| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| Research Progress of 3D-printed Graphene-reinforced Composites |
| YI Denghao1, FENG Yinghao1, ZHANG Jinfang1, LI Xiaofeng1,2, LIU Bin1, LIANG Minjie1, BAI Peikang1
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1 School of Materials Science and Engineering, North University of China, Taiyuan 030051, China
2 Henan Huanghe Whirlwand Co., Ltd., Changge 461500, China |
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Abstract In recent years, graphene has become a research hotspot on account of its outstanding mechanical and thermal properties and the feasibility of mass production. If it used as a reinforcing phase in materials such as metals, polymers, and ceramics that is promising for enhancing the comprehensive performance of the composites. To meet the ever-increasing demand for composites performance optimization, widely varieties of manufacturing methods for the preparing graphene-based composites have emerged, in which 3D printing technology can achieve the perfect combination of process flexibility and high performance products.
However, graphene has a low density and is easily agglomerated due to its large specific surface area, which will affect the mechanical properties of the composites. In addition, poor wettability of graphene with ceramic or metal matrix cannot ensure a good interfacial bonding between graphene and the matrix. Therefore, how to uniformly disperse graphene in composites has been the research direction of researchers. Currently, the commonly used disperse graphene methods include solution mixing method, melt mixing method, in-situ mixing method and mechanical ball mil-ling method, they are widely used in the preparation of metal, polymer and ceramic composites. Among them, mechanical properties of metal or ceramic composites with uniform dispersion graphene were improved, and they got a good incorporation at the interface. In addition, the more researched graphene-reinforced polymer composites’mechanical properties, thermal and electrical characteristics have been significantly enhanced, and they were used in biomedical or energy storage fields,showing better biological or electrical properties.
This paper reviews the research progress of 3D-printed graphene-based composites from three aspects: metal materials, polymers and ceramic matrix composites. The application of graphene-reinforced composites are elaborated in 3D printing from milling and forming. In the future, graphene-reinforced composites are expected to widely used in energy devices, biological scaffolds and aerospace fields, which will extend a broader space for material research.
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Published: 27 April 2020
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| Fund:This work was financially supported by the National Natural Science Foundation of China (51804280), the Natural Science Foundation of Shanxi Province, China (201701D221086, 201801D221146), the Major Science and Technology Projects of Shanxi Province, China (20181101009), Department of Scientific and Technologial Innovation Programs of Higher Education Institutions in Shanxi (201802076), Returned Overseas Students Research Funding Project of Shanxi Province (2017-095), International Cooperation Project of Shanxi Province (201603D421024), the Support Program for Young Academic Leaders of North University of China, China (QX201802). |
About author:: Denghao Yi received his B.S. degree in applied chemistry from North University of China in 2017. He is currently pursuing master’s degree at the School of Material Science and Engineering, North University of China under the supervision of A/Prof. Li Xiaofeng. His research has focused on the preparation of graphene reinforced nickel matrix composites by selective laser melting (SLM).
Xiaofeng Li received his B.E. degree in material from Central South University in 2009 and received his Ph.D. degree in State Key Laboratory for Powder Metallurgy from Central South University, in 2016. He is currently an associate professor and master’s supervisor in North University of China. His research interests are powder metallurgy, additive manufacturing, design and deve-lopment of metal matrix composites. |
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1 Novoselov K S, Geim A K, Morozov S V, et al. Science,2004,306(5696),666.
2 Zhang Y Z, Mo G Q, Li X W, et al. Journal of Power Sources,2011,196(13),5402.
3 Huang X, Qi X, Boey F, et al. Chemical Society Reviews,2012,41(2),666.
4 Kasar A K, Xiong G, Menezes P L. JOM,2018,70(6),829.
5 Stoller M D, Park S, Zhu Y, et al. Nano Letters,2008,8(10),3498.
6 Balandin A A, Ghosh S, Bao W, et al. Nano Letters,2008,8(3),902.
7 Kasar A K, Xiong G P, Menezes P L. JOM,2018,70(6),829.
8 Herzog D, Seyda V, Wycisk E, et al. Acta Materialia,2016,117(15),371.
9 Zhou B, Zhou J, Li H, et al. Materials Science & Engineering A,2018,724(2),1.
10 Ngo T D, Kashani A, Imbalzano G, et al. Composites Part B: Enginee-ring,2018,143,172.
11 Culmone C, Smit G, Breedveld P. Additive Manufacturing,2019,27,461.
12 Chen Z, Li Z, Li J, et al. Journal of the European Ceramic Society,2019,39(4),661.
13 Zhao Z Y, Li L, Tan L, et al. Materials,2018,11(9),1525.
14 Sherrell P C, Mattevi C. Materials Today,2016,19(8),428.
15 Bhadauria A, Singh L K, Laha T. Journal of Alloys and Compounds,2018,748,783.
16 Jia Y, He H, Geng Y, et al. Composites Science & Technology,2017,145,55.
17 Eckel Z C, Chaoyin Z, Martin J H, et al. Science,2016,351(6268),58.
18 Mu X N, Cai H N, Zhang H M, et al. Materials & Design,2018,140,431.
19 Zhang D, Zhan Z. Journal of Alloys and Compounds,2016,658,663.
20 Hu Z, Chen F, Xu J, et al. Composites Part B: Engineering,2018,134,133.
21 Milton S, Duchosal A, Chalon F, et al. Journal of Manufacturing Processes,2019,38,256.
22 Greer C, Nyca A, Noakes M, et al. Additive Manufacturing,2019,27,159.
23 Lewandowski J J, Seifi M. Annual Review of Materials Research,2016,46(1),151.
24 Hu Z, Chen F, Xu J, et al. Journal of Alloys and Compounds,2018,746,269.
25 Tan L. Preparation of aluminized graphene/aluminum matric composite powder and the selective laser melting. Master’s Thesis, North University of China, China,2018(in Chinese).
谭乐.镀铝石墨烯/铝基复合粉末制备及其选择性激光熔化成形.硕士学位论文,中北大学,2018.
26 Zhou W, Dong M, Zhou Z, et al. Carbon,2019,141,67.
27 Marchese G, Colera X G, Calignano F, et al. Advanced Engineering Materials,2017,19(3),1600635.
28 Deng P, Yao C, Feng K, et al. Surface & Coatings Technology,2017,335,334.
29 Hu Z, Tong G, Lin D, et al. Journal of Materials Processing Technology,2016,231,143.
30 Xiao W H, Lu S Q, Wang Y C, et al. Transactions of Nonferrous Metals Society of China,2018,28(10),1958.
31 Hu Z, Saei M, Tong G, et al. Journal of Alloys and Compounds,2016,688,438.
32 Wang Y, Shi J, Lu S, et al. Journal of Manufacturing Science and Engineering,2017,139(4),1005.
33 Lin D, Richard Liu C, Cheng G J. Acta Materialia,2014,80,183.
34 Lin D, Motlag M, Saei M, et al. Acta Materialia,2018,150,360.
35 Li M, Wu X, Yang Y, et al. Materials Characterization,2018,143,197.
36 Wang X, Jiang M, Zhou Z, et al. Composites Part B: Engineering,2017,110,442.
37 Wang J, Jin X, Li C, et al. Chemical Engineering Journal,2019,370,831.
38 Lin D, Jin S, Zhang F, et al. Nanotechnology,2015,26(43),434003.
39 Bing X, Zou Y. Composites Science & Technology,2018,157,78.
40 Compton B G, Hmeidat N S, Pack R C, et al. JOM,2017,70(3),292.
41 Chiappone A, Roppolo I, Naretto E, et al. Composites Part B: Enginee-ring,2017,124,9.
42 Kholkhoev B C, Buinov A S, Kozlova M N, et al. Russian Journal of Applied Chemistry,2018,91(3),392.
43 Zhu D, Ren Y, Liao G, et al. Journal of Applied Polymer Science,2017,134(39),45332.
44 Singh R, Sandhu G S, Penna R, et al. Materials,2017,10(8),881.
45 Wei X, Li D, Jiang W, et al. Scientific Reports,2015,5,11181.
46 Manapat J Z, Mangadlao J D, Tiu B D, et al. ACS Applied Materials & Interfaces,2017,9(11),10085.
47 Fu K, Wang Y, Yan C, et al. Advanced Materials,2016,28(13),2587.
48 Kai S, Mei H, Li B, et al. Advanced Energy Materials,2018,8(4),1527.
49 Garcia R V, Garcia-tunon E, Botas C, et al. ACS Applied Materials & Interfaces,2017,9(42),37136.
50 Xiao Y, Yang J, Qian F, et al. International Journal of Lightweight Materials & Manufacture,2018,1(2),96.
51 Di Z, Chi B, Li B, et al. Synthetic Metals,2016,217,79.
52 Foster C W, Down M P, Zhang Y, et al. Scientific Reports,2017,7,42233.
53 Kai H, Yang J, Dong S, et al. Carbon,2018,130,1.
54 Vernardou D, Vasilopoulos K C, Kenanakis G. Applied Physics A,2017,123(10),623.
55 Aahari A, Marzbanrad E, Yilman D, et al. Carbon,2017,119,257.
56 Cheng Z, Landish B, Chi Z, et al. Materials Science and Engineering: C,2018,82,244.
57 Wang W, Caetano G, Ambler W S, et al. Materials,2016,9(12),992.
58 Misra S K, Ostadhossein F, Babu R, et al. Advanced Healthcare Mate-rials,2017,6(11),1700008.
59 Chen Q, Mangadlao J D, Wallat J, et al. ACS Applied Materials & Interfaces,2017,9(4),4015.
60 Shuai C, Feng P, Gao C, et al. RSC Advances,2015,5,25416.
61 Sayyar S, Gambhir S, Chung J, et al. Nanoscale,2017,9(5),2038.
62 Sayyar S, Bjorninen M, Haimi S, et al. ACS Applied Materials & Interfaces,2016,8(46),31916.
63 Qian Y, Zhao X, Han Q, et al. Nature Communications,2018,9(1),323.
64 Bustillos J, Montero D, Nautiyal P, et al. Polymer Composites,2017,39(11),3877.
65 Hwa L C, Rajoo S, Noor A M, et al. Current Opinion in Solid State and Materials Science,2017,21(6),323.
66 Kunchala P, Kappagantula K. Materials & Design,2018,155,443.
67 Tubio C R, Rama A, Gómez M, et al. Ceramics International,2017,44(5),5760.
68 Yang J S, Huang K, You X, et al. Materials China,2018,37(8),32(in Chinese).
杨金山,黄凯,游潇,等.中国材料进展,2018,37(8),32.
69 Román-Manso B, Moyano J J, Pérez-coll D, et al. Journal of the Euro-pean Ceramic Society,2017,38(5),2265.
70 Zhong J, Zhou G X, He P G, et al. Carbon,2017,117,421.
71 Azhari A, Toyserkani E, Villain C. International Journal of Applied Ceramic Technology,2015,12(1),8.
72 Zhang Y, Zhai D, Xu M, et al. Journal of Materials Chemistry B,2016,4(17),2874.
73 Zhang Y, Zhai D, Xu M, et al. Biofabrication,2017,9(2),025037.
74 Shuai C, Liu T, Gao C, et al. Journal of Alloys and Compounds,2016,655(15),86. |
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2020, Vol. 34 
