Role of multicomponent nanoprecipitates on strength and low-temperature toughness of simulated heat-affected zone (HAZ) in high-strength low-carbon steel

Tingwei Yin; Yongfeng Shen; Nan Jia; Xin Sun; Wenying Xue

doi:10.1007/s12613-025-3245-0

International Journal of Minerals, Metallurgy, and Materials ›› 2026, Vol. 33 ›› Issue (2) :579 -594. DOI: 10.1007/s12613-025-3245-0

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Role of multicomponent nanoprecipitates on strength and low-temperature toughness of simulated heat-affected zone (HAZ) in high-strength low-carbon steel

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Abstract

This study investigates the microstructure and co-precipitation behavior of multicomponent (Ni(Al,Mn) and Cu) nanoparticles in the weld heat-affected zones of high-strength low-carbon steel. Through thermal simulations, the intercritical, fine-grained, and coarse-grained heat-affected zones were systematically characterized to elucidate the interplay between the microstructure, precipitation, and mechanical properties. At a heat input of 30 kJ·cm⁻¹, Ni(Al,Mn) nanoparticles dissolve in the intercritical heat-affected zone, followed by dense reprecipitation coupled with significant coarsening of Cu particles during cooling, thereby retaining high strength but reducing impact toughness to (142 ± 10) J (compared to (205 ± 8) J of the base metal). The fine-grained heat-affected zone, under the same heat input, exhibits a refined ferritic–bainite matrix with a few fine Ni(Al,Mn) and slightly coarsened Cu particles, thus enhancing plastic deformation capacity and resulting in superior impact toughness of (196 ± 7) J. Despite complete dissolution of original precipitates at peak temperatures in the coarse-grained heat-affected zone, re-precipitated nanoparticles provide effective strengthening effect, compensating for grain coarsening and dislocation recovery and resulting in an impressive impact toughness of (186 ± 6) J. The toughening mechanism is primarily attributed to the synergistic actions of the matrix, precipitates, and deformation twins. These findings provide mechanistic and quantitative insights for developing processing–microstructure–property relationships in different welding heat-affected zones, and this framework can be further utilized to optimize welding parameters for tailored applications.

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high-strength low-carbon steel / heat-affected zones / multicomponent nanoparticles / strengthening / toughening

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Tingwei Yin, Yongfeng Shen, Nan Jia, Xin Sun, Wenying Xue. Role of multicomponent nanoprecipitates on strength and low-temperature toughness of simulated heat-affected zone (HAZ) in high-strength low-carbon steel. International Journal of Minerals, Metallurgy, and Materials, 2026, 33(2): 579-594 DOI:10.1007/s12613-025-3245-0

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References

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[1]	J. Moon, G. Bae, B.Y. Jeong, et al., Ultrastrong and ductile steel welds achieved by fine interlocking microstructures with filmlike retained austenite, Nat. Commun., 15(2024), No. 1, art. No. 1301.

[2]	Jiao ZB, Luan JH, Guo W, Poplawsky JD, Liu CT. Effects of welding and post-weld heat treatments on nanoscale precipitation and mechanical properties of an ultra-high strength steel hardened by NiAl and Cu nanoparticles. Acta Mater., 2016, 120: 216

[3]	Li TT, Yang J. Development in oxide metallurgy for improving the weldability of high-strength low-alloy steel: Combined deoxidizers and microalloying elements. Int. J. Miner. Metall. Mater., 2024, 3161263

[4]	X.C. Yang, X.J. Di, J.S. Wang, et al., The co-precipitation evolution of NiAl and Cu nanoparticles and its influence on strengthening and toughening mechanisms in low-carbon ultrahigh strength martensite seamless tube steel, Int. J. Plast., 166(2023), art. No. 103654.

[5]	F.L. Ding, Q.Y. Guo, B. Hu, et al., Influences of Cu alloying on precipitation, austenitic reversion and mechanical properties of NiAl-strengthened medium-Mn steels, Acta Mater., 284(2025), art. No. 120623.

[6]	Xu SS, Zhao Y, Chen Det al.. Nanoscale precipitation and its influence on strengthening mechanisms in an ultra-high strength low-carbon steel. Int. J. Plast., 2019, 113: 99

[7]	M.Z. Wang, Y.F. Shen, N. Jia, W.Y. Xue, and X.L. Wang, Multistage precipitation triggering 3 GPa compressive strength and superior corrosion resistance in a FeCrVNiAl alloy, Mater. Futur., 4(2025), No. 3, art. No. 035004.

[8]	B.C. Zhou, T. Yang, G. Zhou, H. Wang, J.H. Luan, and Z.B. Jiao, Mechanisms for suppressing discontinuous precipitation and improving mechanical properties of NiAl-strengthened steels through nanoscale Cu partitioning, Acta Mater., 205(2021), art. No. 116561.

[9]	Kapoor M, Isheim D, Vaynman S, Fine ME, Chung YW. Effects of increased alloying element content on NiAl-type precipitate formation, loading rate sensitivity, and ductility of Cu- and NiAl-precipitation-strengthened ferritic steels. Acta Mater., 2016, 104: 166

[10]	Lee SG, Lee DH, Sohn SSet al.. Effects of Ni and Mn addition on critical crack tip opening displacement (CTOD) of weld-simulated heat-affected zones of three high-strength low-alloy (HSLA) steels. Mater. Sci. Eng. A, 2017, 697: 55

[11]	Li TT, Yang J, Zhang YH, Sun H, Chen YL, Zhang YQ. Effect of Al content on nanoprecipitates, austenite grain growth and toughness in coarse-grained heat-affected zones of Al–Ti–Ca deoxidized shipbuilding steels. Int. J. Miner. Metall. Mater., 2025, 324879

[12]	Xie GM, Duan RH, Wang YQ, Luo ZA, Wang GD. Microstructure and toughness of thick-gauge pipeline steel joint via double-sided friction stir welding combined with preheating. Int. J. Miner. Metall. Mater., 2023, 304724

[13]	J. Wang, Y.F. Shen, W.Y. Xue, N. Jia, and R.D.K. Misra, The significant impact of introducing nanosize precipitates and decreased effective grain size on retention of high toughness of simulated heat affected zone (HAZ), Mater. Sci. Eng. A, 803(2021), art. No. 140484.

[14]	Jiao ZB, Luan JH, Miller MK, Chung YW, Liu CT. Co-precipitation of nanoscale particles in steels with ultra-high strength for a new era. Mater. Today, 2017, 203142

[15]	Bono JT, DuPont JN, Jain D, Baik SI, Seidman DN. Investigation of strength recovery in welds of NUCu-140 steel through multipass welding and isothermal post-weld heat treatments. Metall. Mater. Trans. A, 2015, 46115158

[16]	W. Fu, C.N. Li, X.J. Di, et al., Effect of peak temperature on nanoscale Cu-rich re-precipitation behavior and strength-toughness of welding heat affected zones for Cu-bearing high strength steel, Mater. Charact., 199(2023), art. No. 112809.

[17]	Hunter AH, Farren JD, DuPont JN, Seidman DN. An atom-probe tomographic study of arc welds in a multi-component high-strength low-alloy steel. Metall. Mater. Trans. A, 2013, 4441741

[18]	Yu XH, Caron JL, Babu SS, Lippold JC, Isheim D, Seidman DN. Characterization of microstructural strengthening in the heat-affected zone of a blast-resistant naval steel. Acta Mater., 2010, 58175596

[19]	X.Y. Qi, L.X. Du, J. Hu, and R.D.K. Misra, Enhanced impact toughness of heat affected zone in gas shield arc weld joint of low-C medium-Mn high strength steel by post-weld heat treatment, Steel Res. Int., 89(2018), No. 4, art. No. 1700422.

[20]	R.M. Geng, J. Li, C.B. Shi, J.G. Zhi, and B. Lu, Effect of Ce on microstructures, carbides and mechanical properties in simulated coarse-grained heat-affected zone of 800-MPa high-strength low-alloy steel, Mater. Sci. Eng. A, 840(2022), art. No. 142919.

[21]	X.C. Yang, C.N. Li, J.Y. Han, et al., Effect of welding state on the re-precipitation behavior of Cu-rich and NiAl nanoparticles in HAZ of 1100 MPa grade low carbon ultra-high strength steel, Mater. Sci. Eng. A, 897(2024), art. No. 146334.

[22]	Jiang SH, Wang H, Wu Yet al.. Ultrastrong steel via minimal lattice misfit and high-density nanoprecipitation. Nature, 2017, 5447651460

[23]	Y.Z. Li, S.L. Zhao, S.H. He, C.P. Huang, and M.X. Huang, Enhancing yield stress and uniform elongation in an ultrathin packaging steel via controlling dislocation density, Int. J. Plast., 155(2022), art. No. 103334.

[24]	T. Masumura, K. Inami, K. Matsuda, T. Tsuchiyama, S. Nanba, and A. Kitahara, Quantitative evaluation of dislocation density in as-quenched martensite with tetragonality by X-ray line profile analysis in a medium-carbon steel, Acta Mater., 234(2022), art. No. 118052.

[25]	Wang MZ, Shen YF, Jia N, Xue WY, Wang ZD. Ultrahigh strength triggered by BCC and B2 eutectic-phase interfaces in a novel FeCrVNiAl high-entropy alloy. Mater. Res. Lett., 2024, 1210745

[26]	Ungar T, Dragomir I, Révész Á, Borbély A. The contrast factors of dislocations in cubic crystals: The dislocation model of strain anisotropy in practice. J. Appl. Crystallogr., 1999, 325992

[27]	T.W. Yin, Y.F. Shen, N. Jia, Y.J. Li, and W.Y. Xue, Controllable selection of martensitic variant enables concurrent enhancement of strength and ductility in a low-carbon steel, Int. J. Plast., 168(2023), art. No. 103704.

[28]	Zhou JH, Shen YF, Jia N. Strengthening mechanisms of reduced activation ferritic/martensitic steels: A review. Int. J. Miner. Metall. Mater., 2021, 283335

[29]	J. Mola, S. Scherbring, U. Lienert, A. Zargaran, H. Biermann, and P. Sahu, Size-dependent stress response of nanoscale B2 intermetallic precipitates revealed by in-situ high-energy X-ray diffraction, Acta Mater., 291(2025), art. No. 120967.

[30]	Niu WY, Zhang XL, Liang JW, Shen YF, Xue WY, Li JP. Role of nano-bainite laths and nanosized precipitates: Strengthening a low-alloy steel to 1870 MPa. J. Mater. Res. Technol., 2024, 33: 2331

[31]	Z.X. Guo, X.C. Lu, C. Paramatmuni, et al., Slip system-resolved GNDs and SEDs: A multi-scale framework for predicting crack nucleation in single-crystal metals, Acta Mater., 288(2025), art. No. 120853.

[32]	S.S. Xu, J.P. Li, Y. Cui, et al., Mechanical properties and deformation mechanisms of a novel austenite-martensite dual phase steel, Int. J. Plast., 128(2020), art. No. 102677.

[33]	Han G, Xie ZJ, Li ZY, Lei B, Shang CJ, Misra RDK. Evolution of crystal structure of Cu precipitates in a low carbon steel. Mater. Des., 2017, 135: 92

[34]	Zhao Y, Tong X, Wei XHet al.. Effects of microstructure on crack resistance and low-temperature toughness of ultra-low carbon high strength steel. Int. J. Plast., 2019, 116: 203

[35]	X.N. Xu, P. Kumar, R.Q. Cao, et al., Exceptional cryogenic-to-ambient impact toughness of a low carbon micro-alloyed steel with a multi-heterogeneous structure, Acta Mater., 274(2024), art. No. 120019.

[36]	Q. Zhu, Z.L. Pan, Z.Y. Zhao, et al., Defect-driven selective metal oxidation at atomic scale, Nat. Commun., 12(2021), No. 1, art. No. 558.

[37]	Li YJ, Yuan G, Li LLet al.. Ductile 2-GPa steels with hierarchical substructure. Science, 2023, 3796628168

[38]	N. Zhao, Q.Q. Zhao, Y.L. He, et al., Strengthening-toughening mechanism of cost-saving marine steel plate with 1000 MPa yield strength, Mater. Sci. Eng. A, 831(2022), art. No. 142280.

[39]	Singh N, Casillas G, Wexler D, Killmore C, Pereloma E. Application of advanced experimental techniques to elucidate the strengthening mechanisms operating in microalloyed ferritic steels with interphase precipitation. Acta Mater., 2020, 201: 386

[40]	C.W. He, Y.F. Shen, W.Y. Xue, Z.J. Fan, and Y.R. Zhou, Nanosized κ-carbide and B₂ boosting strength without sacrificing ductility in a low-density Fe-32Mn–11Al steel, Nanomaterials, 15(2024), No. 1, art. No. 48.

[41]	Du C, Hoefnagels JPM, Vaes R, Geers MGD. Block and sub-block boundary strengthening in lath martensite. Scr. Mater., 2016, 116: 117

[42]	L.F. Sun, Z.F. He, N. Jia, et al., Local chemical order enables an ultrastrong and ductile high-entropy alloy in a cryogenic environment, Sci. Adv., 10(2024), No. 48, art. No. eadq6398.

[43]	Russell KC, Brown LM. A dispersion strengthening model based on differing elastic moduli applied to the iron-copper system. Acta Metall., 1972, 207969

[44]	Z.P. Xiong, I. Timokhina, and E. Pereloma, Clustering, nanoscale precipitation and strengthening of steels, Prog. Mater. Sci., 118(2021), art. No. 100764.

[45]	X.C. Yang, X.J. Di, Q.Y. Duan, W. Fu, L.Z. Ba, and C.N. Li, Effect of precipitation evolution of NiAl and Cu nanoparticles on strengthening mechanism of low carbon ultra-high strength seamless tube steel, Mater. Sci. Eng. A, 872(2023), art. No. 144939.

[46]	Y.L. Wang, Y.F. Shen, N. Jia, J.J. Wang, and S.X. Zhao, Acicular martensite induced superior strength-ductility combination in a 20Cr2Ni2MoV steel, Mater. Sci. Eng. A, 848(2022), art. No. 143400.

[47]	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.

[48]	Zhao XY, Zhang XX, Zhou JQet al.. Direct quenching and double tempering obtain high strength and toughness of Cu-bearing HSLC martensitic steel. J. Mater. Res. Technol., 2025, 35: 13

[49]	Sk MB, Khan AK, Lenka Set al.. Effect of microstructure and texture on the impact transition behaviour of thermomechanically treated reinforcement steel bars. Mater. Des., 2016, 90: 1136

[50]	You Y, Shang CJ, Chen L, Subramanian S. Investigation on the crystallography of the transformation products of reverted austenite in intercritically reheated coarse grained heat affected zone. Mater. Des., 2013, 43: 485

[51]	X.Y. Zhang, J.L. Wang, T. Zhou, L. Yan, and H. Yu, Impact toughness and fracture propagation mechanism of NiAl precipitation-strengthened HSLA steels, Mater. Des., 241(2024), art. No. 112927.

[52]	Dong XX, Shen YF, Jia N, Xue WY, Li JP. Optimizing strength & ductility combination of medium-carbon TRIP steel via multi-stage work hardening. J. Mater. Res. Technol., 2024, 30: 1414

[53]	Peng B, Wang H, Zhou Met al.. Ultrastrong metallic materials via minimal lattice misfit and strong ordering effect. Sci. China Mater., 2023, 66114182

[54]	M. Shih, J.S. Miao, M. Mills, and M. Ghazisaeidi, Stacking fault energy in concentrated alloys, Nat. Commun., 12(2021), No. 1, art. No. 3590.

[55]	X.Y. Li, Z. Zhang, and J.W. Wang, Deformation twinning in body-centered cubic metals and alloys, Prog. Mater. Sci., 139(2023), art. No. 101160.

[56]	Rahman KM, Vorontsov VA, Dye D. The effect of grain size on the twin initiation stress in a TWIP steel. Acta Mater., 2015, 89: 247

[57]	T.J. Chen, E.X. Cui, Y.F. Shen, N. Jia, Z.D. Wang, and Z.J. Fan, Superior combination of strength and ductility in Fe–10Mn–0.6C steel trigged by austenite reversion transformation, Mater. Sci. Eng. A, 901(2024), art. No. 146579.