Nanotechnology 2011,22(24):245603 CrossRef 16 Kim Y-J, Yoo H, Le

Nanotechnology 2011,22(24):245603.CrossRef 16. Kim Y-J, Yoo H, Lee C-H, Park JB, Baek H, Kim M, Yi G-C: Position- and morphology-controlled ZnO nanostructures grown on graphene layers. Adv Mater 2012,24(41):5565–5569.CrossRef 17. Alver U, Zhou W, Belay AB, Krueger R, Davis KO, Hickman NS: Optical and structural properties of ZnO nanorods grown on graphene oxide and reduced graphene oxide film by hydrothermal method. Appl Surf Sci 2012,258(7):3109–3114.CrossRef 18. Lee JM, Pyun YB, Yi J, Choung JW, Park WI: ZnO nanorod–graphene hybrid architectures for multifunctional conductors. J Phys Chem C 2009,113(44):19134–19138.CrossRef 19. Sugunan A, Warad HC, Boman M, Dutta J: Zinc oxide nanowires

in chemical bath on seeded substrates: role of hexamine. J Sol–gel Sci Techn 2006,39(1):49–56.CrossRef GSK2245840 datasheet 20. Rodzi AS, Berhan MN, Rusop M: Synthesis and characterization of zinc oxide nanostructured by electrochemical deposition method. Adv Mat Res 2012, 576:573–576.CrossRef 21. Yi J, Lee JM, Park WI: Vertically aligned ZnO

nanorods and graphene hybrid architectures for high-sensitive flexible gas sensors. Sensor Actuat B-Chem 2011,155(1):264–269.CrossRef 22. Liu J-y Y, X-x ZG-h, Y-k W, Zhang K, Pan N, Wang X-p: High performance ultraviolet photodetector fabricated with ZnO nanoparticles-graphene hybrid structures. Chin J Chem Phys 2013,26(2):225–230.CrossRef 23. Yang K, Xu C, Huang L, Zou L, Wang H: Hybrid nanostructure heterojunction solar Methane monooxygenase cells fabricated using vertically aligned ZnO nanotubes grown https://www.selleckchem.com/products/Cediranib.html on reduced graphene oxide. Nanotechnology 2011,22(40):405401.CrossRef 24. Lee JM, Yi J, Lee WW, Jeong HY, Jung T, Kim Y, Park WI: ZnO nanorods-graphene hybrid structures for enhanced current spreading and light extraction in GaN-based light emitting diodes. Appl Phys Lett 2012,100(6):061107.CrossRef 25. Yang NH, Huang Y-C, Chang S-Y: Oriented growth of ZnO nanorod arrays

on ultraviolet-activated low-temperature cured seed layers. Meeting Abstracts 2009,MA2009–01(31):1158. 26. Ahmad NF, Rusli NI, Mahmood MR, Yasui K, Hashim AM: Seed/catalyst-free growth of zinc oxide nanostructures on multilayer graphene by thermal evaporation. Nanoscale Res Lett 2014,9(1):83.CrossRef 27. Liu L, Ryu S, Tomasik MR, Stolyarova E, Jung N, Hybertsen MS, Steigerwald ML, Brus LE, Flynn GW: Graphene oxidation: thickness-dependent EPZ015666 mouse etching and strong chemical doping. Nano Lett 2008,8(7):1965–1970.CrossRef 28. Xu C, Kim B-S, Lee J-H, Kim M, Hwang SW, Choi BL, Lee EK, Kim JM, Whang D: Seed-free electrochemical growth of ZnO nanotube arrays on single-layer graphene. Mater Lett 2012, 72:25–28.CrossRef 29. Xu C, Lee J-H, Lee J-C, Kim B-S, Hwang SW, Whang D: Electrochemical growth of vertically aligned ZnO nanorod arrays on oxidized bi-layer graphene electrode. Cryst Eng Comm 2011,13(20):6036–6039.CrossRef 30.

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