Microstructure Recrystallization and Mechanical Properties of a Cold-Rolled TiNbZrTaHf Refractory High-Entropy Alloy

doi:10.1007/s40195-023-01649-x

Abstract

Abstract:

The equiatomic TiNbZrTaHf alloy was successfully rolled at room temperature with the reduction of ~ 85%. The microstructure and tensile properties were investigated after cold working and annealing. It was determined that the recrystallization temperature of the TiNbZrTaHf alloy between 850 and 900 °C. Complete recrystallization and normal grain growth occurred, the high stability of single phase was maintained after annealing at 1000, 1200, and 1400 °C. But the precipitated phase appeared after long term annealing, as seen after 500 h at 1000 °C. After cold working, the tensile strength and the elongation of TiNbZrTaHf were 1137 MPa and 25.1%, respectively. The annealed alloy has a high tensile strength (σ_b = 863 MPa) and ductility (ε_e = 28.5%). Moreover, the oxidation of TiNbZrTaHf alloy at elevated temperatures has a significant impact on its mechanical properties. The poor oxidation resistance of TiNbZrTaHf can accelerate tensile failure by inducing fractures at grain boundaries.

Key words: Refractory high entropy alloy, Cold rolling, Recrystallization, Oxidation resistance, Mechanical properties

Chuan Rong, Jieren Yang, Xiaoliang Zhao, Ke Huang, Ying Liu, Xiaohong Wang, Dongdong Zhu, Ruirun Chen. Microstructure Recrystallization and Mechanical Properties of a Cold-Rolled TiNbZrTaHf Refractory High-Entropy Alloy[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(4): 633-647.

Figures/Tables 18

Fig. 1 a X-ray diffraction pattern, b microstructure of the as-cast TiNbZrTaHf refractory alloy

Fig. 2 a Microstructure of the TiNbZrTaHf alloy after 85% reduction in thickness (the cold rolling direction is horizontal), b line profiles of the misorientation angle along the arrow AB, c pole figure of grain 1 (G1) and grain 2 (G2), d the kernel average misorientation (KAM) mapping, e boundary misorientation distribution

Fig. 3 Microstructures and grain diameter distribution histogram of TiNbZrTaHf after 85% thickness reduction and annealing at 1000 °C for a, b 1 h, c, d 4 h, e, f 24 h, g, h 500 h. Low angle boundaries (LABs) with misorientations (θ), 2° ≤ θ < 15° and high angle boundaries (HABs) with θ ≥ 15° are shown in white and black lines, respectively

Fig. 4 Invert pole figures for the normal (ND), rolling (RD) and transverse (TD) directions of TiNbZrTaHf alloys a after 85% cold-rolled and annealing at 1000 °C for b 1 h, c 24 h

Fig. 6 In-situ microstructure evolution in the cold-rolled TiNbZrTaHf alloy during continuous heating at ~ 280 K/min: a 22 °C, b 1200 °C, c 1300 °C, d 1400 °C

Fig. 7 In-situ microstructure evolution during isothermal holding at 1400 °C: a 1 min, b 2 min, c 5 min, d 10 min, e 30 min, f 60 min

Fig. 8 a-f Needlelike precipitation during isothermal holding at 1400 °C: a 22 min, b 23 min, c 24 min, d 25 min, e 26 min, f 27 min, and g EDS maps after annealing at 1400 °C for 1 h

Fig. 9 Engineering stress vs. engineering strain tensile curves of as-cast, cold rolled and annealed TiNbZrTaHf alloy. The inset shows the geometry of the tensile sample (R, radius of curvature)

Table 1 RT tensile properties of TiNbZrTaHf refractory alloy

Alloy	σ_0.2 (MPa)	σ_b (MPa)	ε_e (%)
As-cast	639	668	27.9
85% cold rolling	1089	1137	25.1
1200 °C, 1 h	803	863	28.5

Fig. 5 Microstructure of TiNbZrTaHf after 85% reduction and annealing at 1200 °C for a 1 h, b 4 h and annealing at 1400 °C for c 1 h, d 4 h

Fig. 10 SEM images of the tensile fracture surface of TiNbZrTaHf tested at room temperature: a as-cast, b, c cold-rolled, d annealed 1 h at 1200 °C

Fig. 11 Engineering stress vs. engineering strain tensile curves of a as-cast, b cold-rolled with 85% reduction, c annealed 1 h at 1200 °C of TiNbZrTaHf alloy

Fig. 12 SEM images of the tensile fracture surface of TiNbZrTaHf tested at elevated temperature: as-cast alloy at a 800 °C and b 900 °C, cold-rolled alloy at c 800 °C and d 900 °C, 1200 °C annealed 1 h alloy at e 800 °C, f 900 °C

Fig. 13 Annealed microstructures of TiNbZrTaHf alloy after cold rolling (85% reduction) for 1 h: a 800 °C, b 850 °C, c 900 °C, boundary misorientation distribution at d 800 °C, e 850 °C, f grain diameter distribution histogram

Fig. 14 Linear relationship between lnD and lnt for the grain growth at: a 1000 and 1200 °C, b 1400 °C

Table 2 EDS analysis of selected regions in Fig. 15 (at.%)

Treatment temperature	Region	Ti	Nb	Zr	Ta	Hf	O
1000 °C	A	8.51	4.08	24.81	11.98	22.50	28.12
1000 °C	B	22.19	17.17	8.25	20.00	14.34	18.08
1200 °C	C	53.89	0.72	0.07	0.40	0.06	44.85
	D	1.87	1.31	6.64	7.01	12.73	70.44
	E	7.71	33.73	0.01	35.12	1.92	23.12

Fig. 15 a BSE image after annealing at 1000 °C for 500 h, b the EBSD image and c the related phase distribution, d, e BSE images after annealing at 1200 °C for 500 h and f its XRD pattern

Fig. 16 Oxidation microstructures of TiNbZrTaHf alloy at 1200 °C for 168 h: a surface, b cross-section, c EDS maps of cross-section

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