the formation of the steel matrix and second phase, and provides classification. The microstructure of LDS after processing includes the matrix structure, к-carbide, and B2 (FeAl, NiAl, or MnAl) phase of ferritic LDS, austenitic LDS, and dual-phase LDS. The influence of alloy elements on the corrosion resistance of LDS is derived from the addition of Al and Mn for metallurgy. Additionally, the influence of Cr and Mo addition on the corrosion resistance improvement was studied. The electrochemical properties of the corrosion process in LDS are discussed. Further, the microstructure of LDS affects the corrosion resistance properties including pitting corrosion, hydrogen embrittlement, and SCC (stress corrosion cracking). Finally, future research directions are proposed.

Key words: Low-density steel, Alloy element adjustment, Microstructure, Corrosion resistance

Chao Liu, Yilun Li, Xuequn Cheng, Xiaogang Li. Recent Advances on the Corrosion Resistance of Low-Density Steel: A Review[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(7): 1055-1067.

Figures/Tables 12

Fig. 1 Typical heat treatment processes of a ferrite LDS [25,26,27,28,29], b austenitic LDS [5,19,30,33,34,35,36,37,38,39,41,49], c duplex LDS [16,32,40,42,43,44,45,55]

Fig. 2 a APT maps of C, Mn, and Al for Fe-3.2Mn-10Al-1.2C [51], b characteristics of the optical microstructures of Fe-7Al in hot-rolled condition [26], c IPF maps of Fe-8Al-5Mn alloy after cold rolling and annealing at 750 °C for 1 h [28], d TEM micrograph of NbC and к-carbide along grain boundary of Fe-8Al-5Mn-0.1Nb-0.1C [28], e statistical of mechanical properties of ferrite LDS with different compositions [14,25,26,28,29]

Fig. 3 Statistical of mechanical properties of ferrite LDS with different compositions and different heat treatments [2,5,21,30,34,36,37,38,39,41,49,53]

Fig. 4 a Direct 1:1 correlation of atomic resolution STEM and APT of Fe-26.7Mn-14.0Al-5.3C alloy, b APT concentration profile extracted across the horizontal γ/κ interface highlighted by the arrow in a [31], TEM dark-field micrographs and selected-area diffraction patterns of c Fe-28Mn-9Al-0.8C alloy aged at 625 °C for 3 h and d Fe-25.7Mn-10.6Al-1.2C alloy [35]

Fig. 5 a TEM bright-field image and corresponding SADPs of austenite and B2 in Fe-21Mn-10Al-1C-5Ni alloy, EBSD phase map b and KAM c of austenite grains in Fe-21Mn-10Al-1C-5Ni alloy annealed at 900 °C for 15 min [5]

Fig. 6 a Microstructure of Fe-26Mn-6.2Al-0.05C steel after hot rolling at 900-1100 °C [44], b statistical of mechanical properties of duplex LDS with different compositions [5,16,32,40,42,43,44,45], c TEM bright-field images of Fe-15Mn-7Al-0.8C alloy tensioned at strains of 5% and 10% [32]

Fig. 7 a Microstructure and EDX maps of Fe-31.1Mn-9.07Al-0.89C alloy corroded at 750 °C for 4 h, b XRD analyses of scale formed on Fe-30.1Mn-8.05Al-0.88C-3.04Cr alloy corroded at 850 °C for 24 h [56]

Fig. 8 Three alloys (A: Fe-22.6Mn-6.3Al-3.1Cr-0.68C, B: Fe-28Mn-5.2Al-5.1Cr-2.8Si-0.95C, C: MBIP) (Fe-30Mn-8.5Al-3.2Cr-1.1C) in 3.5 wt% NaCl solution of a XRD pattern of surface corrosion products, b Nyquist plots, c Bode plots [62]

Fig. 9 Effect of alloying elements and solution environment on a Ecorr and b Icorr in LDS [60], c potentiodynamic polarization curves of the five Fe-Mn-Al alloys (A-Fe-28.52Mn-9.97Al-1.047C, B-Fe-29.6Mn-10.19Al-0.832C, C-Fe-28.63Mn-10.45Al-0.498C, D-Fe-29.99Mn-10.19Al-0.305C, and E-Fe-21.5Mn-9.86Al-0.33C-6.32Cr) in deaerated 3.5% NaCl solution [11]

Fig. 10 Pitting corrosion morphology of Fe-30Mn-5Al-0.5C (a) and Fe-30Mn-5Al-0.5C-(b) 3Cr (c) 6Cr (d) 9Cr steels after hot rolling and immersion in 0.1 M NaCl solution for 30 min [72], e cyclic polarization curves for thermo-mechanical processed Fe-30Mn-5Al steel in deaerated 0.1 M NaCl solution and f XPS spectra for Cr 2p3/2 of Fe-30Mn-5Al steels with 3, 6, and 9 wt% Cr [72], g polarization curves of Fe-29.8Mn-10.7Al-1.13C-XMo-XCr steels measured in a 0.6 M NaCl solution, h chemical composition depth profiles in the passivated layers of 3Mo-3Cr alloys, and i pit initiation sites of Fe-29.2Mn-10.6Al-1.13C-5Cr [65]

Fig. 11 Fractographs of alloy a Fe-27.7Mn-8.9Al-0.42C in 3.5% NaCl and b Fe-24.4Mn-9.96Al-0.4C in 3.5% NaCl [10], c intergranular secondary crack in alloy Fe-32.16Mn-9.41Al-0.93C applied potential of -1,200 mV, d fracture surface of alloy Fe-32.67Mn-9.42Al-0.91C at -1,300 mV in 3.5% NaCl solution [12], e cracks caused by corrosion at material defects in Fe-31.3Mn-8.8A1-0.9C alloy [12], f side surface of cracks in Fe-27.7Mn-8.9A1-0.42C alloy in 3.5% NaCl solution [10]

Fig. 12 a Formation mechanism of the oxide formation in Fe-Mn-Al steels during hydrogen charging [84], b RD-IPF map, and c KAM map of hydrogen-related subcracks caused by slip localization in Fe-25.7Mn-10.6Al-1.16C alloy [85]

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