Synthesis of the liquid-like graphene with excellent tribological properties

Tribology International

Volumn 105, Issue , 2017, Pages 118-124

  Yang, Jin ^a   Xia, Yunfei ^a   Song, Haojie ^a   Chen, Beibei ^a   Zhang, Zhaozhu ^b  

^a JIANGSU UNIVERSITY   (China)

^b LANZHOU INSTITUTE OF CHEMICAL PHYSICS   (China)

Author keywords

Graphene; Liquid like; Tribological; Well dispersion

Indexed keywords

BLOCK COPOLYMERS; DISPERSIONS; FRICTION; INTERFACES (MATERIALS); LIQUIDS; PHASE INTERFACES; TRIBOLOGY;

ELECTROSTATIC ADSORPTION; EXCELLENT SOLUBILITY; FRICTION COEFFICIENTS; LUBRICANT ADDITIVES; MOLECULAR REARRANGEMENT; SURFACE SULFONATION; TRIBOLOGICAL; TRIBOLOGICAL PROPERTIES;

GRAPHENE;

EID: 84991735025     PISSN: 0301679X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.triboint.2016.09.040     Document Type: Article

References (27)

1. [1] Berman, D., Erdemir, A., Sumant, A.V., Graphene: a new emerging lubricant. Mater Today 17 (2014), 31–42.
2. 2 nanosheets as additives used in hydraulic applications. Tribol Int 97 (2016), 14–20.
3. [3] Liang, S., Shen, Z., Yi, M., Liu, L., Zhang, X., Ma, S., In-situ exfoliated graphene for high-performance water-based lubricants. Carbon 96 (2016), 1181–1190.
4. [4] Kim, H.-J., Kim, D.-E., Water lubrication of stainless steel using reduced graphene oxide coating. Sci Rep, 5, 2015, 17034.
5. [5] Kim K-S, Lee H-J, Lee C, Lee S-K, Jang H, Ahn J-H, Kim J-H, Lee H-J. Chemical vapor deposition-grown graphene: the thinnest solid lubricant. ACS Nano 2011;5: 5107–114.
6. [6] Shin, Y., Stromberg, R., Nay, R., Huang, H., Wee, A.T.S., Yang, H., et al. Frictional characteristics of exfoliated and epitaxial graphene. Carbon 49 (2011), 4070–4073.
7. [7] Eswaraiah, V., Sankaranarayanan, V., Ramaprabhu, S., Graphene-based engine oil nanofluids for tribological applications. ACS Appl Mater Interfaces 3 (2011), 4221–4227.
8. [8] Lin, J., Wang, L., Chen, G., Modification of graphene platelets and their tribological properties as a lubricant additive. Tribol Lett 41 (2011), 209–215.
9. [9] Choudhary, S., Mungse, H.P., Khatri, O.P., Dispersion of alkylated graphene in organic solvents and its potential for lubrication applications. J Mater Chem 22 (2012), 21032–21039.
10. [10] Song, H.J., Li, N., Frictional behavior of oxide graphene nanosheets as water-base lubricant additive. Appl Phys A 105 (2011), 827–832.
11. [11] Fernandes NJ, Wallin TJ, Vaia RA, Koerner H, Giannelis EP. Nanoscale ionic materials. 2013; 26:4353–358.
12. [12] Kim, D., Archer, L.A., Nanoscale organic-inorganic hybrid lubricants. Langmuir 27 (2011), 3083–3094.
13. 2) nanofluids with self-healing lubricating behaviors. Mater Lett 97 (2013), 169–172.
14. [14] Li Q, Dong LJ, Fang JF, Xiong CX. Property-structure relationship of nanoscale ionic materials based on multiwalled carbon nanotubes. ACS Nano 2010;4: 5797–806.
15. [15] Tang, Z.H., Zhang, L.Q., Zeng, C.F., LinTF, Guo, B.C., General route to graphene with liquid-like behavior by non-covalent modification. Soft Matter 8 (2012), 9214–9220.
16. [16] Wu, L.S., Zhang, B.Q., Lu, H., Liu, C.-Y., Nanoscale ionic materials based on hydroxyl-functionalized graphene. J Mater Chem A 2 (2014), 1409–1417.
17. [17] Agarwal, P., Qi, H., Archer, L.A., The ages in a self-suspended nanoparticle liquid. Nano Lett 10 (2010), 111–115.
18. [18] Zeng, C.F., Tang, Z.H., Guo, B.C., Zhang, L.Q., Supramolecular ionic liquid based on graphene oxide. Phys Chem Chem Phys 14 (2012), 9838–9845.
19. [19] Li, Q., Dong, L.J., Sun, F., Huang, J., Xie, H., Xiong, C.X., Self-unfolded graphene sheets. Chem Eur J 18 (2012), 7055–7059.
20. [20] Zhou, F., Liang, Y.M., Liu, W.M., Ionic liquid lubricants: designed chemistry for engineering applications. Chem Soc Rev 38 (2009), 2590–2599.
21. [21] Cai, M.R., LiangYM, Zhou, F., Liu, W.M., A novel imidazolium salt with antioxidation and anticorrosion dual functionalities as the additive in poly(ethyleneglycol) for steel/steel contacts. Wear 306 (2013), 197–208.
22. [22] Gusain, R., Mungse, H.P., Kumar, N., Ravindran, T.R., Pandian, R., Sugimura, H., et al. Covalently attached graphene-ionic liquids hybrid nanomaterials: synthesis, characterization and tribological application. J Mater Chem A 4 (2015), 926–937.
23. [23] Mahrova, M., Pagano, F., Pejakovic, V., Valea, A., Kalin, M., Igartua, A., et al. Pyridinium based dicationic ionic liquids as base lubricants or lubricant additives. Tribol Int 82 (2015), 245–254.
24. [24] Dai, W., Kheireddin, B., Gao, H., Liang, H., Roles of nanoparticles in oil lubrication. Tribol Int 102 (2016), 88–98.
25. [25] Qu, M., Yao, Y., He, J., Ma, X., Liu, S., Feng, J., et al. Tribological performance of functionalized ionic liquid and Cu microparticles as lubricating additives in sunflower seed oil. Tribol Int 104 (2016), 166–174.
26. [26] Xiong, L., He, Z., Han, S., Tang, J., Wu, Y., Zeng, X., Tribological properties study of N-containing heterocyclic imidazoline derivatives as lubricant additives in water-glycol. Tribol Int 104 (2016), 98–108.
27. [27] Huang GW, Yu QL, Ma ZF, Cai MR, Liu WM. Probing the lubricating mechanism of oil-soluble ionic liquids additives. Tribol Int. 〈 http://dx.doi.org/10.1016/j.triboint.2016.08.027〉.