石墨烯增强空心微点阵材料的制备与表征

doi:10.1007/s12204-021-2339-8

J Shanghai Jiaotong Univ Sci ›› 2023, Vol. 28 ›› Issue (2): 192-196.doi: 10.1007/s12204-021-2339-8

石墨烯增强空心微点阵材料的制备与表征

鲍海生，刘龙权

（上海交通大学航空航天学院飞机结构强度试验平台，上海200240)

收稿日期:2020-06-17 接受日期:2020-08-07 出版日期:2023-03-28 发布日期:2023-03-21

Fabrication and Characterization of Graphene-Enhanced Hollow Microlattice Materials

BAO Haisheng (鲍海生), LIU Longquan∗ (刘龙权)

(Laboratory of Aircraft Structure and Strength, School of Aeronautics and Astronautics, Shanghai Jiao Tong University, Shanghai 200240, China)

Received:2020-06-17 Accepted:2020-08-07 Online:2023-03-28 Published:2023-03-21

摘要/Abstract

摘要： 提出一套石墨烯增强空心微点阵材料的制备方法和工艺技术，主要包括3D打印、纳米复合镀和聚合物蚀刻等先进制造技术。系统地表征和分析了石墨烯增强金属镀层的微观组织形貌和均匀性，并开展了准静态压缩试验，研究了石墨烯增强空心微点阵材料的力学性能。试验结果表明，归功于纳米材料物理和化学分散工艺的综合应用，成功获得了均匀的镍-磷-石墨烯（Ni-P-G）镀层，从而提高了空心微点阵材料的比模量和比强度。在此基础上，对比分析了石墨烯含量对空心微点阵材料力学性能的影响规律，得到了较优的石墨烯含量，并结合细观力学分析模型，揭示了石墨烯对空心微点阵材料弹性模量和强度的影响机理。

关键词: 空心微点阵, 石墨烯, 多孔材料, 化学镀, 力学性能

Abstract: A method was developed and proposed to fabricate graphene-enhanced hollow microlattice materials, which include the three-dimensional (3D) printing, nanocomposite electroless plating, and polymer etching technologies. The surface morphology and uniformity of as-deposited coatings were systematically characterized and analyzed. Moreover, the mechanical properties of the microlattices were investigated through quasi-static compression tests. The results demonstrated that a uniform Nickel-phossphorous-graphene (Ni-P-G) coating was obtained successfully, and the specific modulus and strength were increased by adding graphene into the microlattice materials. The optimal mass concentration of graphene nanoplatelets was obtained after comparing the specific modulus and strength of the materials with different densities of graphene, and the strength mechanism was discussed.

中图分类号:

TG 146.1

鲍海生, 刘龙权. 石墨烯增强空心微点阵材料的制备与表征[J]. J Shanghai Jiaotong Univ Sci, 2023, 28(2): 192-196.

BAO Haisheng (鲍海生), LIU Longquan∗ (刘龙权). Fabrication and Characterization of Graphene-Enhanced Hollow Microlattice Materials[J]. J Shanghai Jiaotong Univ Sci, 2023, 28(2): 192-196.

参考文献 16

[1]	BAUER J, MEZA L R, SCHAEDLER T A, et al. Nanolattices: an emerging class of mechanical metamaterials [J]. Advanced Materials, 2017, 29(40): 1701850.
[2]	FAN Q, GAO Y, ZHAO Y, et al. Fabrication of diamond-structured composite materials with Ni-P-diamond particles by electroless plating [J]. Materials Letters, 2018, 215: 242-245.
[3]	MEZA L R, GREER J R. Mechanical characterization of hollow ceramic nanolattices [J]. Journal of Materials Science, 2014, 49(6): 2496-2508.
[4]	MONTEMAYOR L C, GREER J R. Mechanical response of hollow metallic nanolattices: Combining structural and material size effects [J]. Journal of Applied Mechanics, 2015, 82(7): 071012.
[5]	ZHENG X, LEE H, WEISGRABER T H, et al. Ultralight, ultrastiff mechanical metamaterials [J]. Science, 2014, 344(6190): 1373-1377.
[6]	SHI J H, LIU L Q. Creating hollow microlattice materials reinforced by carbon nanotubes for improved mechanical properties [J]. Materials Letters, 2019, 240: 205-208.
[7]	SONG J, WANG Y, ZHOU W, et al. Topology optimization-guided lattice composites and their mechanical characterizations [J]. Composites Part B: Engineering, 2019, 160: 402-411.
[8]	WU H, LIU F, GONG W, et al. Preparation of Ni–P–GO composite coatings and its mechanical properties [J]. Surface and Coatings Technology, 2015, 272: 25-32.
[9]	RANA A R K, FARHAT Z. Preparation and tribological characterization of graphene incorporated electroless Ni-P composite coatings [J]. Surface and Coatings Technology, 2019, 369: 334-346.
[10]	KURAPOVA O Y, LOMAKIN I V, SERGEEV S N, et al. Fabrication of nickel-graphene composites with superior hardness [J]. Journal of Alloys and Compounds, 2020, 835: 155463.
[11]	PAPAGEORGIOU D G, KINLOCH I A, YOUNG R J. Mechanical properties of graphene and graphene-based nanocomposites [J]. Progress in Materials Science, 2017, 90: 75-127.
[12]	BHADAURIA A, SINGH L K, LAHA T. Effect of physio-chemically functionalized graphene nanoplatelet reinforcement on tensile properties of aluminum nanocomposite synthesized via spark plasma sintering [J]. Journal of Alloys and Compounds, 2018, 748: 783-793.
[13]	BHADAURIA A, SINGH L K, LAHA T. Combined strengthening effect of nanocrystalline matrix and graphene nanoplatelet reinforcement on the mechanical properties of spark plasma sintered aluminum based nanocomposites [J]. Materials Science and Engineering: A, 2019, 749: 14-26.
[14]	JEONG G, PARK J, NAM S, et al. The effect of grain size on the mechanical properties of aluminum [J]. Archives of Metallurgy and Materials, 2015, 60(2): 1287-1291.
[15]	RASHAD M, PAN F, TANG A, et al. Effect of Graphene Nanoplatelets addition on mechanical properties of pure aluminum using a semi-powder method [J]. Progress in Natural Science: Materials International, 2014, 24(2): 101-108.
[16]	ZHANG Z, CHEN D L. Consideration of Orowan strengthening effect in particulate-reinforced metal matrix nanocomposites: A model for predicting their yield strength [J]. Scripta Materialia, 2006, 54(7): 1321-1326.

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石墨烯增强空心微点阵材料的制备与表征

Fabrication and Characterization of Graphene-Enhanced Hollow Microlattice Materials

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