Enhanced strength and ductility in Ti46Al4Nb1Mo alloys via boron addition

doi:10.1016/j.jmst.2021.06.037

Abstract

Abstract:

To improve the strength and ductility of TiAl alloys by second phase, Ti46Al4Nb1Mo alloys doped with different B content (0.4%, 0.8%, 1.2%, 1.6% and 2.0%, atomic percent, hereafter in at.%, referred to as TNM-xB) were prepared. Macro/microstructure evolution, mechanical properties and deformation mechanisms of the alloys were studied systematically. Results showed that the microstructure of TNM-0.4B and TNM-0.8B alloy remained columnar dendrites, and the secondary dendritic arms of columnar grains were more obvious. When the content of B is 1.2%, the columnar dendrites transformed to equiaxed grains, and the α₂/γ lamellae colony size was further refined in TNM-1.6B and TNM-2.0B alloy. The morphologies and kinds of the borides were changed with increasing B content, XRD results showed that TiB phase appeared with 1.6%B content, and both TiB and TiB₂ phase formed in TNM-2.0B alloy. There were straight and curved TiB phases located around grain boundaries in TNM-0.4B and TNM-0.8B alloy, and when the content of B increased to 1.2%, the curved TiB phases were reduced, while the tiny and straight TiB phases increased. With further increasing B content to 1.6% and 2.0%, the tiny and straight TiB phases were coarser. Compressive testing results showed that the mechanical properties of the TNM alloy were enhanced with increasing B content. The maximum strength and strain of TNM alloy were 2339MPa and 33.7% with 1.6% B addition. The compressive strength and strain were mainly enhanced via refinement of lamellar colony and formation of TiB, and it is found that pile-up of dislocations and deformed twins promoted by TiB are predominant in improving the mechanical properties of TNM alloys with higher strength and strain.

Key words: TiAl alloy, TiB, Microstructure, Mechanical properties

Yingmei Tan, Ruirun Chen, Hongze Fang, Yangli Liu, Hongzhi Cui, Yanqing Su, Jingjie Guo, Hengzhi Fu. Enhanced strength and ductility in Ti46Al4Nb1Mo alloys via boron addition[J]. J. Mater. Sci. Technol., 2022, 102: 16-23.

Figures/Tables 11

Fig. 1. XRD patterns of TNM-xB alloys.

Fig. 2. Macrostructure (a) TNM; (b) TNM-0.4B; (c) TNM-0.8B; (d) TNM-1.2B; (e) TNM-1.6B; (f) TNM-2.0B.

Fig. 3. SEM images (a) TNM; (b) TNM-0.4B; (c) TNM-0.8B.

Fig. 4. SEM images (a) TNM; (b) TNM-0.4B; (c) TNM-0.8B; (d) TNM-1.2B; (e) TNM-1.6B; (f) TNM-2.0B.

Fig. 5. EDS result (a) TNM; (b) TNM-1.2B; (c) TNM-1.6B; (d) EDS analysis of TiB.

Fig. 6. Compressive properties of TNM with increasing B content.

Fig. 7. Tensile properties of TNM and TNM-1.6B alloy.

Fig. 8. SEM-BSE images of TNM-0.8B alloy:(a), (b), (c) and (d) microstructure near the fracture surface.

Fig. 9. SEM-SE images of TNM-1.6B alloys: (a), (b), (c) and (d) fracture morphology of TNM-1.6B alloy.

Fig. 10. TEM deformed microstructure of TNM and TNM-1.6B alloy (a) and (b) TNM alloy deformed to 20%; (c) and (d) TNM-1.6B alloy deformed to 20%.

Fig. 11. TEM deformed microstructure (a) and (c) TNM-1.6B alloy deformed to 29%; (b) EDS mapping of TiB in Fig.(a); (d) HRTEM image of twins in Fig.(c).

References 40

[1]	T. Noda, Intermetallics 6 (1998) 709-713. DOI URL
[2]	D.M. Dimiduk, Mater. Sci. Eng. A 263 (1999) 281-288. DOI URL
[3]	K. Kothari, R. Radhakrishnan, N.M. Wereley, Prog. Aerosp. Sci. 55 (2012) 1-16. DOI URL
[4]	G. Yang, H. Kou, Y. Zhang, J. Yang, J. Li, H. Fu, Adv. Eng. Mater. 18 (2016) 1645-1650. DOI URL
[5]	R.M. Imayev, V.M. Imayev, M. Oehring, F. Appel, Intermetallics 15 (2007) 451-460. DOI URL
[6]	S. Saeedipour, A. Kermanpur, F. Sadeghi, J. Alloys Compd. 817 (2020) 152749.
[7]	Y. Liu, R. Hu, J. Yang, J. Li, Mater. Sci. Eng. A 679 (2017) 7-13. DOI URL
[8]	S.A. Raji, A.P.I. Popoola, S.L. Pityana, O.M. Popoola, Heliyon 6 (2020) e04463.
[9]	U. Hecht, V. Witusiewicz, A. Drevermann, J. Zollinger, Intermetallics 16 (2008) 969-978. DOI URL
[10]	J. Li, S. Jeffs, M. Whittaker, N. Martin, Intermetallics 127 (2020) 106984.
[11]	D.R. Johnson, H. Inui, S. Muto, Y. Omiya, T. Yamanaka, Acta Mater 54 (2006) 1077-1085. DOI URL
[12]	S.W. Kim, P. Wang, M.H. Oh, D.M. Wee, K.S. Kumar, Intermetallics 12 (2004) 499-509. DOI URL
[13]	D. Hu, Intermetallics 10 (2002) 851-858. DOI URL
[14]	J. Li, S. Jeffs, M. Whittaker, N. Martin, Mater. Des. 195 (2020) 109064.
[15]	M.Y. Koo, J.S. Park, M.K. Park, K.T. Kim, S.H. Hong, Scr. Mater. 66 (2012) 4 87-4 90. DOI URL
[16]	W.D. Wang, Y.C. Ma, B. Chen, M. Gao, K. Liu, Y.Y. Li, J. Mater. Sci. Technol. 26 (2010) 639-647. DOI URL
[17]	M.G. Li, S.L. Xiao, Y.Y. Chen, L.J. Xu, J. Tian, Mater. Sci. Eng. A 733 (2018) 190-198. DOI URL
[18]	T.T. Cheng, Intermetallics 8 (2000) 29-37. DOI URL
[19]	X.Y. Wang, S.P. Li, Y.F. Han, G.F. Huang, J.W. Mao, W.J. Lu, Scr. Mater 196 (2021) 113758.
[20]	G.L. Chen, X.J. Xu, Z.K. Teng, Y.L. Wang, J.P. Lin, Intermetallics 15 (2007) 625-631. DOI URL
[21]	G. Yang, H. Kou, J. Yang, J. Li, H. Fu, J. Alloys Compd. 663 (2016) 594-600. DOI URL
[22]	B.G. Liu, L.H. Liu, W.D. Xing, R.C. Liu, R. Yang, P.A. Withey, J. Zhu, R. Yu, Inter-metallics 90 (2017) 97-102.
[23]	P.A. Loginov, Y.Y. Kaplanskii, G.M. Markov, E.I. Patsera, K.V. Vorotilo, A.V. Ko-rotitskiy, N.V. Shvyndina, E.A. Levashov, Mater.Sci.Eng. A814 (2021) 141153.
[24]	T.I. Nazarova, V.M. Imayev, R.M. Imayev, Russ. Phys. J. 58 (2015) 797-802. DOI URL
[25]	M. Schloffer, F. Iqbal, H. Gabrisch, E. Schwaighofer, F.-P. Schimansky, S. Mayer, A. Stark, T. Lippmann, M. Göken, F. Pyczak, H. Clemens, Intermetallics 22 (2012) 231-240. DOI URL
[26]	A. Kelly, W.R. Tyson, J. Mech. Phys. Solids 13 (1965) 329-350. DOI URL
[27]	L. Jia, C. Zhang, K. Kondoh, R. Niu, B. Chen, S. Li, Z. Lu, J. Mater. Res. Technol. 9 (2020) 10184-10188. DOI URL
[28]	T.E.J. Edwards, F. Di Gioacchino, R. Muñoz-Moreno, W.J. Clegg, Acta Mater 140 (2017) 305-316. DOI URL
[29]	J. Wang, H. Huang, Appl. Phys. Lett. 85 (2004) 5983-5985. DOI URL
[30]	Z. Jin, T.R. Bieler, Philos. Mag. A 71 (1995) 925-947. DOI URL
[31]	J.-P. Monchoux, J. Luo, T. Voisin, A. Couret, Mater. Sci. Eng. A 679 (2017) 123-132. DOI URL
[32]	Y. Guo, S. Xiao, Y. Chen, J. Tian, Z. Zheng, L. Xu, Intermetallics 126 (2020) 106933.
[33]	H. Feng, Y. Zhou, D. Jia, Q. Meng, Scr.Mater 55 (2006) 667-670.
[34]	Q. Meng, H. Feng, G. Chen, R. Yu, D. Jia, Y. Zhou, J. Cryst. Growth 311 (2009) 1612-1615. DOI URL
[35]	G.L. Chen, L.C. Zhang, Mater. Sci. Eng. A 329-331 (2002) 163-170. DOI URL
[36]	D. Li, G. Zhang, G. Lu, J. Wang, C. Liu, Corros. Sci. 177 (2020) 108971.
[37]	Y. Hao, J. Liu, S. Li, J. Li, X. Liu, X. Feng, Mater. Sci. Eng. A 705 (2017) 210-218. DOI URL
[38]	D.G. Morris, S. Günter, M. Leboeuf, Philos. Maga. A 69 (1994) 527-550.
[39]	F. Roters, D. Raabe, G. Gottstein, Acta Mater 48 (2000) 4181-4189. DOI URL
[40]	K. Lu, L. Lu, S. Suresh, Science 324 (2009) 349-352. DOI PMID