| METALS AND METAL MATRIX COMPOSITES |
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| Research Progress on Work-hardening Behavior of In-situ Bulk Metallic Glass Composites |
| ZHAI Haimin1,2,*, OU Mengjing1,2, YUAN Huayan1,2, Cui Shuai3, LI Wensheng1,2,*
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1 State Key Laboratory of Advanced Processing and Recycling of Non-ferrous Metals,Lanzhou University of Technology,Lanzhou 730050,China
2 School of Materials Science and Engineering,Lanzhou University of Technology,Lanzhou 730050,China
3 School of Materials Science and Engineering,Nanjing University of Science and Technology,Nanjing 210094,China |
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Abstract Bulk metallic glass (BMG) exhibits excellent mechanical and physical properties owing to its short-range order and long-range disorder. Such glasses have been widely studied as potential structural materials. However,they are prone to brittle fracture when loaded at room temperature because they undergo local shearing at room temperature,especially under uniaxial tension,thereby lacking plasticity. To overcome this shortcoming,researchers have proposed that introducing a crystalline phase would suppress the instability expansion of the shear band,thereby ensuring the tensile ductility of BMG composites (BMGCs) at room temperature. However,in most in-situ Ti- and Zr-based BMGCs,the dislocation strengthening in the crystalline phase could not compensate for the shear softening effect in the glass matrix. The resultant softening and necking during deformation limit the practical engineering applications of BMGCs. Researchers have also proposed the strengthening mechanisms of traditional steel materials,such as transformation-induced plasticity or twining-induced plasticity for BMGCs. These strengthening mechanisms adequately compensate for the shear softening effect caused by the initiation and expansion of multiple shear bands in the glass matrix. The strengthened CuZr- and Ti-based BMGCs show obviously improved work-hardening ability and tensile plasticity. This work focuses on the key scientific problems related to the work-hardening behaviour of BMGCs,classifies and introduces several common methods for work hardening in BMGCs, and discusses the research progress on hardening mechanisms of BMGCs in the last decade. Moreover, current problems associated with the strengthening and hardening of BMGCs are discussed,providing a reference for the design and preparation of toughened in-situ BMGCs and the study of microscopic deformation mechanisms.
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Published:
Online: 2022-12-09
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| Fund:National Natural Science Foundation of China (51901092, 52075234), the Program of Science and Technology International Cooperation Demonstrative Base of Metal Surface Engineering along the Silk Road (2017D01003), the Natural Science Foundation of Gansu Province (20JR5RA431), the Hongliu Distinguished Young Talent Support Program of Lanzhou University of Technology(26/062005), and the Open Fund Project of Hunan Province Key Laboratory of Electromagnetic Equipment Design and Manufacturing, Hunan Institute of Technology (DC202001). |
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1 Inoue A,Takeuchi,A. Acta Materialia 2011,59,2243.
2 Greer A L,Cheng Y Q,Ma E. Materials Science and Engineering R: Reports, 2013,74,71.
3 Li H X,Lu Z C,Wang S L,et al. Progress in Materials Science,2019,103,235.
4 Wang W H. Progress in Physics,2013,33(5),177 (in Chinese).
汪卫华. 物理学进展,2013,33(5),177.
5 Eckert J,Das J,Pauly S,et al. Advanced Engineering Materials,2007,9(2),443.
6 Qiao J W. Journal of Materials Science and Technology,2013,29(8),685.
7 Qiao J,Jia H,Liaw P K. Materials Science and Engineering R: Reports,2016,100,1.
8 Hays C C,Kim C P,Johnson W L. Physical Review Letters,2000,84,2901.
9 Hofmann D C,Suh J Y,Wiest A,et al. Nature,2008,451,1085.
10 Hofmann D C,Suh J Y,Wiest A,et al. Proceedings of the National Academy of Sciences of the United States of America,2008,105,20136.
11 Qiao J W,Wang S,Zhang Y,et al. Applied Physics Letters,2009,94,151905.
12 Narayan R L,Singh P S,Hofmann D C,et al. Acta Materialia, 2012,60,5089.
13 Chen G,Cheng J L,Liu C T. Intermetallics,2012,28,25.
14 Cheng J L,Chen G,Liu C T,et al. Scientific Reports,2013,3,2097.
15 Bai J,Li J S,Qiao J W,,et al. Scientific Reports,2016,6,32287
16 Qiao J W,Sun A C,Huang E W,et al. Acta Materialia,2011,29,4126.
17 Oh Y S,Kim C P,Lee S,et al. Acta Materialia,2011,59,7277.
18 Jeon C,Kim C P,Joo S H,et al. Acta Materialia,2013,61,3012.
19 Rim K R,Park J M,Kim W T,et al. Journal of Alloys and Compounds,2013,579,253.
20 Park J M,Lim K R,Park E S,et al. Journal of Alloys and Compounds,2014,615,S113.
21 Kolodziejska J A,Kozachkov H,Kranjc K,et al. Scientific Reports,2016,6,22563.
22 Zhang L,Narayan R L,Fu H M,et al. Acta Materialia,2019,168,24.
23 Lee M L,Li Y,Schuh C A. Acta Materialia,2004,52,4121.
24 Qiao J W,Zhang Y,Jia H L,et al. Applied Physics Letters,2012,100,121902.
25 Pauly S,Gorantla S,Wang G,et al. Nature Materials,2010,9,473.
26 Song W L,Song K K,Liu Z Q,et al. Materials China,2014,33(5),300(in Chinese).
宋温丽,宋凯凯,刘增乾,等. 中国材料进展,2014,33(5),300.
27 Wu Y,Song W L,Zhou J,et al. Acta Physica Sinica, 2017,66(17),176111 (in Chinese).
吴渊,宋温丽,周捷,等.物理学报,2017,66(17),176111.
28 Fan J,Qiao J W,Wang Z H,et al. Scientific Reports,2017,7,1877.
29 Zhai H M,Wang H F,Liu F. Journal of Alloys and Compounds,2016,685,322.
30 Wu Y,Xiao Y H,Chen G L,et al. Advanced Materials,2010,22,2770.
31 Wu Y,Wang H,Wu H H,et al. Acta Materialia,2011,59,2928.
32 Hofmann D C. Science,2010,329,1294.
33 Liu Z Q,Li R,Liu G,et al. Acta Materialia,2012,60,3128.
34 Kim C P,Oh Y S,Lee S,et al. Scripta Materialia,2011,65,304.
35 Fan J,Rao W,Qiao J W,et al. Journal of Materials Science and Technology, 2020,50,192.
36 Zhai H M,Xu Y H,Du Y,et al. Journal of Non-Crystalline Solids,2017,471,128.
37 Gao J H,Sharp J,Guan D,et al. Acta Materialia, 2015,86,208.
38 Chen M W,Inoue A,Zhang W,et al. Physical Review Letters,2006,96,245502.
39 Sun G Y,Zhang M. Materials Reports B:Research Papers,2019,33(1),462(in Chinese).
孙国元,张敏. 材料导报:研究篇,2019,33 (1),462.
40 Shao Y,Yao K F,Li M,et al. Applied Physics Letters,2013,103,171901.
41 Qiao J W,Zhang T,Yang F Q,et al. Scientific Reports,2013,3,2816.
42 Pan J,Wang Y X,Guo Q,et al. Nature Communications,2018,9,560.
43 Zhai H M,Wang H F,Liu F. Transactions of Nonferrous Metals Society of China (English Edition),2017,27,363.
44 Eckert J,Das J,Kim K B,et al. Intermetallics,2006,14,876.
45 Liu Y H,Wang G,Wang R J,et al. Science,2007,315,1385.
46 Wang Z T,Pan J,Li Y,et al. Physical Review Letters,2013,111,135504.
47 Pan J,Ivanov Yu P,Zhou W H,,et al. Nature,2020,578,559.
48 Lu Z P,Jiang S H,He J Y,et al. Acta Metallurgica Sinica,2016,52(10),1183(in Chinese).
吕昭平,蒋虽合,何骏阳,等. 金属学报,2016,52(10),1183.
49 Zhang Z Y,Wu Y,Zhou J,et al. Intermetallics,2013,42,68.
50 Zhang Z Y,Wu Y,Zhou J,et al. Scripta Materialia,2013,69,73.
51 Hong S H,Kim J T,Park H J,et al. Intermetallics,2015,62,36.
52 Hong S H,Kim J T,Park H J,et al. Intermetallics,2016,75,1.
53 Louzguine-Luzgin D V,Vinogradov A, Xie G, et al. Philosophical Magazine,2009,89(32),2887.
54 Guo W,Kato H. Materials and Design,2015,83,238.
55 Wu F F,Chan K C,Jiang S S,et al. Scientific Reports,2014,4,5302.
56 Pauly S,Das J,Bednarcik J,et al. Scripta Materialia,2009,60,431.
57 Song K K,Pauly S,Zhang Y,et al. Acta Materialia,2011,59,6620.
58 Song K K,Pauly S,Sun B A,et al. Intermetallics,2012,30,132.
59 Liu Y J,Yao H W,Zhang T W,et al. Materials Science & Engineering A,2017,682,542.
60 Pauly S,Liu G,Wang G,et al. Acta Materialia,2009,57,5445.
61 Liu Z Q,Liu G,Qu R T,et al. Scientific Reports,2014,4,4167.
62 Jiang Y P,Qiu K. Materials & Design,2015,65,410.
63 Shete M K,Singh I,Narasimhan R,et al. Scripta Materialia,2016,124,51.
64 Zhou H F,Qu S X,Yang W. International Journal of Plasticity,2013,44,147.
65 Liu Z Q,Li R,Liu G,et al. AIP Advances,2012,2,032176.
66 Wu G J,Li R,Liu Z Q,et al. Intermetallics,2012,24,50.
67 Okulov I V,Soldatov I V,Sarmanova M F,et al. Nature Communications,2015,6,7932.
68 Song W L,Wu Y,Wang H,et al. Advanced Materials,2016,28,8156.
69 Mu J,Zhu Z W,Su R,et al. Acta Materialia,2013,61,5008.
70 Wu Y,Zhou D Q,Song W L,et al. Physical Review Letters,2012,109,245506.
71 Sun B A,Song K K,Pauly S,et al. International Journal of Plasticity,2016,85,34.
72 Dong J L,Zhang T W,Wang Z,et al. Materials Science & Engineering A,2018,736,329.
73 Zhang L,Pauly S,Tang M Q,et al. Scientific Reports,2016,6,19235.
74 Zhang L,Zhu Z W,Fu H M,et al. Materials Science and Engineering: A,2017,689,404.
75 Zhang L,Narayan R L,Fu H M,et al. Acta Materialia,2019,168,24.
76 Zhang L,Zhang H F,Li W Q,et al. Journal of Alloys and Compounds,2017,708,972.
77 Hofmann D C,Suh J Y,Wiest A,et al. Scripta Materialia,2008,59,684.
78 Zhai H M,Wang H F,Liu F. Materials & Design,2016,110,782.
79 Sun X H,Wang Y S,Fan J,et al. Materials & Design,2015,86,266.
80 Xia S H,Wang J T. International Journal of Plasticity,2010,26,1442.
81 Weng G J. Journal of the Mechanics and Physics of Solids,1990,38,419.
82 Zhai H M,Xu Y H,Zhang F,et al. Journal of Alloys and Compounds,2016,694,1.
83 Chen H,He Y,Shiflet G J,et al. Nature,1994,367,541. |
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