Recalescence Behavior, Solidification Characteristics and Microstructure Transformation of Rapidly Solidified Undercooled Cu-based Alloys

Hongfu Wang; Cheng Tang; Xibin He; Jin’e Yang; Jinpeng Xie

doi:10.1007/s11595-022-2655-3

Journal of Wuhan University of Technology Materials Science Edition ›› 2023, Vol. 37 ›› Issue (6) : 1228 -1239. DOI: 10.1007/s11595-022-2655-3

Metallic Materials

Recalescence Behavior, Solidification Characteristics and Microstructure Transformation of Rapidly Solidified Undercooled Cu-based Alloys

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Abstract

The undercooled solidification microstructures of Cu55Ni45, Cu55Ni43Co2, and Cu60Ni38Co2 Cu-base alloys were obtained by fluxing method. Using infrared temperature measuring device, the law of the change of the recalescence degree with the increase of the undercooling during rapid solidification was studied. At the same time, high-speed camera was used to capture and photograph the images of solid/liquid interface migration during rapid solidification of undercooled melt, and the morphology evolution of solidification front was discussed. Finally, the microstructure morphology and transformation process of the Cu-based alloys were systematically analyzed. It is found that the microstructure morphology of the alloys goes through the same evolution process and appeared two grain refinement phenomena, that is, “coarse dendrite-equiaxed grain — oriented fine dendrite — equiaxed grain”. But its characteristics undercooling ΔT ₁, ΔT ₂, and critical undercooling ΔT* varies. Electron backscatter diffraction (EBSD) and transmission electron microscopy (TEM) were used to characterize the grain refinement structure with high undercooling. EBSD results show that the grain refinement structure with high undercooling presents a very high proportion of high angle grain boundaries, the grain orientation is random and there is no high strength texture, and a large number of annealing twins, which indicates that recrystallization occurs in the structure. TEM results show that dislocation network and stacking fault density are relatively low in most areas of grain refinement structure with high undercooling, which can confirm the theory that stress induces recrystallization of the structure.

Keywords

rapid solidification / recalescence degree / solidification front / microstructure

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Hongfu Wang, Cheng Tang, Xibin He, Jin’e Yang, Jinpeng Xie. Recalescence Behavior, Solidification Characteristics and Microstructure Transformation of Rapidly Solidified Undercooled Cu-based Alloys. Journal of Wuhan University of Technology Materials Science Edition, 2023, 37(6): 1228-1239 DOI:10.1007/s11595-022-2655-3

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References

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[1]	Li D, Yang G, Zhou Y. Recalescence and Solidification Microstructure of Highly Undercooled Alloy Ni68B21Si11[J]. Acta Metallurgica Sinica, 1992, 28(10): 1-5.

[2]	Liu F, Yang G. Rapid Solidification of Highly Undercooled Bulk Liquid Superalloy: Recent Developments, Future Directions[J]. International Materials Reviews, 2013, 51(3): 145-170.

[3]	Wang H, An Y, Xu X, et al. Rapid Solidification Microstructure Evolution and Grain Refinement of Deeply Undercooled Nickel Alloys[J]. Materials Characterization, 2020, 170: 110 703.

[4]	Liu L, Ma X, Huang Q, et al. Solidification Process and Microstructure Evolution of Bulk Undercooled Co-Sn Alloys[J]. Transactions of Nonferrous Metals Society of China, 2013, 23(1): 289-293.

[5]	Zhang Z, Song G, Yang G. Recalescence Behavior and Solidification Structure of the Undercooled Fe82B17Si1 Eutectic Alloy[J]. Progress in Natural Science, 2000, 10(5): 364-370.

[6]	Yang C, Liu F, Yang G, et al. Structure Evolution Upon Non-equilibrium Solidification of Bulk Undercooled Fe-B System[J]. Journal of Crystal Growth, 2009, 311(2): 404-412.

[7]	Xi Z, Yang G, Zhou Y. Growth Morphology of Ni-3Si in High Undercooled Ni-Si Eutectic Alloy[J]. Progress in Natural Science, 1997, 5: 114-121.

[8]	Wang P, Liu F, Lu Y, et al. Grain Refinement and Coarsening in Hypercooled Solidification of Eutectic Alloy[J]. Journal of Crystal Growth, 2008, 310(19): 4 309-4 313.

[9]	Zhou S, Hu R, Li J, et al. Stress Induced Deformation in the Solidification of Undercooled Co80Pd20 Alloys[J]. Materials Science and Engineering: A, 2011, 528(3): 973-977.

[10]	An Y, Xu X, Zhao Y, et al. Nonequilibrium Solidification Velocity, Recalescence Degree and Grain Refinement of Highly Undercooled Ni-based Single-phase Alloys[J]. Journal of Alloys and Compounds, 2021, 881: 160 658.

[11]	An H, Yang J, Zhang X, et al. Rapid Dendrite Growth in Solidification of Highly Undercooled Alloys[J]. Journal of Wuhan University of Technology-Mater. Sci. Ed., 2021, 36(2): 259-261.

[12]	Ma K, Zhao Y, Xu X, et al. The Effect of Undercooling on Growth Velocity and Microstructure of Ni95Cu5 Alloys[J]. Journal of Crystal Growth, 2019, 513: 30-37.

[13]	Li J, Liu YC, Lu Y, et al. Structural Evolution of Undercooled Ni-Cu Alloys[J]. Journal of Crystal Growth, 1998, 192: 462-470.

[14]	Li J, Jie WQ, Yang G. Solidification Structure Formation in Undercooled Fe-Ni Alloy[J]. Acta Materialia, 2002, 50(7): 1797-1807.

[15]	Zhang D, Prasad A, Bermingham Michael J, et al. Grain Refinement of Alloys in Fusion-Based Additive Manufacturing Processes[J]. Metallurgical and Materials Transactions A, 2020, 51(9): 4 341-4 359.

[16]	Schwarz M, Karma A, Eckler K, et al. Physical Mechanism of Grain Refinement in Solidification of Undercooled Melts[J]. Physical Review Letters, 1994, 73(10): 1 380-1 383.

[17]	Jones BL, Weston GM. Grain Refinement in Undercooled Copper[J]. J. Aust. Inst. Met, 1970, 15: 3 167.

[18]	Zhang T, Liu F, Wang H, et al. Grain Refinement in Highly Undercooled Solidification of Ni85Cu15 Alloy Melt: Direct Evidence for Recrystallization Mechanism[J]. Scripta Materialia, 2010, 63(1): 43-46.

[19]	Horvay G. The Tension Field Created by a Spherical Nucleus Freezing into Its Less Dense Undercooled Melt[J]. International Journal of Heat and Mass Transfer, 1965, 8(2): 195-243.

[20]	Willnecker R, Herlach DM, Feuerbacher B. Grain Refinement Induced by a Critical Crystal Growth Velocity in Undercooled Melts[J]. Applied Physics Letters, 1990, 56(4): 324-326.

[21]	Perepezko JH. Nucleation Reactions in Undercooled Liquids[J]. Materials Science and Engineering A, 1984, 178(1): 105-111.

[22]	Mullis AM, Cochrane RF. Grain Refinement and the Stability of Dendrites Growing into Undercooled Pure Metals and Alloys[J]. Journal of Applied Physics, 1997, 82(8): 3 783-3 790.

[23]	Liu F, Yang G. Stress-induced Recrystallization Mechanism for Grain Refinement in Highly Undercooled Superalloy[J]. Journal of Crystal Growth, 2001, 231: 295-305.

[24]	Wang H, Liu F, Yang G. Experimental Study of Grain Refinement Mechanism in undercooled Ni-15at%Cu Alloy[J]. Journal of Materials Research, 2011, 25(10): 1 963-1 974.

[25]	Herlach D. Non-Equilibrium Solidification of Undercooled Metallic Melts[J]. Metals, 2014, 4(2): 196-234.

[26]	Chen Z, Yang Y, Chen Q, et al. Recalescence Effect Simulation and Microstructure Evolution of Undercooled Fe82B17Si1 Alloy[J]. Acta Metallurgica Sinica, 2014, 50(7): 795-801.

[27]	Boettinger WJ, Coriell SR, Trivedi R. Rapid Solidification Processing: Principles and Technologies IV[M], 1988 Baton Rouge: Claitor’s Pulishing Division.