Rejuvenated metallic glass strips produced via twin-roll casting

doi:10.1016/j.jmst.2019.08.022

Abstract

Abstract:

The energy state and atomic level structure of metallic glasses (MGs) are very sensitive to their cooling rates, and a lower cooling rate generally causes a lower energy and more relaxed state of MGs. In this work, the Zr_41.2Ti_13.8Cu_12.5Ni₁₀Be_22.5 (Vit. 1) ribbons with a thickness of 40 μm and 110 μm and the strips with a thickness of 320 μm and 490 μm were produced by single-roll melt spinning and twin-roll casting, respectively. The increase in thickness of either ribbons or strips results in a lower energy state with a smaller relaxation enthalpy, a lower content of free volume, and a higher hardness. Although the cooling rate of the twin-roll produced 320 μm-thick strip is almost one magnitude lower than that of the single-roll produced 110 μm-thick ribbon, the former, however, possesses a rejuvenated energy state as compared to the latter. Molecular dynamics simulations reveal that the squeezing force during twin-roll casting affects the evolution of connection types of clusters, and the 2-atom and 4-atom connections are prone to be retained, which results in a higher energy state of MGs. Such a rejuvenation process during twin-roll casting can overwhelm the relaxation process caused by the lower cooling rate. Therefore, twin-roll casting is not only a method being capable for producing strips with a large thickness, but also prone to obtain a high energy state of the MG strip.

Key words: Metallic glass, Metallic glass strip, Twin-roll casting, Rejuvenation, Cluster connection

Long Zhang, Yi Wu, Shidong Feng, Wen Li, Hongwei Zhang, Huameng Fu, Hong Li, Zhengwang Zhu, Haifeng Zhang. Rejuvenated metallic glass strips produced via twin-roll casting[J]. J. Mater. Sci. Technol., 2020, 38: 73-79.

Figures/Tables 11

Fig. 1. Schematic illustration of single-roll melting spinning and twin-roll casting for producing metallic glass ribbons and strips, respectively.

Fig. 2. Appearance of Vit. 1 ribbons prepared by single-roll melt spinning (a, b), and strips prepared by twin-roll casting (c, d). The respective thickness of ribbons/strips is given. (e) The XRD spectra of the Vit. 1 ribbons and strips.

Fig. 3. (a) TEM micrograph with an inset of SAED pattern and (b) HRTEM image with an inset of the FFT pattern of the twin-roll produced 490 μm-thick strip.

Fig. 4. (a) DSC traces and (b) the enlarged DSC trances before Tg of Vit. 1 ribbons and strips.

Fig. 5. DSC-measured relaxation enthalpies of the Vit. 1 ribbons and strips.

Fig. 6. Nanoindentation-measured hardness of the Vit. 1 ribbons and strips.

Fig. 7. (a) The integrated 1D diffraction profiles from their SAED patterns, and (b) the measured position of the first diffraction maximum (Q1).

Fig. 8. SEM micrographs of eutectic Al-33 wt% Cu alloy: (a) the ribbon prepared by single-roll melt spinning and (b) the strip prepared by single-roll casting. The characteristic spacing of the eutectic microstructure is used to estimate the cooling rate.

Fig. 9. Schematic diagram of the model Cu46Zr46Al8 MGs formed (a) at a cooling rate of 1 × 1012 K/s under hydrostatic pressure 0 GPa and (b) at a cooling rate of 5 × 1011 K/s under 1 GPa pressure along x-direction.

Fig. 10. Distributions of (a) Zr-centered, (b) Cu-centered and (c) Al-centered polyhedra in simulated Cu46Zr46Al8 MGs.

Fig. 11. Statistical connecting types of polyhedra with different shared atomic number(s).

References

[1]	W.H. Wang,Prog. Mater. Sci. 106 (2019), 100561.
[2]	J. Schroers, Phys. Today 66 (2013) 32-37.
[3]	Y. Wu, H. Wang, X.J. Liu, X.H. Chen, X.D. Hui, Y. Zhang, Z.P. Lu, J. Mater. Sci. Technol. 30 (2014) 566-575.
[4]	A. Inoue, Acta Mater. 48 (2000) 279-306.
[5]	J. Eckert, J. Das, S. Pauly, C. Duhamel, Adv. Eng. Mater. 9 (2007) 443-453.
[6]	C. Schuh, T. Hufnagel, U. Ramamurty, Acta Mater. 55 (2007) 4067-4109.
[7]	W. Klement, R.H. Willens, P. Duwez, Nature 187 (1960) 869-870.
[8]	E. Axinte, Mater. Des. 35 (2012) 518-556.
[9]	A. Inoue, A. Takeuchi, Acta Mater. 59 (2011) 2243-2267.
[10]	A.L. Greer, Science 267 (1995) 1947-1953.
[11]	W.L. Johnson, MRS Bull. 24 (1999) 42-56.
[12]	S.S. Park, G.T. Bae, D.H. Kang, I.-H. Jung, K.S. Shin, N.J. Kim, Scr. Mater. 57 (2007) 793-796.
[13]	J.H. Bae, A.K. Prasada Rao, K.H. Kim, N.J. Kim, Scr. Mater. 64 (2011) 836-839.
[14]	Y.S. Oh, H. Lee, J.G. Lee, N.J. Kim, Mater. Trans. 48 (2007) 1584-1588.
[15]	G. Duggan, D.J. Browne, Trans. IIM 62 (2009) 417-421.
[16]	Z.P. Pei, D.Y. Ju, X. Li, Trans. Nonferrous Met. Soc. China 27 (2017) 2406-2414.
[17]	Y. Sun, A. Concustell, A.L. Greer, Nat. Rev. Mater. 1 (2016) 16039.
[18]	C. Liu, P. Guan, Y. Fan, Acta Mater. 161 (2018) 295-301.
[19]	S.V. Ketov, Y.H. Sun, S. Nachum, Z. Lu, A. Checchi, A.R. Beraldin, H.Y. Bai, W.H. Wang, D.V. Louzguine-Luzgin, M.A. Carpenter, A.L. Greer, Nature 524 (2015) 200-203.
[20]	L. Zhao, K.C. Chan, S.H. Chen, S.D. Feng, D.X. Han, G. Wang, Acta Mater. 169 (2019) 122-134.
[21]	D. Şopu, A. Foroughi, M. Stoica, J. Eckert, Nano Lett. 16 (2016) 4467-4471.
[22]	L. Zhang, M. Tang, Z. Zhu, H. Fu, H. Zhang, A. Wang, H. Li, H. Zhang, Z. Hu, J. Alloys Compd. 638 (2015) 349-355.
[23]	P. Ross, S. Küchemann, P.M. Derlet, H. Yu, W. Arnold, P. Liaw, K. Samwer, R. Maaß, Acta Mater. 138 (2017) 111-118.
[24]	D.V. Louzguine-Luzgin, V.Y. Zadorozhnyy, S.V. Ketov, Z. Wang,A.A. Tsarkov A.L. Greer, Acta Mater. 129 (2017) 343-351.
[25]	J. Pan, Y.X. Wang, Q. Guo, D. Zhang, A.L. Greer, Y. Li, Nat. Commun. 9 (2018) 560.
[26]	D.J. Magagnosc, G. Kumar, J. Schroers, P. Felfer, J.M. Cairney, D.S. Gianola, Acta Mater. 74 (2014) 165-182.
[27]	X.L. Bian, G. Wang, H.C. Chen, L. Yan, J.G. Wang, Q. Wang, P.F. Hu, J.L. Ren, K.C. Chan, N. Zheng, A. Teresiak, Y.L. Gao, Q.J. Zhai, J. Eckert, J. Beadsworth, K.A. Dahmen, P.K. Liaw, Acta Mater. 106 (2016) 66-77.
[28]	C. Gammer, C. Mangler, C. Rentenberger, H.P. Karnthaler, Scr. Mater. 63 (2010) 312-315.
[29]	Y.Q. Cheng, E. Ma, H.W. Sheng,Phys. Rev. Lett. 102 (2009), 245501.
[30]	S. Plimpton, J. Comput. Phys. 117 (1995) 1-19.
[31]	W.G. Hoover, Phys. Rev. A 31 (1985) 1695-1697.
[32]	M. Parrinello, A. Rahman, J. Appl. Phys. 52 (1981) 7182-7190.
[33]	K. Kosiba, D. S¸ opu, S. Scudino, L. Zhang, J. Bednarcik, S. Pauly, Int. J. Plast. 119 (2019) 156-170.
[34]	W. Dmowski, Y. Yokoyama, A. Chuang, Y. Ren, M. Umemoto, K. Tsuchiya, A. Inoue, T. Egami, Acta Mater. 58 (2010) 429-438.
[35]	A.R. Yavari, A. Le Moulec, A. Inoue, N. Nishiyama, N. Lupu, E. Matsubara, W.J. Botta, G. Vaughan, M. Di Michiel, A. Kvick, Acta Mater. 53 (2005) 1611-1619.
[36]	M. Samavatian, R. Gholamipour, A.A. Amadeh, S. Mirdamadi, Mater. Sci. Eng. A 753 (2019) 218-223.
[37]	T.J. Lei, L.R. DaCosta, M. Liu, W.H. Wang, Y.H. Sun, A.L. Greer, M. Atzmon, Acta Mater. 164 (2019) 165-170.
[38]	D. Sopu, C. Soyarslan, B. Sarac, S. Bargmann, M. Stoica, J. Eckert, Acta Mater. 106 (2016) 199-207.
[39]	W.H. Wang, Q. Wei, S. Friedrich, Phys. Rev. B 57 (1998) 8211-8217.
[40]	R.M. Srivastava, J. Eckert, W. Löser, B.K. Dhindaw, L. Schultz, Mater. Trans. 43 (2002) 1670-1675.
[41]	K. Kosiba, S. Pauly, Sci. Rep. 7 (2017) 2151.
[42]	S. Pauly, P. Wang, U. Kühn, K. Kosiba, Addit. Manuf. 22 (2018) 753-757.
[43]	A. Peker, W.L. Johnson, Appl. Phys. Lett. 63 (1993) 2342-2344.
[44]	J. Ding, E. Ma, M. Asta, R.O. Ritchie, Sci. Rep. 5 (2015) 17429.
[45]	J. Ding, E. Ma, NPJ Comput. Mater 3 (2017) 9.
[46]	S.D. Feng, K.C. Chan, L. Zhao, S.P. Pan, L. Qi, L.M. Wang, R.P. Liu, Mater. Des. 158 (2018) 248-255.