Enhanced strength and ductility of high-entropy alloy via dislocation-mediated heterogeneous martensitic transformation

Feng Wang; Xinglong An; Zhangwei Wang; Wenqian Wu; Wenzhen Xia; Song Ni; Ji Gu; Jianhong Yi; Yong Yang; Min Song; Yuntian Zhu

doi:10.20517/microstructures.2025.33

Microstructures ›› 2025, Vol. 5 ›› Issue (4) :2025088 DOI: 10.20517/microstructures.2025.33

Research Article

Enhanced strength and ductility of high-entropy alloy via dislocation-mediated heterogeneous martensitic transformation

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¹State Key Laboratory of Powder Metallurgy, Central South University, Changsha 410083, Hunan, China.

²Department of Mechanical and Materials Engineering, University of Nebraska-Lincoln, Lincoln, NE 68588, USA.

³School of Metallurgical Engineering, Anhui University of Technology, Ma’anshan 243002, Anhui, China.

⁴School of Materials Science and Engineering, Kunming University of Science and Technology, Kunming 650093, Yunnan, China.

⁵Department of Mechanical Engineering, College of Engineering, City University of Hong Kong, Kowloon Tong 999077, Hong Kong, China.

⁶Department of Materials Science and Engineering, College of Engineering, City University of Hong Kong, Kowloon Tong 999077, Hong Kong, China.

^#Authors contributed equally.

Correspondence to: Prof. Zhangwei Wang and Prof. Min Song, State Key Laboratory of Powder Metallurgy, Central South University, No. 932 Lushan South Road, Changsha 410083, Hunan, China. E-mail: z.wang@csu.edu.cn, msong@csu.edu.cn; Prof. Yuntian Zhu, Department of Materials Science and Engineering, College of Engineering, City University of Hong Kong, No. 83 Tat Chee Avenue, Kowloon Tong 999077, Hong Kong, China. E-mail: y.zhu@cityu.edu.hk

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Abstract

The pursuit of unparalleled mechanical properties has driven the exploration of heterostructured materials in recent years. Traditional strategies that rely on tuning internal plastic strain to create heterogeneous distributions of martensite have failed to overcome the strength-ductility trade-off in materials, despite the desirable extensive hardening effect of martensitic transformation. Here, we report a paradigm-shifting approach utilizing dislocation-mediated heterogeneous martensitic transformation to resolve this dilemma. Realized in a partially recrystallized metastable face-centered cubic (FCC) high-entropy alloy (HEA), the phase transformation from FCC to a hexagonal close-packed (HCP) structure occurs exclusively in the non-recrystallized zones during initial tensile loading, facilitated by abundant pre-existing dislocations serving as sources for partial dislocations. In contrast, deformation in the adjacent recrystallized zones, which are devoid of dislocations, proceeds through dislocation slip. The resulting heterogeneous deformation persists with increasing strain, underpinned by the emergence of unique dual FCC-HCP nanograins at localized HCP lamellar intersections in the non-recrystallized zones. Such sustained heterogeneous deformation enables the full exploitation of remarkable hetero-deformation-induced strengthening and strain hardening, leading to a superior strength-ductility combination in the current HEA. Our findings establish a new pathway for engineering high-performance heterostructured materials.

Keywords

Heterogeneous martensitic transformation / high-entropy alloy / strength / ductility / hetero-deformation induced hardening

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Feng Wang, Xinglong An, Zhangwei Wang, Wenqian Wu, Wenzhen Xia, Song Ni, Ji Gu, Jianhong Yi, Yong Yang, Min Song, Yuntian Zhu. Enhanced strength and ductility of high-entropy alloy via dislocation-mediated heterogeneous martensitic transformation. Microstructures, 2025, 5(4): 2025088 DOI:10.20517/microstructures.2025.33

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References

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

[1]	Sathiyamoorthi P.High-entropy alloys with heterogeneous microstructure: processing and mechanical properties.Prog Mater Sci2022;123:100709

[2]	Ma E.Towards strength-ductility synergy through the design of heterogeneous nanostructures in metals.Mater Today2017;20:323-31

[3]	Park HK,Jung J.Efficient design of harmonic structure using an integrated hetero-deformation induced hardening model and machine learning algorithm.Acta Mater2023;244:118583

[4]	Tang X,Long J.Recent progress on plastic forming of laminated metal composites: processes, heterogeneous deformation, and interfacial regulation.J Mater Sci Technol2025;229:67-91

[5]	Shen J,Yang J.Fabrication of spatially-variable heterostructured CoCrFeMnNi high entropy alloy by laser processing.Mat Sci Eng A2024;896:146272

[6]	Zhang C,Cao P.Aged metastable high-entropy alloys with heterogeneous lamella structure for superior strength-ductility synergy.Acta Mater2020;199:602-12

[7]	Fang TH,Tao NR.Revealing extraordinary intrinsic tensile plasticity in gradient nano-grained copper.Science2011;331:1587-90

[8]	Pan QS,Jing LJ,Lu L.Cyclic strain amplitude-dependent fatigue mechanism of gradient nanograined Cu.Acta Mater2020;196:252-60

[9]	Zhang BH,Wang PF,Cao Y.Enhanced strength-ductility of CoCrFeMnNi high-entropy alloy with inverse gradient-grained structure prepared by laser surface heat-treatment technique.J Mater Sci Technol2022;111:111-9

[10]	Cheng Z,Lu Q,Lu L.Extra strengthening and work hardening in gradient nanotwinned metals.Science2018;362:eaau1925

[11]	Wei Y,Zhu L.Evading the strength-ductility trade-off dilemma in steel through gradient hierarchical nanotwins.Nat Commun2014;5:3580 PMCID:PMC3988817

[12]	Pan Q,Feng R.Gradient cell-structured high-entropy alloy with exceptional strength and ductility.Science2021;374:984-9

[13]	Shi P,Zheng T.Enhanced strength-ductility synergy in ultrafine-grained eutectic high-entropy alloys by inheriting microstructural lamellae.Nat Commun2019;10:489 PMCID:PMC6353877

[14]	Du XH,Chang HT.Dual heterogeneous structures lead to ultrahigh strength and uniform ductility in a Co-Cr-Ni medium-entropy alloy.Nat Commun2020;11:2390 PMCID:PMC7220923

[15]	Cao S,Jiang J.Effect of heat treatment on gradient microstructure and tensile property of laser powder bed fusion fabricated 15-5 precipitation hardening stainless steel.Acta Metall Sin2024;37:181-95

[16]	Grässel O,Frommeyer G.High strength Fe-Mn-(Al, Si) TRIP/TWIP steels development - properties - application.Int J Plast2000;16:1391-409

[17]	Li Z,Grabowski B,Raabe D.Ab initio assisted design of quinary dual-phase high-entropy alloys with transformation-induced plasticity.Acta Mater2017;136:262-70

[18]	Liu SF,Wang HT.Stacking fault energy of face-centered-cubic high entropy alloys.Intermetallics2018;93:269-73

[19]	Liu S,Wang H.Transformation-reinforced high-entropy alloys with superior mechanical properties via tailoring stacking fault energy.J Alloys Compd2019;792:444-55

[20]	Sohrabi MJ,Heydarinia A.Deformation-induced martensitic transformation kinetics in TRIP-assisted steels and high-entropy alloys.Acta Mater2024;280:120354

[21]	Guo N,Dong Q.Strengthening and toughening austenitic steel by introducing gradient martensite via cyclic forward/reverse torsion.Mater Design2018;143:150-9

[22]	Cao SC,Zhu L.Nature-inspired hierarchical steels.Sci Rep2018;8:5088 PMCID:PMC5865137

[23]	Plimpton S.Fast parallel algorithms for short-range molecular dynamics.J Comput Phys1995;117:1-19

[24]	Li Z,Deng Y,Tasan CC.Metastable high-entropy dual-phase alloys overcome the strength-ductility trade-off.Nature2016;534:227-30

[25]	Ding Q,Chen X.Tuning element distribution, structure and properties by composition in high-entropy alloys.Nature2019;574:223-7

[26]	Hasan MN,An XH.Simultaneously enhancing strength and ductility of a high-entropy alloy via gradient hierarchical microstructures.Int J Plast2019;123:178-95

[27]	Courtney, T.H. Mechanical behavior of materials, Waveland Press, 2005.

[28]	Yang M,Yuan F,Ma E.Dynamically reinforced heterogeneous grain structure prolongs ductility in a medium-entropy alloy with gigapascal yield strength.Proc Natl Acad Sci U S A2018;115:7224-9 PMCID:PMC6048477

[29]	Chen W,Wang Z,Gu J.Grain size dependent deformation behavior of a metastable Fe40Co20Cr20Mn10Ni10 high-entropy alloy.J Alloys Compd2021;883:160876

[30]	Zhang X.Twinning of deformation-induced ε-martensite in Fe-30Mn-6Si shape memory alloy.Acta Mater2018;143:237-47

[31]	Martinez M.Characterization of deformation twinning in polycrystalline cobalt: a quantitative analysis.Materialia2019;7:100420

[32]	Wagner C.Effects of stacking fault energy and temperature on grain boundary strengthening, intrinsic lattice strength and deformation mechanisms in CrMnFeCoNi high-entropy alloys with different Cr/Ni ratios.Acta Mater2023;244:118541

[33]	Ponge, D.; MiUán, J.; Raabe, D. Design of lean maraging TRIP steels. In Advanced Steels 2011, Proceedings of the ICAS, Guilin, China, November 9-11, 2010; Weng, Y., Dong, H., Gan, Y., Eds.; Springer-Verlag: Berlin, Heidelberg, 2011; pp 199-208.

[34]	Yang XS,Zhang TY.The mechanism of bcc α’ nucleation in single hcp ε laths in the fcc γ → hcp ε → bcc α’ martensitic phase transformation.Acta Mater2015;95:264-73

[35]	Soleimani M,Mirzadeh H.Transformation-induced plasticity (TRIP) in advanced steels: a review.Mater Sci Eng A2020;795:140023

[36]	Shen S,Wu C.Temperature dependence of mechanical properties and deformation mechanism of Fe-25Mn-3Al-3Si alloy at high strain rate.Mater Sci Eng A2023;872:144912

[37]	Su J,Raabe D.Deformation-driven bidirectional transformation promotes bulk nanostructure formation in a metastable interstitial high entropy alloy.Acta Mater2019;167:23-39

[38]	Singh D,Sawaguchi T.Elucidating deformation pathways and interface characteristic of self-accommodated dual γ/ε phase microstructure in Fe-Mn-Si-Al alloy.Mater Charact2024;207:113521

[39]	Yang JH.Intersecting-shear mechanisms for the formation of secondary ϵ martensite variants.Acta Metall Mater1992;40:2025-31

[40]	Yang JH.On secondary variants formed at intersections of ϵ martensite variants.Acta Metall Mater1992;40:2011-23

[41]	Mishra RS,Agrawal P.High entropy alloys - tunability of deformation mechanisms through integration of compositional and microstructural domains.Mater Sci Eng A2021;812:141085

[42]	Liu J,Huang B.Nano-twinning and martensitic transformation behaviors in 316L austenitic stainless steel during large tensile deformation.Acta Metall Sin2023;36:758-70

[43]	Huang M,Wang C.Optimizing crack initiation energy in austenitic steel via controlled martensitic transformation.J Mater Sci Technol2024;198:231-42

[44]	Bu Y,Liu J,Raabe D.Nonbasal slip systems enable a strong and ductile hexagonal-close-packed high-entropy phase.Phys Rev Lett2019;122:075502

[45]	Chen S,Gludovatz B.Real-time observations of TRIP-induced ultrahigh strain hardening in a dual-phase CrMnFeCoNi high-entropy alloy.Nat Commun2020;11:826 PMCID:PMC7012927

[46]	Li W,Li D,Gao Y.Mechanical behavior of high-entropy alloys.Prog Mater Sci2021;118:100777

[47]	Mughrabi H.On the role of strain gradients and long-range internal stresses in the composite model of crystal plasticity.Mater Sci Eng A2001;317:171-80

[48]	Liu XL,Wang W.Back-stress-induced strengthening and strain hardening in dual-phase steel.Materialia2019;7:100376

[49]	Kim RE,Haftlang F.Hierarchical ferrous medium entropy with heterogeneous precipitates embedded in core-shell grain structure for superior mechanical properties.Acta Mater2024;281:120397