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Materials Protection >

2023 , Vol. 56 >Issue 1: 88 - 93

DOI: https://doi.org/10.16577/j.issn.1001-1560.2023.0014

Study on Self-Healing Growth and Friction Properties of Graphene on Nickel-Based Surface

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  • 1. Xing’an Power Supply Company, State Grid Inner Mongolia Eastern Power Co., Ltd., Ulanhot 137400, China;2. State Grid Inner Mongolia Eastern Power Co., Ltd., Hohhot 010000, China;3. School of Materials Science and Engineering, Shaanxi University of Science and Technology, Xi’an 710021, China

Received date: 2022-07-13

  Revised date: 2022-08-16

  Accepted date: 2022-09-07

  Online published: 2023-07-25

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Abstract

To solve the problem of insufficient durability of graphene film with nano-scale thickness in substrate protection, the self-healing process referring to the re-growth of graphene film after damage on a nickel-based surface was studied by heat treatment method. The characterization of microstructure and morphology showed that the graphene could grow again and repair the damaged surface under the conditions of a heat treatment temperature of 700 ℃and a holding time of 5 min. The results of friction test showed that the friction coefficient of the regrown graphene film was 0.05, which was 50%lower than that of the original nickel surface. Meantime, the mechanism of graphene regrowth was explored, and the driving force of graphene regrowth was described clearly. Generally, this research achievements provided experimental basis and theoretical explanation for graphene self-healing field.

Key words: graphene; self-healing growth; friction performance; nickel substrate

Cite this article

LV Tong-fa, CAO Yang, HE Yong-chun, LV Chao, LU Ji-chao, YU Shi-qi, WU Tao, MU Xin, QIANG Hao, YE Xiao-hui . Study on Self-Healing Growth and Friction Properties of Graphene on Nickel-Based Surface[J]. Materials Protection, 2023 , 56(1) : 88 -93 . DOI: 10.16577/j.issn.1001-1560.2023.0014

References

[ 1] HOLMBERG K, ANDERSSON P, ERDEMIR A. Global energy consumption due to friction in passenger cars[J]. Tribology International, 2012, 47: 221-234.

[ 2] 吴 浩, 夏延秋, 吴礼宁, 等. 磁控溅射碳/铜复合涂层在脂润滑下的载流摩擦学性能研究[J]. 材料保护,2021, 54(11): 10-14.WU H, XIA Y Q, WU L N, et al. Study on Current-Carrying Tribological Properties of Magnetron Sputtered Carbon/Copper Composite Coatings under Grease Lubrication[J].Materials Protection, 2021, 54(11): 10-14.

[ 3] HOLMBERG K, ERDEMIR A. The impact of tribology on energy use and CO2 emission globally and in combustion engine and electric cars[J]. Tribology International, 2019,135: 389-396.

[ 4] 段昭宇, 李长生, 开绍森, 等. 镀镍石墨/NiCrW 合金复合材料的微观组织和摩擦学性能[J]. 材料保护, 2021,54(4): 1-6.DUAN Z Y, LI C S, KAI S S, et al. Microstructures and Wear Behavior of Nickel - Coated Graphite/NiCrW Alloy Composite[J]. Materials Protection, 2021, 54(4): 1-6.

[ 5] 郑泉水, 欧阳稳根, 马 明, 等. 超润滑:“零”摩擦的世界[J]. 科技导报, 2016, 34(9): 12-26.ZHENG Q S,OUYANG W G, MA M, et al. Super lubrication:A world of "zero" friction[J]. Science and Technology Review, 2016, 34(9): 12-26.

[ 6] QU C, SHI S, MA M, et al. Rotational instability in superlubric joints[J]. Physical Review Letters,2019,122(24):246 101.

[ 7] HOD O, MEYER E, ZHENG Q, et al. Structural superlubricity and ultralow friction across the length scales[J]. Nature, 2018, 563(7 732): 485-492.

[ 8] PTAK F, ALMEIDA C M, PRIOLI R. Velocity-dependent friction enhances tribomechanical differences between monolayer and multilayer graphene[J]. Scientific Reports,2019,9(1): 1-9.

[ 9] WU P, LI X, ZHANG C, et al. Self-assembled graphene film as low friction solid lubricant in macroscale contact[J].ACS Applied Materials & Interfaces, 2017, 9 (25):21 554-21 562.

[10] BAO T, WANG Z, ZHAO Y, et al. Long-term stably dispersed functionalized graphene oxide as an oil additive[J].RSC Advances, 2019, 9(67): 39 230-39 241.

[11] DAI B, FU L, ZOU Z, et al. Rational design of a binary metal alloy for chemical vapour deposition growth of uniform single-layer graphene[J]. Nature Communications,2011,2(1): 1-6.

[12] LI X, CAI W, COLOMBO L, et al. Evolution of graphene growth on Ni and Cu by carbon isotope labeling[J]. Nano Letters, 2009, 9(12): 4 268-4 272.

[13] CHEN Y P, YU Q. Graphene rolls off the press[J]. Nature Nanotechnology, 2010, 5(8): 559-560.

[14] BAE S, KIM H, LEE Y, et al. Roll-to-roll production of 30-inch graphene films for transparent electrodes[J]. Nature Nanotechnology, 2010, 5(8): 574-578.

[15] BUBNOVA O. A decade of R2R graphene manufacturing[J]. Nature Nanotechnology, 2021, 16(10): 1 050.

[16] 张朝华,付 磊,张艳锋,等. 石墨烯催化生长中的偏析现象及其调控方法[J]. 化学学报, 2013,71(3):308-322.ZHANG Z H, FU L, ZHANG Y F, et al. Segregation Phenomenon and Its Control in the Catalytic Growth of Graphene[J]. Acta Chimica Sinica, 2013,71(3):308-322.

[17] 魏博远. 高熵合金基底CVD 石墨烯生长规律及微观机理研究[D]. 哈尔滨: 哈尔滨工业大学, 2020.WEI B Y. Research on the microscopic mechanism of graphene growth by high entropy alloy based CVD[D]. Harbin: Harbin Institute of Technology, 2018.

[18] YE X, LONG J, LIN Z, et al. Direct laser fabrication of large-area and patterned graphene at room temperature[J].Carbon, 2014, 68: 784-790.

[19] YE X, LIN Z, ZHANG H, et al. Protecting carbon steel from corrosion by laser in situ grown graphene films[J].Carbon, 2015, 94: 326-334.

[20] YE X H, YU F, CURIONI M, et al. Corrosion resistance of graphene directly and locally grown on bulk nickel substrate by laser irradiation[J]. Rsc Advances, 2015, 5(45):35 384-35 390.

[21] CHAE S J, Güneş F, KIM K K, et al. Synthesis of largearea graphene layers on polynickel substrate by chemical vapor deposition: wrinkle formation[J]. Advanced Materials,2009, 21(22): 2 328-2 333.

[22] 叶晓慧. 激光快速原位制备石墨烯及其耐腐蚀性研究[D]. 北京: 清华大学, 2015.YE X H, Rapid Laser In-situ Growth of Grapheneand Its Anti-corrosion Performance[D]. Beijing: Tsinghua University, 2015.

[23] 王矜奉. 固体物理教程[M]. 济南: 山东大学出版社,2013: 140-148.WANG J F.Solid State Physics Course[M]. Jinan: Shandong University Press, 2013: 140-148.
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