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Duplex metallic glass with two amorphous phases has been extensively investigated for desirable strength and plasticity. In this paper, the metastable phase separation and dual amorphous phase formation of liquid Zr35Al23Ni22Gd20 alloy under substantial undercooling condition and rapid cooling condition are studied by drop tube technology. The equilibrium solidification structure consists of three crystalline phases, while the critical undercooling temperature of metastable phase separation is determined to be 516 K (0.37TL). The separated Zr-rich liquid phase undergoes amorphous transition and becomes amorphous AM-Zr phase with the composition of Zr45Ni23Al23Gd9 when alloy undercooling is increased to 624 K (0.45TL). After that, the Gd-rich liquid phase forms amorphous AM-Gd phase with the composition of Gd39Al22Ni20Zr19 at larger undercooling of 714 K (0.52TL). With the increase of liquid undercooling and cooling rate, the kinetic mechanism of metastable phase separation changes from nucleation and growth type to spinodal decomposition type, and consequently the microstructure of dual amorphous phases transforms from a spherical morphology to a reticular structure. The average hardness and Young’s modulus, which are influenced by free volume, phase volume fraction and structure of dual amorphous phases, exhibit a complex variation of first increasing and then decreasing with the decrease of alloy droplet size. The formation of dual amorphous phases is in favor of the energy dissipation and the generation of multiple shear bands during mechanical compression, which improves the plasticity for this kind of amorphous alloy.
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Keywords:
- liquid undercooling /
- rapid solidification /
- metastable phase separation /
- duplex amorphous alloy
[1] Johnson W L, Samwer K 2005 Phys. Rev. Lett. 95 195501Google Scholar
[2] Schroers J 2013 Phys. Today 66 32Google Scholar
[3] Wisitsorasak A, Wolynes P G 2012 Proc. Natl. Acad. Sci. U. S. A. 109 16068Google Scholar
[4] Li H Q, Tao K X, Fan C, Liaw P K, Choo H 2006 Appl. Phys. Lett. 89 041921Google Scholar
[5] Xing L Q, Li Y, Ramesh K T, Li J, Hufnagel T C 2001 Phys. Rev. B. 64 180201Google Scholar
[6] Liu Y H, Wang G, Wang R J, Zhao D Q, Pan M X, Wang W H 2007 Science 315 1385Google Scholar
[7] Zong H T, Ma M Z, Zhang X Y, Qi L, Li G, Jing Q, Liu R P 2011 Chin. Phys. Lett. 28 036103Google Scholar
[8] Kim D H, Kim W T, Park E S, Mattern N, Eckert J 2013 Prog. Mater Sci. 58 1103Google Scholar
[9] Chen HS, Turnbull D 1969 Acta Metall. Mater. 17 1021Google Scholar
[10] Kündig AA, Ohnuma M, Ping D H, Ohkubo T, Hono K 2004 Acta Mater. 52 2441Google Scholar
[11] Du X H , Huang J C, Hsieh K C, Lai Y H, Chen H M, Jang J S C, Liaw P K 2007 Appl. Phys. Lett. 91 131901Google Scholar
[12] Baumer R E, Demkowicz M J 2013 Phys. Rev. Lett. 110 145502Google Scholar
[13] Banerjee R, Puthucode A, Bose S, Ayyub P 2007 Appl. Phys. Lett. 90 021904Google Scholar
[14] Chang H J, Yook W, Park E S, Kyeong J S, Kim D H 2010 Acta Mater. 58 2483Google Scholar
[15] Park B J, Chang H J, Kim D H, et al. 2006 Phys. Rev. Lett. 96 245503Google Scholar
[16] 沙莎, 王伟丽, 吴宇昊, 魏炳波 2018 67 046402Google Scholar
Sha S, Wang W L, Wu Y H, Wei B B 2018 Acta Phys. Sin. 67 046402Google Scholar
[17] Ruan Y, Wang Q Q, Chang S Y, Wei B 2017 Acta Mater. 141 456Google Scholar
[18] Luo B C, Liu X R, Wei B 2009 J. Appl. Phys. 106 053523Google Scholar
[19] 徐山森, 常健, 吴宇昊, 沙莎, 魏炳波 2019 68 196401Google Scholar
Xu S S, Chang J, Wu Y H, Sha S, Wei B B 2019 Acta Phys. Sin. 68 196401Google Scholar
[20] Levi C G, Mehrabian R 1982 Metall. Trans. A 13 221Google Scholar
[21] 陈克萍, 吕鹏, 王海鹏 2017 66 068101Google Scholar
Chen K P, Lü P, Wang H P 2017 Acta Phys. Sin. 66 068101Google Scholar
[22] Sohn S W, Yook W, Kim W T, Kim D H 2012 Intermetallics 23 57Google Scholar
[23] Bo H, Liu L B, Hu J L, et al. 2014 Thermochim. Acta 591 51Google Scholar
[24] Fischer E, Colinet C 2015 J. Phase Equilib. Diffus. 36 5Google Scholar
[25] Mattern N, Han J H, Zinkevich M, et al. 2012 Calphad 39 27Google Scholar
[26] Spaepen F 1977 Acta Metall. Mater. 23 407Google Scholar
[27] Liu Y, Bei H, Liu C T, George E P 2007 Appl. Phys. Lett. 90 513Google Scholar
[28] Bian X L, Wang G, Chan K C, Ren J L, Gao Y L, Zhai Q J 2013 Appl. Phys. Lett. 103 101907Google Scholar
[29] Dai L H, Liu L F, Yan M, Xie X, Wei B C, Jurgen E 2004 Chin. Phys. Lett. 21 1593Google Scholar
[30] Yan P X, Wang W L , Yan N, Sha S, Wei B B 2020 Sci. Sin. Technol. 50 1402Google Scholar
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图 3 Zr35Al23Ni22Gd20合金的双相共存区凝固组织与液滴直径关系 (a) D = 520 μm, 晶体非晶共存区; (b)晶体非晶共存区HRTEM放大图; (c) D = 390 μm, 双非晶相共存区; (d) D = 90 μm, 双非晶相; (a1), (c1), (d1)选区电子衍射; (c2), (d2) Gd元素EDS图谱
Figure 3. Duplex phases microstructure of Zr35Al23Ni22Gd20 alloy with different droplet diameters: (a) Crystalline and amorphous phases coexistence zone with 520 μm droplet diameter; (b) HRTEM micrograph of (a); (c) duplex amorphous phases coexistence zone with 390 μm droplet diameter; (d) duplex amorphous phases with 90 μm droplet diameter; (a1), (c1), (d1) selected area electron diffraction, (c2) and (d2) EDS-mapping of Gd.
图 6 四元Zr35Al23Ni22Gd20合金的热力学性质 (a)四组元之间的混合焓[23,24]; (b)二元Zr-Gd合金中的亚稳相分离区[25]; (c) Zr55(1–X)Al23Ni22Gd55X合金中Zr-Gd组元亚稳相分离曲线
Figure 6. Thermodynamic properties of quaternary Zr35Al23Ni22Gd20 alloy: (a) Mixing enthalpy between elements[23,24]; (b) metastable phase separation zone in binary Zr-Gd phase diagram[25]; (c) Zr-Gd metastable miscibility gap of Zr55(1–X)Al23Ni22Gd55X alloy.
图 10 双相非晶Zr35Al23Ni22Gd20合金流变行为 (a) 240 μm合金颗粒载荷-位移关系; 插图为(a)图的局部放大图; (b) 合金颗粒锯齿流变行为的归一化结果
Figure 10. Serration features of duplex amorphous phases Zr35Al23Ni22Gd20 alloy: (a) Load-displacement curves of solidified 240 μm droplet, where the inset is enlarged view of (a); (b) normalization results for serration properties of solidified alloy droplets.
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[1] Johnson W L, Samwer K 2005 Phys. Rev. Lett. 95 195501Google Scholar
[2] Schroers J 2013 Phys. Today 66 32Google Scholar
[3] Wisitsorasak A, Wolynes P G 2012 Proc. Natl. Acad. Sci. U. S. A. 109 16068Google Scholar
[4] Li H Q, Tao K X, Fan C, Liaw P K, Choo H 2006 Appl. Phys. Lett. 89 041921Google Scholar
[5] Xing L Q, Li Y, Ramesh K T, Li J, Hufnagel T C 2001 Phys. Rev. B. 64 180201Google Scholar
[6] Liu Y H, Wang G, Wang R J, Zhao D Q, Pan M X, Wang W H 2007 Science 315 1385Google Scholar
[7] Zong H T, Ma M Z, Zhang X Y, Qi L, Li G, Jing Q, Liu R P 2011 Chin. Phys. Lett. 28 036103Google Scholar
[8] Kim D H, Kim W T, Park E S, Mattern N, Eckert J 2013 Prog. Mater Sci. 58 1103Google Scholar
[9] Chen HS, Turnbull D 1969 Acta Metall. Mater. 17 1021Google Scholar
[10] Kündig AA, Ohnuma M, Ping D H, Ohkubo T, Hono K 2004 Acta Mater. 52 2441Google Scholar
[11] Du X H , Huang J C, Hsieh K C, Lai Y H, Chen H M, Jang J S C, Liaw P K 2007 Appl. Phys. Lett. 91 131901Google Scholar
[12] Baumer R E, Demkowicz M J 2013 Phys. Rev. Lett. 110 145502Google Scholar
[13] Banerjee R, Puthucode A, Bose S, Ayyub P 2007 Appl. Phys. Lett. 90 021904Google Scholar
[14] Chang H J, Yook W, Park E S, Kyeong J S, Kim D H 2010 Acta Mater. 58 2483Google Scholar
[15] Park B J, Chang H J, Kim D H, et al. 2006 Phys. Rev. Lett. 96 245503Google Scholar
[16] 沙莎, 王伟丽, 吴宇昊, 魏炳波 2018 67 046402Google Scholar
Sha S, Wang W L, Wu Y H, Wei B B 2018 Acta Phys. Sin. 67 046402Google Scholar
[17] Ruan Y, Wang Q Q, Chang S Y, Wei B 2017 Acta Mater. 141 456Google Scholar
[18] Luo B C, Liu X R, Wei B 2009 J. Appl. Phys. 106 053523Google Scholar
[19] 徐山森, 常健, 吴宇昊, 沙莎, 魏炳波 2019 68 196401Google Scholar
Xu S S, Chang J, Wu Y H, Sha S, Wei B B 2019 Acta Phys. Sin. 68 196401Google Scholar
[20] Levi C G, Mehrabian R 1982 Metall. Trans. A 13 221Google Scholar
[21] 陈克萍, 吕鹏, 王海鹏 2017 66 068101Google Scholar
Chen K P, Lü P, Wang H P 2017 Acta Phys. Sin. 66 068101Google Scholar
[22] Sohn S W, Yook W, Kim W T, Kim D H 2012 Intermetallics 23 57Google Scholar
[23] Bo H, Liu L B, Hu J L, et al. 2014 Thermochim. Acta 591 51Google Scholar
[24] Fischer E, Colinet C 2015 J. Phase Equilib. Diffus. 36 5Google Scholar
[25] Mattern N, Han J H, Zinkevich M, et al. 2012 Calphad 39 27Google Scholar
[26] Spaepen F 1977 Acta Metall. Mater. 23 407Google Scholar
[27] Liu Y, Bei H, Liu C T, George E P 2007 Appl. Phys. Lett. 90 513Google Scholar
[28] Bian X L, Wang G, Chan K C, Ren J L, Gao Y L, Zhai Q J 2013 Appl. Phys. Lett. 103 101907Google Scholar
[29] Dai L H, Liu L F, Yan M, Xie X, Wei B C, Jurgen E 2004 Chin. Phys. Lett. 21 1593Google Scholar
[30] Yan P X, Wang W L , Yan N, Sha S, Wei B B 2020 Sci. Sin. Technol. 50 1402Google Scholar
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