Achieving the excellent intermediate-temperature strength–ductility synergy in a fine-grained FeCrNi-based medium entropy alloy with heterogeneous precipitation

Tianxiang Bai; Tuanwei Zhang; Zhiming Jiao; Jinyao Ma; Hui Chang; Jianjun Wang; Dan Zhao; Shengguo Ma; Zhouzhu Mao; Xiaoxiao Liu; Zhihua Wang

doi:10.1007/s12613-024-3034-1

International Journal of Minerals, Metallurgy, and Materials ›› 2025 DOI: 10.1007/s12613-024-3034-1

Research Article

Achieving the excellent intermediate-temperature strength–ductility synergy in a fine-grained FeCrNi-based medium entropy alloy with heterogeneous precipitation

Tianxiang Bai¹^,² ,
Tuanwei Zhang¹^,²^,^a ,
Zhiming Jiao¹^,² ,
Jinyao Ma¹^,²^,³ ,
Hui Chang¹^,² ,
Jianjun Wang¹^,² ,
Dan Zhao¹^,² ,
Shengguo Ma¹^,² ,
Zhouzhu Mao¹^,² ,
Xiaoxiao Liu¹^,² ,
Zhihua Wang¹^,²^,^b

Author information +

History +

Abstract

Fe–Cr–Ni austenitic alloys are extensively utilized in the hot-end components of nuclear light water reactors, turbine disks, and gas compressors. However, their low strength at elevated temperatures limits their engineering applications. In this study, a novel precipitation-strengthened alloy system is developed by incorporating Al and Si elements into a FeCrNi equiatomic alloy. The results indicate that the FeCrNiAl_xSi_x (at%, x = 0.1, 0.2) alloys possess heterogeneous precipitation structures that feature a micron-scale σ phase at the grain boundaries and a nanoscale ordered body-centered cube (B2) phase within the grains. An exceptional strength-ductility synergy across a wide temperature range is achieved in FeCrNiAl_0.1Si_0.1 alloys due to grain refinement and precipitation strengthening. Notably, a yield strength of 693.83 MPa, an ultimate tensile strength of 817.55 MPa, and a uniform elongation of 18.27% are attained at 873 K. The dislocation shearing mechanism for B2 phases and the Orowan bypass mechanism for σ phase, coupled with a high density of nano-twins and stacking faults in the matrix, contribute to the excellent mechanical properties at cryogenic and ambient temperatures. Moreover, the emergence of serrated σ phase and micro-twins in the matrix plays a crucial role in the strengthening and toughening mechanisms at intermediate temperatures. This study offers a novel perspective and strategy for the development of precipitation-hardened Fe–Cr–Ni austenitic alloys with exceptional strength–ductility synergy over a broad temperature range.

Keywords

high/medium-entropy alloys / medium temperature / mechanical property / serrated σ phase

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Tianxiang Bai, Tuanwei Zhang, Zhiming Jiao, Jinyao Ma, Hui Chang, Jianjun Wang, Dan Zhao, Shengguo Ma, Zhouzhu Mao, Xiaoxiao Liu, Zhihua Wang. Achieving the excellent intermediate-temperature strength–ductility synergy in a fine-grained FeCrNi-based medium entropy alloy with heterogeneous precipitation. International Journal of Minerals, Metallurgy, and Materials, 2025 https://doi.org/10.1007/s12613-024-3034-1

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	ChangM, KoulAK, AuP, TeradaT. Damage tolerance of wrought alloy 718 Ni–Fe-base superalloy. J. Mater. Eng. Perform., 1994, 3(3): 356

[2]	XiongL, YouZS, QuSD, LuL. Fracture behavior of heterogeneous nanostructured 316L austenitic stainless steel with nanotwin bundles. Acta Mater., 2018, 150: 130

[3]	DingQQ, ZhangY, ChenX, et al.. Tuning element distribution, structure and properties by composition in high-entropy alloys. Nature., 2019, 574(7777): 223

[4]	F. Yang, L.M. Dong, L. Cai, X.J. Hu, and F. Fang, Mechanical properties of FeMnCoCr high entropy alloy alloyed with C/Si at low temperatures, J. Alloy. Compd., 859(2021), art. No. 157876.

[5]	O.N. Senkov, J.D. Miller, D.B. Miracle, and C. Woodward, Accelerated exploration of multi-principal element alloys with solid solution phases, Nat. Commun., 6(2015), art. No. 6529.

[6]	Q.J. Li, H. Sheng, and E. Ma, Strengthening in multi-principal element alloys with local-chemical-order roughened dislocation pathways, Nat. Commun., 10(2019), No. 1, art. No. 3563.

[7]	Z.J. Zhang, M.M. Mao, J.W. Wang, et al., Nanoscale origins of the damage tolerance of the high-entropy alloy CrMnFeCoNi, Nat. Commun., 6(2015), art. No. 10143.

[8]	TabachnikovaED, PodolskiyAV, LaktionovaMO, BereznaiaNA, TikhonovskyMA, TortikaAS. Mechanical properties of the CoCrFeNiMnV_x high entropy alloys in temperature range 4.2–300 K. J. Alloys Compd., 2017, 698: 501

[9]	TongY, ChenD, HanB, et al.. Outstanding tensile properties of a precipitation-strengthened FeCoNiCrTi_0.2 high-entropy alloy at room and cryogenic temperatures. Acta Mater., 2019, 165: 228

[10]	WangSB, WuMX, ShuD, ZhuGL, WangDH, SunBD. Mechanical instability and tensile properties of TiZrHfN-bTa high entropy alloy at cryogenic temperatures. Acta Mater., 2020, 201: 517

[11]	D.D. Zhang, J.Y. Zhang, J. Kuang, G. Liu, and J. Sun, The B2 phase-driven microstructural heterogeneities and twinning enable ultrahigh cryogenic strength and large ductility in NiCoCr-based medium-entropy alloy, Acta Mater., 233(2022), art. No. 117981.

[12]	K. Wang, X. Jin, Y. Zhang, P.K. Liaw, and J.W. Qiao, Dynamic tensile mechanisms and constitutive relationship in CrFeNi medium entropy alloys at room and cryogenic temperatures, Phys. Rev. Mater., 5(2021), No. 11, art. No. 113608.

[13]	KimJH, NaYS. Tensile properties and serrated flow behavior of as-cast CoCrFeMnNi high-entropy alloy at room and elevated temperatures. Met. Mater. Int., 2019, 25(2): 296

[14]	FuJX, CaoCM, TongW, HaoYX, PengLM. The tensile properties and serrated flow behavior of a thermomechanically treated CoCrFeNiMn high-entropy alloy. Mater. Sci. Eng. A, 2017, 690: 418

[15]	GaliA, GeorgeEP. Tensile properties of high- and medium-entropy alloys. Intermetallics, 2013, 39: 74

[16]	OttoF, DlouhýA, SomsenC, BeiH, EggelerG, GeorgeEP. The influences of temperature and microstructure on the tensile properties of a CoCrFeMnNi high-entropy alloy. Acta Mater., 2013, 61(15): 5743

[17]	Q.Q. Ding, Z.Z. Lao, H. Wei, J.X. Li, H.B. Bei, and Z. Zhang, Site occupancy of alloying elements in γ′ phase of nickel-base single crystal superalloys, Intermetallics, 121(2020), art. No. 106772.

[18]	ZhangL, ZhouY, JinX, DuXY, LiBS. Precipitation-hardened high entropy alloys with excellent tensile properties. Mater. Sci. Eng. A, 2018, 732: 186

[19]	X. Bai, W. Fang, J.W. lv, et al., Effect of Cr content on precipitation behavior of (CoCrNi)₉₄Ti₃Al₃ medium entropy alloys, Intermetallics, 132(2021), art. No. 107125.

[20]	GwalaniB, ChoudhuriD, SoniV, et al.. Cu assisted stabilization and nucleation of L12 precipitates in Al_0.3CuFeCrNi₂ fcc-based high entropy alloy. Acta Mater., 2017, 129: 170

[21]	L. Wang, X.Y. Wu, H.J. Su, et al., Microstructure and mechanical property of novel L12 nanoparticles-strengthened CoFeNi-based medium entropy alloys, Mater. Sci. Eng. A, 840(2022), art. No. 142917.

[22]	S.M. Yang, J.L. Wu, Y.T. Pan, and D.Y. Lin, Precipitate evolution in 22Cr25NiWCuCo(Nb) austenitic heat-resistant stainless steel during heat treatment at 1200°C, Materials, 14(2021), No. 5, art. No. 1104.

[23]	MaSM, DaiJ, ZhangCC, et al.. Enhanced high temperature mechanical properties and heat resistance of an Al–Cu–Mg–Fe–Ni matrix composite reinforced with in situ TiB₂ particles. J. Mater. Sci., 2023, 58(32): 13019

[24]	HeJY, LiuWH, WangH, et al.. Effects of Al addition on structural evolution and tensile properties of the FeCoNiCrMn high-entropy alloy system. Acta Mater., 2014, 62: 105

[25]	RaoJC, DiaoHY, OcelíkV, et al.. Secondary phases in Al_xCoCrFeNi high-entropy alloys: An in situ TEM heating study and thermodynamic appraisal. Acta Mater., 2017, 131: 206

[26]	Q. Li, T.W. Zhang, J.W. Qiao, et al., Superior tensile properties of Al_0.3CoCrFeNi high entropy alloys with B2 precipitated phases at room and cryogenic temperatures, Mater. Sci. Eng. A, 767(2019), art. No. 138424.

[27]	ParkJM, MoonJ, BaeJW, JungJ, LeeS, KimHS. Effect of annealing heat treatment on microstructural evolution and tensile behavior of Al_0.5CoCrFeMnNi high-entropy alloy. Mater. Sci. Eng. A, 2018, 728: 251

[28]	ZhuYT, AmeyamaK, AndersonPM, et al.. Heterostructured materials: Superior properties from hetero-zone interaction. Mater. Res. Lett., 2021, 9(1): 1

[29]	X.X. Dong, B. Gao, L.R. Xiao, et al., Heterostructured metallic structural materials: Research methods, properties, and future perspectives, Adv. Funct. Mater., 34(2024), No. 51, art. No. 2410521.

[30]	T.X. Bai, T.W. Zhang, S.G. Ma, D. Zhao, and Z.H. Wang, Extra strengthening and work hardening in novel precipitation-hardened FeCrNiSi_x medium-entropy alloys, Adv. Eng. Mater., 23(2021), No. 4, art. No. 2001185.

[31]	H. Chang, T.W. Zhang, S.G. Ma, et al., Strengthening and strain hardening mechanisms in precipitation-hardened CrCoNi medium entropy alloys, J. Alloys Compd., 896(2022), art. No. 162962.

[32]	T.W. Zhang, R.L. Xiong, J.W. Bae, et al., Role of carbon on the enhanced strength-ductility synergy in a high-entropy alloy by multiple synergistic strategies, J. Alloys Compd., 1003(2024), art. No. 175698.

[33]	B. Gludovatz, A. Hohenwarter, K.V.S. Thurston, et al., Exceptional damage-tolerance of a medium-entropy alloy CrCoNi at cryogenic temperatures, Nat. Commun., 7(2016), art. No. 10602.

[34]	S.S. Sohn, A.K. da Silva, Y. Ikeda, et al., Ultrastrong medium-entropy single-phase alloys designed via severe lattice distortion, Adv. Mater., 31(2019), No. 8, art. No. 1807142.

[35]	LiZ, PradeepKG, DengY, RaabeD, TasanCC. Metastable high-entropy dual-phase alloys overcome the strength–ductility trade-off. Nature, 2016, 534(7606): 227

[36]	R.K. Nutor, Q. Cao, R. Wei, et al., A dual-phase alloy with ultrahigh strength-ductility synergy over a wide temperature range, Sci. Adv., 7(2021), No. 34, art. No. eabi4404.

[37]	C.J. Liu, C. Gadelmeier, S.L. Lu, et al., Tensile creep behavior of HfNbTaTiZr refractory high entropy alloy at elevated temperatures, Acta Mater., 237(2022), art. No. 118188.

[38]	W. Jiang, Y.T. Zhu, and Y.H. Zhao, Mechanical properties and deformation mechanisms of heterostructured high entropy and medium-entropy alloys: A review, Front. Mater., 8(2022), art. No. 530.

[39]	LiuWH, LuZP, HeJY, et al.. Ductile CoCrFeNiMo_x high entropy alloys strengthened by hard intermetallic phases. Acta Mater., 2016, 116: 332

[40]	WangJY, ZouJP, YangHL, et al.. Ultrastrong and ductile (CoCrNi)₉₄Ti₃Al₃ medium-entropy alloys via introducing multiscale heterogeneous structures. J. Mater. Sci. Technol., 2023, 135: 241

[41]	J.Z. Huang, J.Y. Wang, L.J. Yang, et al., Comparative study on microstructure and mechanical properties of a novel nano-composite strengthening heat-resistant steel and two typical heat-resistant steels, Mater. Today Commun., 36(2023), art. No. 106679.

[42]	KimYJ, LeeDG, JeongHK, LeeYT, JangH. High temperature mechanical properties of HK40-type heat-resistant cast austenitic stainless steels. J. Mater. Eng. Perform., 2010, 19(5): 700

[43]	ZhangL, HouYH, LiYC, XiangZL, WangEG. Size and type of inclusions in Fe–Cr–Co heat-resistant steel and elevated-temperature strength under the effect of electromagnetic stirring. ISIJ Int., 2019, 59(6): 1049

[44]	S. Wang, K.H. Zheng, Z.B. Zheng, J. Wang, J. Long, and Y.M. Li, Effect of Zr on microstructure and high-temperature mechanical properties of austenitic heat resistant steel, Mater. Res. Express, 6(2019), No. 11, art. No. 116549.

[45]	HuangL, LiGQ, WangXX, ZhangC, ChoeL, EngelhardtM. High temperature mechanical properties of high strength structural steels Q550, Q690 and Q890. Fire Technol., 2018, 54(6): 1609

[46]	FedoseevaAE, NikitinIS, DudovaNR, KaibyshevRO. Analysis of mechanical properties for the heat resistant Co-modified 12 and 9% Cr steels. Phys. Met. Metallogr., 2020, 121(12): 1233

[47]	WangZW, BeiHB, BakerI. Microband induced plasticity and the temperature dependence of the mechanical properties of a carbon-doped FeNiMnAlCr high entropy alloy. Mater. Charact., 2018, 139: 373

[48]	StepanovND, ShaysultanovDG, TikhonovskyMA, ZherebtsovSV. Structure and high temperature mechanical properties of novel non-equiatomic Fe–(Co, Mn)–Cr–Ni–Al–(Ti) high entropy alloys. Intermetallics, 2018, 102: 140

[49]	M. Schneider and G. Laplanche, Effects of temperature on mechanical properties and deformation mechanisms of the equiatomic CrFeNi medium-entropy alloy, Acta Mater., 204(2021), art. No. 116470.

[50]	Y.Q. Wang, C.J. Hu, N. Li, S.H. Lin, Z.Q. Ge, and C.S. Zheng, Effect of sigma phases on moderate-temperature tensile properties of Z3CN20.09M CASS used for primary coolant pipe of nuclear power plant, Coatings., 13(2023), art. No. 101.

[51]	C.L. Chu, W.P. Chen, L.R. Huang, H. Wang, L. Chen, and Z.Q. Fu, Exceptional strength–ductility synergy at room and liquid nitrogen temperatures of Al_7.5Co_20.5Fe₂₄Ni₂₄Cr₂₄ high-entropy alloy with hierarchical precipitate heterogeneous structure, Int. J. Plasticity, 175(2024), art. No. 103939.

[52]	BabcockSE, BalluffiRW. Grain boundary kinetics: II. In situ observations of the role of grain boundary dislocations in high-angle boundary migration. Acta Metall., 1989, 37(9): 2367

[53]	GleiterH. The mechanism of grain boundary migration. Acta Metall., 1969, 17(5): 565

[54]	Z.Y. You, Z.Y. Tang, F.B. Chu, H. Ding, and R.D.K. Misra, Significantly enhancing elevated-temperature strength and ductility of a FeMnCoCr high-entropy alloy via grain boundary engineering: Exploring multi-deformation mechanisms, Mater. Sci. Eng. A, 886(2023), art. No. 145547.

[55]	BeckPA, SperryPR. Strain induced grain boundary migration in high purity aluminum. J. Appl. Phys., 1950, 21(2): 150

[56]	PondRC, SmithDA, SoutherdenPWJ. On the role of grain boundary dislocations in high temperature creep. Philos. Mag. A, 1978, 37(1): 27

[57]	WinningM, GottsteinG, ShvindlermanLS. On the mechanisms of grain boundary migration. Acta Mater., 2002, 50(2): 353

[58]	RaeCMF. On the movement of grain boundary dislocations in recrystallizing interfaces. Philos. Mag. A, 1981, 44(6): 1395

[59]	EletiRR, ChokshiAH, ShibataA, TsujiN. Unique high-temperature deformation dominated by grain boundary sliding in heterogeneous necklace structure formed by dynamic recrystallization in HfNbTaTiZr BCC refractory high entropy alloy. Acta Mater., 2020, 183: 64

[60]	C. Zhang, Q. Yu, Y.T. Tang, et al., Strong and ductile FeNi-CoAl-based high-entropy alloys for cryogenic to elevated temperature multifunctional applications, Acta Mater., 242(2023), art. No. 118449.

[61]	TangYT, WilkinsonAJ, ReedRC. Grain boundary serration in nickel-based superalloy Inconel 600: Generation and effects on mechanical behavior. Metall. Mater. Trans. A, 2018, 49(9): 4324

[62]	BarbaD, PedrazziniS, Vilalta-ClementeA, et al.. On the composition of microtwins in a single crystal nickel-based superalloy. Scripta Mater., 2017, 127: 37