Resistance of UV-perforated reduced graphene oxide on polystyrene surface

UV-perforated reduced graphene oxide flakes of large areas, some of them up to 500 µm in diameter, have been produced on polystyrene surface. These flakes were formed during precipitation of UV-reduced graphene oxide composites based on polystyrene from benzene solutions by petroleum ether. Two composites based on polystyrene with molecular weights of 9,000 Da and 45,000 Da were synthesized to compare their conductive properties. Conditions of the formation of planar structures from UV-perforated reduced graphene oxide flakes were varied. So, resistances were compared for composites deposited from solutions with different concentrations and at different temperatures. Very low resistances for some flakes precipitated from 5 wt.% solution of composite of 9,000 Da molecular mass at the room temperature were obtained. The absolute values of measured resistances were found to be 1.5 orders of magnitude lower than resistance of copper. At the same time some, regions of graphene inclusions from 12 wt.% solution of latter polystyrene composite demonstrated even lower resistance, almost 3 orders of magnitude lower than copper resistance. This result is explained by existence of superconducting component in the reduced graphene oxide inclusions. In the case of composites with graphene flakes produced from higher molecular weight polystyrene (45,000 Da) resistance was high and varied from semiconducting values to non-conductive state.

1. Novoselov K.S., Fal’ko V.I., Colombo L., Gellert P.R., Schwab M.G., Kim K.A. Roadmap for Graphene Nature. Nature, 2012, 490, P. 192–200.

2. Huang X., Yin Z., et al. Graphene-based materials: Synthesis, Characterizations, Properties, and Applications. Small, 2011, 7(14), P. 1876–1902.

3. Potts J.R., Dreyer D.R., Bielawski C.W., Ruoff R.S. Graphene-Based Polymer Nanocomposites. Polymer, 2011, 52, P. 5–25. Resistance of UV-perforated reduced graphene oxide on polystyrene surface 797

4. Kostromin S., Saprykina N., Vlasova E. et al. Nanocomposite polyazomethine/reduced graphene oxide with enhanced conductivity. Journal of Polymer Research, 2017, 24(12), P. 211.

5. Uchoa B., Castro Neto A.H. Superconducting states of pure and doped graphene. Phys Rev Letters, 2007, 98 P. 146801-1–146801-4.

6. Chapman J., Su Y., Howard C.A., et al. Superconductivity in Ca-doped graphene laminates. Sci. Rep., 2016, 6, P. 23254.

7. Tonnoir C., Kimouche A., Coraux J., et al. Induced superconductivity in graphene grown on Rhenium. Phys. Rev. Lett., 2013, 111(24), P. 246805.

8. Nikolaeva M.N., Bugrov A.N., Anan’eva T.D., et. al. Resistance of reduced graphene oxide on polystyrene surface. Nanosystems: physics, chemistry, mathematics, 2018, 9(4), P. 496–499.

9. Dideykin A., Aleksenskiy A.E., Kirilenko D., et. al. Monolayer graphene from graphite oxide. Diam. Relat. Mat., 2011, 20(2), P. 105–108.

10. Rabchinskii M.K., Shnitov V.V., Dideikin A.T., et.al. Nanoscale Perforation of Graphene Oxide during Photoreduction Process in the Argon Atmosphere. J. Phys. Chem. C, 2016, 120(49), P. 28261–28269.

11. Aleksenskii A.E., Vul‘ S.P., Dideikin A.T., et.al. Etching of wrinkled graphene oxide films in noble gas atmosphere under UV irradiation. Nanosystems: physics, chemistry, mathematics, 2016, 8(1), P. 81–86.

12. Nikolaeva M.N., Bugrov A.N., Anan’eva T.D., et al. Conductive properties of the composite films of graphene oxide based on polystyrene in a metal-polymer-metal structure. Russ. J. Appl. Chem., 2014, 87(8), P. 1151–1155.

13. Nikolaeva M.N., Gushchina E.V., Dunaevskii M.S., et al. The influence of substrate material on the resistance of composite films based on reduced graphene oxide and polystyrene. Nanosystems: physics, chemistry, mathematics, 2017, 8(5), P. 665–669.

14. Khairullin A.R., Nikolaeva M.N., Bugrov A.N. Resistance of the composite films based on polystyrene and graphene oxide. Nanosystems: physics, chemistry, mathematics, 2016, 7(6), P. 1055–1058.

15. Nikolaeva M.N., Anan’eva T.D., Bugrov A.N., et.al. Correlation between structure and resistance of composites based on polystyrene and multilayered graphene oxide. Nanosystems: physics, chemistry, mathematics, 2017, 8(2), P. 266–271.

16. Yevlampieva N., Bugrov A., Anan’eva T., et al. Soluble poly (methyl methacrylate) composites containing covalently associated zirconium dioxide nanocrystals. Am. J. Nano Res. and Appl., 2014, 2(2), P. 1–8.

17. Esquinazi P., Heikkila T.T., Lysogorskiy Y.V., et.al. On the superconductivity of graphite interfaces.¨ JETP Letters, 2014, 100(5), P. 336–339.

18. Scheike T., Bhlmann W., Esquinazi P., et. al. Can doping graphite trigger room temperature superconductivity? Evidence for granular high-temperature superconductivity in water-treated graphite powder. Advanced Materials, 2012, 24(43), P. 5826–5831.

19. Volovik G.E., Pudalov V.M. Graphite on graphite. JETP Letters, 2016, 104(12), P. 880–882.

20. Saad M., Gilmutdinov I.F., Kiiamov A.G., et al. Observation of Persistent Currents in Finely Dispersed Pyrolytic Graphite. JETP Letters, 2018, 107(1), P. 37–41.

21. Ionov A.N. Josephson-Like Behaviour of the Current-Voltage Characteristics of Multi-graphene Flakes Embedded in Polystyrene. J. Low Temp. Phys., 2016, 185(5-6), P. 515–521.