Mo and Ta addition in NbTiZr medium entropy alloy to overcome tensile yield strength-ductility trade-off

doi:10.1016/j.jmst.2021.08.073

Abstract

Abstract:

In this study, single-phase NbTiZr and NbTiZr(MoTa)_0.1 medium-entropy alloys (MEAs) were investigated for their use in biomedical implants. The alloys were prepared by arc melting, and were then cold-rolled, annealed, and characterized in terms of phase analysis, mechanical properties, fractography, and wear resistance. Both alloys showed a single body-centered cubic phase with superior mechanical, and tribological properties compared to commercially available biomedical alloys. Mo and Ta-containing MEAs showed higher tensile yield strength (1060 ± 18 MPa)) and higher tensile ductility (∼20%), thus overcoming the strength-ductility trade-off with no signs of transformation-induced plasticity, twinning, or precipitation. The generalized stacking fault energy (GSFE) calculations on the {112}<111> slip system by the first-principles calculations based on density functional theory showed that the addition of less than 0.2 molar fraction of Mo and Ta lowers the GSFE curves. This behavior posits the increase in ductility of the alloy by facilitating slips although strength is also increased by solid solution strengthening. The wear resistance of both alloys against hardened steel surfaces was superior to that of commercial biomedical alloys. Thus, we concluded that NbTiZr(MoTa)_0.1 MEA with good tensile ductility is a potential candidate for biomedical implants.

Key words: Medium-entropy alloys, Wear-resistant, Biomedical implants, Solid solution hardening, Staking fault energy

Muhammad Akmal, Hyun Woo Seong, Ho Jin Ryu. Mo and Ta addition in NbTiZr medium entropy alloy to overcome tensile yield strength-ductility trade-off[J]. J. Mater. Sci. Technol., 2022, 109: 176-185.

Figures/Tables 9

Fig. 1. (a) SQS-60 supercell and (b) SQS-60vac supercell of NbTiZrMoTa HEA.

Fig. 2. (a) NR, (b) FRNR, (c) ZR, and (d) FRZR of SQS-60vac supercell of NbTiZrMoTa HEA.

Fig. 3. (a) XRD patterns of the MEAs and (b) Camera images and EBSD micrographs of the alloys.

Fig. 4. (a) P-h curves of the MEAs, (b) Wear rate of the MEAs and the commercial biomedical alloys, (c) Surface roughness of the alloys after wear testing.

Fig. 5. (a) True tensile stress-strain curves, (b) Fractography of the deformed samples, (c) Strain hardening rate, and (d) EBSD images of unstrained and strained samples of NbTiZr and NbTiZr(MoTa)0.1 MEAs.

Fig. 6. (a) TEM image and (b) elemental mapping of the 10% strained NbTiZr(MoTa)0.1 MEA sample, (c) TEM image of 40% cold-rolled NbTiZr MEA, and (d) TEM image of 20% cold-rolled NbTiZr(MoTa)0.1 MEA.

Table 1. Lattice constant a0 of NbTiZr(MoTa)x system.

X value of the NbTiZr(MoTa)_x system	Method	a₀ (pm)	Refs.
0	DFT	339.4	The present work
	DFT	339.0	Rao et al. [66]
	Exp.	340.1	Senkov et al. [68]
	Exp.	341	Akmal et al. [21]
0.167	DFT	337.3	The present work
0.2	Exp.	338	Akmal et al. [21]
0.375	DFT	335.4	The present work
0.4	Exp.	336	Akmal et al. [21]
0.6	Exp.	335	Akmal et al. [21]
0.643	DFT	333.7	The present work
0.8	Exp.	333	Akmal et al. [21]
1	DFT	331.7	The present work
	DFT	332	Koval et al. [69]
	Exp.	bcc1 = 331.0, bcc2 = 337.9	Wang et al. [17]
	Exp.	bcc1 = 324, bcc2 = 340	Akmal et al. [21]

Fig. 7. GSFE curves with (a) x = 0, (b) x = 0.167, (c) x = 0.375, (d) x = 0.643, and (e) x = 1 of NbTiZ(MoTa)x alloys and (f) unstable stacking fault energy with X values.

Fig. 8. (a) Mixing enthalpies of important pairs involved in the alloys calculated by using the entall miedema calculator [70], (b) density and the strength-to-weight ratio of the alloys.

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