Enhanced Strength-ductility of FeMnNiCo High-entropy Alloy with Incorporation of In-situ TiC Reinforcements

Yue Xu; Yuanbo Deng; Heguo Zhu

doi:10.1007/s11595-025-3125-5

Journal of Wuhan University of Technology Materials Science Edition ›› 2025, Vol. 40 ›› Issue (3) : 887 -894. DOI: 10.1007/s11595-025-3125-5

Metallic Materials

Enhanced Strength-ductility of FeMnNiCo High-entropy Alloy with Incorporation of In-situ TiC Reinforcements

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Abstract

To further enhance the properties of high-entropy alloy (HEAs) and enable its potential applications, we employed a combination approach involving ball milling and induction melting to fabricate in-situ TiC reinforced composites within the FeMnNiCo high entropy alloy matrix. The effect of TiC content on the microstructure and mechanical properties of the composites were studied. It was observed that in-situ formed TiC did not induce any phase transition, maintaining the FCC structure of the high-entropy alloy matrix. As the volume fraction of TiC increased, both the number and size of TiC particles increased, leading to agglomeration in morphology. By introducing 5 vol% of TiC in the composites, a significant enhancement in ultimate tensile strength (609.2 MPa) and yield strength (349.1 MPa), corresponding to a respective increase by 32% and 46% compared to the matrix, was achieved; meanwhile, an elongation value as high as 45% was obtained. This combination of exceptional tensile strength and good plasticity is attributed to synergistic effects from orowan mechanism and solid solution strengthening.

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Yue Xu, Yuanbo Deng, Heguo Zhu. Enhanced Strength-ductility of FeMnNiCo High-entropy Alloy with Incorporation of In-situ TiC Reinforcements. Journal of Wuhan University of Technology Materials Science Edition, 2025, 40(3): 887-894 DOI:10.1007/s11595-025-3125-5

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References

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[1]	YehJW, ChenSK, LinSJ, et al.. Nanostructured High-Entropy Alloys with Multiple Principal Elements: Novel Alloy Design Concepts and Outcomes[J]. Adv Eng Mater., 2004, 6: 299-303

[2]	LiangYJ, WangL, WenY, et al.. High-content Ductile Coherent Nanoprecipitates Achieve Ultrastrong High-entropy Alloys[J]. Nat. Commun., 2018, 9: 40-46

[3]	LiZ, PradeepKG, DengY, et al.. Metastable High-entropy Dual-phase Alloys Overcome the Strength-ductility Trade-off[J]. Nature, 2016, 534: 227-230

[4]	GangireddyS, GwalaniB, SoniV, et al.. Contrasting Mechanical Behavior in Precipitation Hardenable Al_xCoCrFeNi High Entropy Alloy Microstructures: Single Phase FCC vs Dual Phase FCC-BCC[J]. Mater. Sci. Eng. A, 2019, 739: 158-166

[5]	AliN, ZhangL, LiuD, et al.. Strengthening Mechanisms in High Entropy Alloys: A Review[J]. Mater. Today Commun., 2022, 33: 104-113

[6]	WangZ, ChenS, YangS, et al.. Light-weight Refractory High-entropy Alloys: A Comprehensive Review[J]. J. Mater. Sci. Technol., 2023, 151: 41-65

[7]	LiL, JiangH, NiZ, et al.. Influences of Milling Time and NbC on Microstructure of AlCoCrFeNi_2.1 High Entropy Alloy by Mechanical Alloying[J]. J. Wuhan Univ. Technol. -Mat. Sci. Edit., 2023, 38: 423-429

[8]	SonarT, IvanovM, TrofimovE, et al.. An Overview of Microstructure, Mechanical Properties and Processing of High Entropy Alloys and Its Future Perspectives in Aero Engine Applications[J]. Mater. Sci. Energy Technol., 2023, 238: 156-159

[9]	GludovatzB, HohenwarterA, CatoorD, et al.. A Fracture-Resistant High-entropy Alloy for Cryogenic Applications[J]. Science, 2014, 345: 1153-1158

[10]	KumarD, SeetharamR, PonappaK. A Review on Microstructures, Mechanical Properties and Processing of High Entropy Alloys Reinforced Composite Materials[J]. J. Alloys Compd., 2024, 972: 172-176

[11]	ZhangG, YangX, YangZ, et al.. Preparation of WC/CoCrFeNiAl_0.2 High-entropy-alloy Composites by High-gravity Combustion Synthesis[J]. Int. J. Miner. Metall. Mater., 2020, 27: 244-251

[12]	WuH, HuangS, ZhuC, et al.. Excellent Mechanical Properties of In-situ TiC/FeCrNiCuV_0.1 High Entropy Alloy Matrix Composites[J]. Mater. Lett., 2019, 257: 126-129

[13]	PanY, LiW, LuX, et al.. Microstructure and Tribological Properties of Titanium Matrix Composites Reinforced with in situ Synthesized TiC Particles[J]. Mater. Charact., 2020, 170: 110-116

[14]	ShenL, ZhaoY, LiY, et al.. Synergistic Strengthening of FeCrNiCo High Entropy Alloys Via Micro-TiC and Nano-SiC Particles[J]. Mater. Today Commun., 2021, 26: 101-107

[15]	WuH, HuangSR, ZhuCY, et al.. In situ TiC/FeCrNiCu High-Entropy Alloy Matrix Composites: Reaction Mechanism, Microstructure and Mechanical Properties[J]. Acta Metall. Sin. (Engl. Lett.), 2020, 33: 1091-1102

[16]	CaoT, WuY, TianJ, et al.. In-situ Oxide Particles Reinforced Fe₄₀Mn₄₀Co₁₀Cr₁₀ High-entropy Alloy by Internal Oxidation and Powder Forging[J]. Scr. Mater., 2022, 215: 114-116

[17]	WuH, HuangS, ZhaoC, et al.. Microstructures and Mechanical Properties of in-situ FeCrNiCu High Entropy Alloy Matrix Composites Reinforced with NbC Particles[J]. Intermetallics, 2020, 127: 106-109

[18]	CuiP, MaY, ZhangL, et al.. Effect of Ti on Microstructures and Mechanical Properties of High Entropy Alloys Based on CoFeMnNi System[J]. Mater. Sci. Eng. A, 2018, 737: 198-204

[19]	ZhangJ, JiaT, ZhuH, et al.. Microstructure and Mechanical Properties of In-situ TiC Reinforced FeCoNiCu_2.0 High Entropy Alloy Matrix Composites[J]. Mater. Sci. Eng. A, 2021, 822: 141-146

[20]	WuH, HuangS, ZhuH, et al.. Strengthening FeCrNiCu High Entropy Alloys via Combining V Additions with In-situ TiC Particles[J]. Scr. Mater., 2021, 195: 113-117

[21]	ZhangJ, JiaT, QiuH, et al.. Effect of Cooling Rate Upon the Microstructure and Mechanical Properties of In-situ TiC Reinforced High Entropy Alloy CoCrFeNi[J]. J. Mater. Sci. Technol., 2020, 42: 122-129

[22]	HuangS, WuH, ChenY, et al.. A Novel NbC/CrMnFeCoNi_0.8 High Entropy Alloy Matrix Composites with Ultrastrength and Ductility: Experiments and Density Function Theory[J]. Composites Communications, 2023, 38: 101-110

[23]	TakeuchiA, InoueA. Classification of Bulk Metallic Glasses by Atomic Size Difference, Heat of Mixing and Period of Constituent Elements and Its Application to Characterization of the Main Alloying Element[J]. Mater. Trans., 2005, 46: 2817-2829

[24]	HuangS, ZhangJ, WuH, et al.. Boosted Mechanical Properties of CoCr₃Fe₅Ni High Entropy Alloy Via In-situ TiC Particles[J]. J. Alloys Compd., 2023, 968: 172-175

[25]	ChungKS, LuanJH, ShekCH. Strengthening and Deformation Mechanism of Interstitially N and C Doped FeCrCoNi High Entropy Alloy[J]. J. Alloys Compd., 2022, 904: 164-168

[26]	DoHS, JangTJ, KimKJ, et al.. A Novel High-entropy Alloy with Multi-strengthening Mechanisms: Activation of TRIP Effect in C-doped High-entropy Alloy[J]. Mater. Sci. Eng. A, 2022, 859: 144-148

[27]	LuE, ZhaoJ, MakkonenI, et al.. Enhancement of Vacancy Diffusion by C and N Interstitials In the Equiatomic FeMnNiCoCr High Entropy Alloy[J]. Acta Mater., 2021, 215: 117-119

[28]	WangZ, BakerI, CaiZ, et al.. The Effect of Interstitial Carbon on the Mechanical Properties and Dislocation Substructure Evolution In Fe_40.4Ni_11.3Mn_34.8Al_7.5Cr₆ High Entropy Alloys[J]. Acta Mater., 2016, 120: 228-239

[29]	LukianovaOA, RaoZ, KulitckiiV, et al.. Impact of Interstitial Carbon on Self-diffusion in CoCrFeMnNi High Entropy Alloys[J]. Scr. Mater., 2020, 188: 264-268

[30]	BaoY, GuoL, ZhongC, et al.. Microstructure and Wear Resistance of Fe₄CoCrNiB_0.2Mo_x (x=0, 0.5, 1) High Entropy Alloys[J]. J. Wuhan Univ. Technol. -Mat. Sci. Edit., 2022, 37: 261-269

[31]	LiQ, ZhangTW, QiaoJW, et al.. Mechanical Properties and Deformation Behavior of Dual-phase Al_0.6CoCrFeNi High-entropy Alloys with Heterogeneous Structure at Room and Cryogenic Temperatures[J]. J. Alloys Compd., 2020, 816: 1526-1563

[32]	YangY, ZhangY, LiJ, et al.. Effects of Varying Copper Content on the Microstructure and Mechanical Properties of FeCoNiCu_x[J]. J. Wuhan Univ. Technol. -Mat. Sci. Edit., 2022, 37: 986-991

[33]	HuangS, WuH, ZhuH, et al.. A Novel As-cast NbTiC₂/FeCrNiCu High Entropy Alloy Matrix Composite with Remarkable Tensile Properties[J]. Mater. Lett., 2021, 283: 1289-1308

[34]	PoirierD, DrewRAL, TrudeauML, et al.. Fabrication and Properties of Mechanically Milled Alumina/Aluminum Nanocomposites[J]. Mater. Sci. Eng. A, 2010, 527: 7605-7614

[35]	JiangL, WenH, YangH, et al.. Influence of Length-scales on Spatial Distribution and Interfacial Characteristics of B₄C in a Nanostructured Al Matrix[J]. Acta Mater., 2015, 89: 327-343