The influence of aluminum nitride (AlN) precipitation on the hot ductility of medium manganese steels was investigated using hot tensile testing, as good hot ductility is essential for continuous casting. A reasonable hot ductility is reached up to 0.04% and at 1.6% aluminum. At 0.04% only few AlN precipitates due to slow kinetics. At 1.6%, coarse AlN precipitates at high temperatures, minimally affecting hot ductility. In contrast, 0.6% aluminum leads to significant ductility loss due to AlN precipitating at γFe grain boundaries. At 1% aluminum, higher nitrogen contents only slightly reduce hot ductility. Thus, hot ductility is mainly influenced by AlN precipitation from γFe. SEM-EDX analysis confirmed that fine AlN at γFe grain boundaries correlate with poor hot ductility.
XuHCaoWDongH, et al.Effects of aluminium on the microstructure and mechanical properties in 0.2C-5Mn steels under different heat treatment conditions. ISIJ Int2015; 55: 662–669.
2.
SuhDWRyuJHJooMS, et al.Medium-Alloy manganese-rich transformation-induced plasticity steels. Metall Mater Trans A2013; 44: 286–293.
3.
KaarSSchneiderRKrizanD, et al.Influence of the phase transformation behaviour on the microstructure and mechanical properties of a 4.5 wt.-% Mn Q&P steel. HTM J Heat Treat Mater2019; 74: 70–84.
4.
KaarSKrizanDSchneiderR, et al.Impact of si and Al on microstructural evolution and mechanical properties of lean Medium manganese quenching and partitioning Steels. Steel Res Int2020; 91: 1–7.
5.
WallnerMSteinederKSchneiderR, et al.Effect of galvannealing on the microstructural and mechanical properties of a si and Al alloyed medium-Mn quenching and partitioning steels. Mater Sci Eng A2022; 841: 1–13.
6.
WallnerMSchneiderRSteinederK, et al.Effect of Si and Al on microstructure-property-relationship of Q&P-steels during galvannealing. Mat Sci Tech2021; 37: 182–189.
7.
SchneiderRKaarSKrizanD, et al.Comparison of the hardness-toughness relationship of Medium-Mn steels after Q&T and Q&P treatments. HTM J Heat Treat Mater2021; 6: 445–457.
8.
GramlichASchmiedlTSchönbornS, et al.Development of air-hardening martensitic forging steels. Mater Sci Eng A2020; 784: 1–6.
9.
MahieuJMakiJDe CoomanBC, et al.Phase transformation and mechanical properties of Si-free CMnAl transformation-induced plasticity-aided steel. Metall Mater Trans A2002; 33: 2573–2580.
10.
PangJCXuBYWangGD, et al.Effect of silicon and aluminium in ferrite on tensile and impact properties. Mater Sci Technol2017; 33: 1806–1810.
11.
KaarSSteinederKSchneiderR, et al.New Ms-formula for exact microstructural prediction of modern 3rd generation AHSS chemistries. Scr Mater2021; 200: 1–4.
12.
GramlichAVan der LindeCAckermann, et al.Effect of molybdenum, aluminium and boron on the phase transformation in 4 wt.–% manganese steels. Results Mater2020; 8: 1–8.
13.
SugimotoKNakashimaYKobayashiJ, et al.Effects of partial replacement of si by Al on impact toughness of 0.2%C-Si-Mn-cr-B TRIP-aided martensitic steel. Metals2023; 13: 1–19.
14.
GulbayOGramlichAKruppU. Effects of silicon and aluminum alloying on phase transformation and microstructure evolution in Fe–0.2C–2.5Mn steel: insights from continuous–cooling–transformation and time–temperature–transformation diagrams. steel Research Int2024; 95: 1–12.
15.
DaiZChenHDingR, et al.Fundamentals and application of solid-state phase transformations for advanced high strength steels containing metastable retained austenite. Mater Sci Eng R Rep2021; 143: 1–39.
16.
AllamTBleckWKlinkenbergC, et al.The continuous casting behavior of medium manganese steels. J Mater Res Technol2021; 15: 292–305.
17.
MintzBQuabanA. The influence of precipitation, high levels of Al, Si, P and a small B addition on the hot ductility of TWIP and TRIP assisted steels: a critical review. Metals (Basel)2022; 12: 502–533.
18.
MintzBYueSJonasJJ. Hot ductility of steels and its relationship to the problem of transverse cracking during continuous casting. Int Mater Rev1991; 36: 187–220.
19.
MintzB. The influence of composition on the hot ductility of steels and to the problem of transverse cracking. ISIJ Int1999; 39: 833–855.
20.
HoflehnerCIlieSSixJ, et al.Influence of thermal history on the hot ductility of a continuously cast low alloyed Cr-Mo steel. J of Materi Eng and Perform2018; 27: 5124–5129.
21.
MintzBQabanA. Understanding the high temperature side of the hot ductility curve for steels. Mater Sci Technol2021; 37: 237–249.
22.
MintzB. Understanding the low temperature end of the hot ductility trough in steels. Mater Sci Technol2008; 24: 112–120.
23.
MintzBAbushoshaR. Effectiveness of hot tensile test in simulating straightening in continuous casting. Mater Sci Technol1992; 8: 171–177.
24.
BanksKTulingAKlinkenbergC, et al.Influence of Ti on hot ductility of Nb containing HSLA steels. Mat Sci Tech2011; 27: 537–545.
25.
GontijoMHoflehnerCIlieS, et al.Holding time influence on the hot ductility behavior of a continuously cast low alloy steel. Metals (Basel)2021; 11: 1–17.
26.
GuilletAYueSAkbenMG. Influence of heat treatment and carbon content on the hot ductility of Nb-Ti microalloyed steels. ISIJ Int1993; 33: 413–419.
27.
NagasakiCAizawaAKiharaJ. Influence of manganese and sulfur on hot ductility of carbon steels at high strain rate. Trans Iron Steel Inst Jpn1987; 27: 506–512.
28.
TulingABanerjeeJRMintzB. Influence of peritectic phase transformation on hot ductility of high aluminium TRIP steels containing Nb. Mater Sci Technol2011; 27: 1724–1731.
29.
HannerzNE. Critical hot plasticity and transverse cracking in continous slab casting wih particular reference to composition. Trans ISIJ1985; 25: 149–158.
30.
OuchiCMatsumotoK. Hot ductility in Nb-bearing high-strength low-alloy steels. Trans Iron Steel Inst Jpn1982; 22: 181–189.
31.
TulingAMintzB. Crystallographic and morphological aspects of AlN precipitation in high Al, TRIP steels. Mater Sci Technol2016; 32: 568–575.
32.
TulingA. The effect of precipitation and microstructure on hot ductility in high Al, Nb containing TRIP steels. PhD Thesis, University of London, UK, 2010.
33.
FunnellGDDaviesRJ. Effect of aluminium nitride particles on hot ductility of steel. Met Tech1978; 5: 150–153.
34.
ThomasBGBrimacombeJKSamarasekeraIV. The formation of panel cracks in steel ingots- A state-of-the-art review. ISS trans1986; 10: 7–20.
35.
OsinkoluGATacikowskiMKobylanskiA. Combined effect of AlN and sulphur on hot ductility of high purity iron-base alloys. J Mater Sci Technol1985; 7: 520–525.
36.
SuzukiHGNishimuraSImamuraJ, et al.Embrittlement of steels occurring in the temperature range from 1 000 to 60° C. Trans Iron Steel Inst Jpn1984; 24: 169–177.
37.
CroftNH. Solubility model to predict effects of aluminium and nitrogen contents on susceptibility of steel castings to intergranular embrittlement. Met Technol1983; 10: 285–290.
38.
KangSEBanerjeeJRMintzB. Influence of S and AlN on hot ductility of high Al, TWIP steels. Mater Sci Technol2012; 28: 589–596.
39.
AbushoshaRAyyadSMintzB. Influence of cooling rate and MnS inclusions on hot ductility of steels. Mater Sci Technol1998; 14: 227–235.
40.
KizuTUrabeT. Hot ductility of sulfur-containing low manganese mild steels at high strain rate. ISIJ Int2009; 49: 1424–1431.
41.
CarpenterKRKillmoreCRDippenaarR. Influence of isothermal treatment on MnS and hot ductility in low carbon, low Mn steels. Metall Mater Trans B2014; 45: 372–380.
42.
AbushoshaRVipondRMintzB. Influence of sulphur and niobium on hot ductility of as cast steels. Mater Sci Technol1994; 7: 1101–1107.
43.
LücklMWojcikTPovoden-KaradenizE, et al.Co-precipitation behavior of MnS and AlN in a low-carbon steel. Steel Res Int2018; 89: 1–9.
44.
AlbaMNabeelMDoganN. Effect of aluminium content on the formation of inclusions in Fe–5Mn– x Al steels. Ironmak Steelmak2021; 48: 379–386.
45.
GuoYWangMWangK, et al.Relation of embrittlement to phosphorus grain-boundary segregation for an advanced Ni–Cr–Mo RPV steel. J Mater Res Technol2022; 18: 2240–2249.
46.
LiJChengG. Hot ductility of Cr15Mn7Ni4N austenitic stainless steel slab. J Mater Res Technol2020; 9: 52–58.
47.
FixCBorrmannLElixmannSM, et al.Investigations on decreased high temperature ductility of different continuously cast steel grades. steel Research int2021; 92: 1–11.
48.
MintzB. Importance of Ar3 temperature in controlling ductility and width of hot ductility trough in steels, and its relationship to transverse cracking. Mater Sci Technol1996; 12: 132–138.
49.
BakhtiariSSharifiSIlieS, et al.Investigation of hot ductility behavior of micro-alloyed steel and the effect of strain rate and dynamic phase transformation on the 2nd ductility minimum. Materialwiss Werkstofftech2025; 56: 601–611.
50.
MintzBTulingADelgadoA. Influence of silicon, aluminium, phosphorus and boron on hot ductility of transformation induced plasticity assisted steels. Mater Sci Technol2003; 19: 1721–1726.
51.
CowleyAMintzB. Relative importance of transformation temperatures and sulphur content on hot ductility of steels. Mater Sci Technol2004; 20: 1431–1439.
52.
MintzBAbu-ShoshaRShakerM. Influence of deformation induced ferrite, grain boundary sliding, and dynamic recrystallisation on hot ductility of 0·1–0·75% C steels. Mater Sci Technol1993; 9: 907–914.
53.
StiebenA. Eigenschaften lufthärtender martensitischer Schmiedestähle mit Mangangehalten von 3–10%. PhD Thesis, RWTH Aachen, Germany, 2018.
54.
DavidDSchneiderRKlöschG, et al.Influence of alloying elements on the transformation behavior of Medium-manganese-steels. NETSUSHORI2024; 64: 187–192.
55.
PeisslPSchneiderRRahoferM, et al.The effect of niobium on the microstructure and phase transformation kinetics in low-carbon Medium manganese steels. HTM, J Heat Treat Mater2015; 6: 267–275.
56.
BadeshiaHKDH. Theory of Transformations in Steels. CRC Press, London, UK, 2021.
