Functionalization of carbon nanomaterials for advanced polymer nanocomposites: A comparison study between CNT and graphene

Progress in Polymer Science

Volumn 67, Issue , 2017, Pages 1-47

  Punetha, Vinay Deep ^a   Rana, Sravendra ^b,f   Yoo, Hye Jin ^c   Chaurasia, Alok ^d   McLeskey, James T ^e   Ramasamy, Madeshwaran Sekkarapatti ^c   Sahoo, Nanda Gopal ^a   Cho, Jae Whan ^c  

^a KUMAUN UNIVERSITY   (India)

^b MARTIN LUTHER UNIVERSITY HALLE WITTENBERG   (Germany)

^c Konkuk University   (South Korea)

^d NANYANG TECHNOLOGICAL UNIVERSITY   (Singapore)

^e RANDOLPH MACON COLLEGE   (United States)

^f UNIVERSITY OF PETROLEUM AND ENERGY STUDIES   (India)

Author keywords

[No Author keywords available]

Indexed keywords

ASPECT RATIO; BLOCK COPOLYMERS; DENDRIMERS; DISPERSIONS; FUEL CELLS; GRAPHENE; HYBRID MATERIALS; NANOCOMPOSITES; NANOSTRUCTURED MATERIALS; NANOTUBES; POLYMERIZATION; YARN;

BIOLOGICAL FUNCTIONS; CARBON NANO-MATERIALS; COMPOSITE PROPERTIES; FUNCTIONALIZATION OF CNTS; FUNCTIONALIZATIONS; NON-COVALENT FUNCTIONALIZATION; POLYMER NANOCOMPOSITE; THERMAL BEHAVIORS;

CARBON NANOTUBES;

EID: 85008315482     PISSN: 00796700     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.progpolymsci.2016.12.010     Document Type: Review

References (451)

1. [1] Sahoo, N.G., Rana, S., Cho, J.W., Li, L., Chan, S.H., Polymer nanocomposites based on functionalized carbon nanotubes. Prog Polym Sci 35 (2010), 837–867.
2. [2] Xie, X.L., Mai, Y.W., Zhou, X.P., Dispersion and alignment of carbon nanotubes in polymer matrix: a review. Mater Sci Eng R Rep 49 (2005), 89–112.
3. [3] Spitalsky, Z., Tasis, D., Papagelis, K., Galiotis, C., Carbon nanotube-polymer composites: chemistry, processing, mechanical and electrical properties. Prog Polym Sci 35 (2010), 357–401.
4. [4] Liu, W.W., Chai, S.P., Mohamed, A.R., Hashim, U., Synthesis and characterization of graphene and carbon nanotubes: a review on the past and recent developments. J Ind Eng Chem 20 (2014), 1171–1185.
5. [5] Rahman, M., Ahmad, M.Z., Kazmi, I., Akhter, S., Afzal, M., Gupta, G., Jalees Ahmed F, Anwar F. Advancement in multifunctional nanoparticles for the effective treatment of cancer. Expert Opin Drug Deliv 9 (2012), 367–381.
6. [6] Lim, D.J., Sim, M., Oh, L., Lim, K., Park, H., Carbon-based drug delivery carriers for cancer therapy. Arch Pharm Res 37 (2014), 43–52.
7. [7] Miao, W., Shim, G., Kang, C.M., Lee, S., Choe, Y.S., Choi, H.G., et al. Cholesteryl hyaluronic acid-coated, reduced graphene oxide nanosheets for anti-cancer drug delivery. Biomaterials 34 (2013), 9638–9647.
8. [8] Sahoo, N.G., Bao, H., Pan, Y., Pal, M., Kakran, M., Cheng, H.k.f., et al. Functionalized carbon nanomaterials as nanocarriers for loading and delivery of a poorly water-soluble anticancer drug: a comparative study. Chem Commun 47 (2011), 5235–5237.
9. [9] Jang, H., Ryoo, S.R., Lee, M., Han, S., Min, D.H., A new helicase assay based on graphene oxide for anti-viral drug development. Mol Cells 35 (2013), 269–273.
10. [10] Wang, C., Mallela, J., Garapati, U.S., Ravi, S., Chinnasamy, V., Girard, Y., et al. A chitosan-modified graphene nanogel for noninvasive controlled drug release. Nanomedicine 9 (2013), 903–911.
11. [11] Farokhzad, O.C., Langer, R., Impact of nanotechnology on drug delivery. ACS Nano 3 (2009), 16–20.
12. [12] Yang, W., Thordarson, P., Gooding, J.J., Ringer, S.P., Braet, F., Carbon nanotubes for biological and biomedical applications. Nanotechnology, 18, 2007 412001/1-12.
13. [13] Yang, Y., Zhang, Y.M., Chen, Y., Zhao, D., Chen, J.T., Liu, Y., Construction of a graphene oxide based noncovalent multiple nanosupramolecular assembly as a scaffold for drug delivery. Chem Eur J 18 (2012), 4208–4215.
14. [14] Goenka, S., Sant, V., Sant, S., Graphene-based nanomaterials for drug delivery and tissue engineering. J Control Release 173 (2014), 75–88.
15. [15] Mao, H.Y., Laurent, S., Chen, W., Akhavan, O., Imani, M., Ashkarran, A.A., et al. Graphene: promises, facts, opportunities, and challenges in nanomedicine. Chem Rev 113 (2013), 3407–3424.
16. [16] Harrison, B.S., Atala, A., Carbon nanotube applications for tissue engineering. Biomaterials 28 (2007), 344–353.
17. [17] Cui, H.F., Vashist, S.K., Al-Rubeaan, K., Luong Jht Sheu, F.S., Interfacing carbon nanotubes with living mammalian cells and cytotoxicity issues. Chem Res Toxicol 23 (2010), 1131–1147.
18. [18] Rosca, I.D., Hoa, S.V., Method for reducing contact resistivity of carbon nanotube-containing epoxy adhesives for aerospace applications. Compos Sci Technol 71 (2011), 95–100.
19. [19] Li, J., Lumpp, J.K., Carbon nanotube filled conductive adhesives for aerospace applications. Aerospace Confer IEEE, 2007, 1–6.
20. [20] Saikia, N., Deka, R., Ab initio study on the noncovalent adsorption of camptothecin anticancer drug onto graphene, defect modified graphene and graphene oxide. J Comput Aided Mol Des 27 (2013), 807–821.
21. [21] Zhao, J., Yu, Y., Bai, Y., Lu, B., Wang, B., Chemical functionalization of BN graphene with the metal-arene group: a theoretical study. J Mater Chem 22 (2013), 9343–9350.
22. [22] Stankovich, S., Piner, R.D., Nguyen, S.T., Ruoff, R.S., Synthesis and exfoliation of isocyanate-treated graphene oxide nanoplatelets. Carbon 44 (2006), 3342–3347.
23. [23] Xu, Y., Liu, Z., Zhang, X., Wang, Y., Tian, J., Huang, Y., et al. A graphene hybrid material covalently functionalized with porphyrin: synthesis and optical limiting property. Adv Mater 21 (2009), 1275–1279.
24. [24] Wang, S., Optimum degree of functionalization for carbon nanotubes. Curr Appl Phys 9 (2009), 1146–1150.
25. [25] Peng, H., Alemany, L.B., Margrave, J.L., Khabashesku, V.N., Sidewall carboxylic acid functionalization of single-walled carbon nanotubes. J Am Chem Soc 125 (2003), 15174–15182.
26. [26] Tasis, D., Tagmatarchis, N., Bianco, A., Prato, M., Chemistry of carbon nanotubes. Chem Rev 106 (2006), 1105–1136.
27. [27] Karousis, N., Tagmatarchis, N., Tasis, D., Current progress on the chemical modification of carbon nanotubes. Chem Rev 110 (2010), 5366–5397.
28. [28] Lee, S.H., Daniel, R., An, J.D., Velamakanni, A., Piner, R.D., Park, S., et al. Polymer brushes via controlled, surface-initiated atom transfer radical polymerization (ATRP) from graphene oxide. Macromol Rapid Comm 31 (2010), 281–288.
29. [29] Gonçalves, G., Marques, P.a.a.p., Barros-Timmons, A., Bdkin, I., Singh, M.K., Emamic, N., et al. Graphene oxide modified with PMMA via ATRP as a reinforcement filler. J Mater Chem 20 (2010), 9927–9934.
30. [30] Ren, L., Huang, S., Zhang, C., Wang, R., Tjiu, W.W., Liu, T., Functionalization of graphene and grafting of temperature-responsive surfaces from graphene by ATRP “on water”. J Nanopart Res, 14, 2012 940/1-9.
31. [31] Vuluga, D., Thomassin, J.M., Molenberg, I., Huynen, I., Gilbert, B., Jerome, C., et al. Straightforward synthesis of conductive graphene/polymer nanocomposites from graphite oxide. Chem Commun 47 (2010), 2544–2546.
32. [32] Beckert, F., Rostas, A.M., Thomann, R., Weber, S., Schleicher, E., Friedrich, C., et al. Self-initiated free radical grafting of styrene homo- and copolymers onto functionalized graphene. Macromolecules 46 (2013), 5488–5496.
33. [33] Rajender, N., Suresh, K.I., Surface-initiated atom transfer radical polymerization (SI-ATRP) from graphene oxide: effect of functionalized graphene sheet (FGS) on the synthesis and material properties of PMMA nanocomposites. Macromol Mater Eng 301 (2016), 81–92.
34. [34] Papagelis, K., Kalyva, M., Tasis, D., Parthenios, J., Siokou, A., Galiotis, C., Covalently functionalized carbon nanotubes as macroinitiators for radical polymerization. Phys Status Solidi B 244 (2007), 4046–4050.
35. [35] Shen, J., Hu, Y., Li, C., Qin, C., Shi, M., Ye, M., Layer-by-layer self-assembly of graphene nanoplatelets. Langmuir 25 (2009), 6122–6128.
36. [36] Zhang, X., Han, M., Chen, S., Bao, L., Li, L., Xu, W., Azo addition to exfoliated graphene: a facile and high yield route to functionalized graphene. RSC Adv 3 (2013), 17689–17692.
37. [37] Gao, T., Wang, X., Yu, B., Wei, Q., Xia, Y., Zhou, F., Noncovalent microcontact printing for grafting patterned polymer brushes on graphene films. Langmuir 29 (2013), 1054–1060.
38. [38] Wang, B., Yang, D., Zhang, J.Z., Xi, C., Hu, J., Stimuli-responsive polymer covalent functionalization of graphene oxide by Ce(IV)-induced redox polymerization. J Phys Chem C 115 (2011), 24636–24641.
39. [39] Xu, L.Q., Yang, W.J., Neoh, K.G., Kang, E.T., Fu, G.D., Dopamine-induced reduction and functionalization of graphene oxide nanosheets. Macromolecules 43 (2010), 8336–8339.
40. [40] Shi, Y., Liu, M., Wang, K., Deng, F., Wan, Q., Huang, Q., et al. Bioinspired preparation of thermo-responsive graphene oxide nanocomposites in an aqueous solution. Polym Chem 6 (2015), 5876–5883.
41. [41] Beckert, F., Friedrich, C., Thomann, R., Mülhaupt, R., Sulfur-functionalized graphenes as macro-chain-transfer and RAFT agents for poducing graphene polymer brushes and polystyrene nanocomposites. Macromolecules 45 (2012), 7083–7090.
42. [42] Layek, R.K., Kuila, A., Chatterjee, D.P., Nandi, A.K., Amphiphilic poly(N-vinyl pyrrolidone) grafted graphene by reversible addition and fragmentation polymerization and the reinforcement of poly(vinyl acetate) films. J Mater Chem A 1 (2013), 10863–10874.
43. [43] You, Y.Z., Hong, C.Y., Pan, C.Y., Directly growing ionic polymers on multi-walled carbon nanotubes via surface RAFT polymerization. Nanotechnology, 17, 2006 2350/1-5.
44. [44] Hong, C.Y., You, Y.Z., Pan, C.Y., Functionalized multi-walled carbon nanotubes with poly(N-(2-hydroxypropyl)methacrylamide) by RAFT polymerization. J Polym Sci A Polym Chem 44 (2006), 2419–2427.
45. [45] Viswanathan, G., Chakrapani, N., Yang, H., Wei, B., Chung, H., Cho, K., et al. Single-step in situ synthesis of polymer-grafted single-wall nanotube composites. J Am Chem Soc 125 (2003), 9258–9259.
46. [46] Sakellariou, G., Ji, H., Mays, J.W., Baskaran, D., Enhanced polymer grafting from multiwalled carbon nanotubes through living anionic surface-initiated polymerization. Chem Mater 20 (2008), 6217–6230.
47. [47] Yoon, K.R., Kim, W.J., Choi, I.S., Functionalization of shortened single-walled carbon nanotubes with poly(p-dioxanone) by grafting-from approach. Macromol Chem Phys 205 (2004), 1218–1221.
48. [48] Kamber, N.E., Jeong, W., Waymouth, R.M., Pratt, R.C., Lohmeijer, B.g.g., Hedrick, J.L., Organocatalytic ring-opening polymerization. Chem Rev 107 (2007), 5813–5840.
49. [49] Xu, Z., Gao, C., In situ polymerization approach to graphene-reinforced nylon-6 composites. Macromolecules 43 (2010), 6716–6723.
50. [50] Sun, S., Wu, P., A one-step strategy for thermal- and pH-responsive graphene oxide interpenetrating polymer hydrogel networks. J Mater Chem 21 (2011), 4095–4097.
51. [51] Zhuang, X., Chen, Y., Wang, L., Neoh, K.G., Kang, E.T., Wang, C., A solution-processable polymer-grafted graphene oxide derivative for nonvolatile rewritable memory. Polym Chem 5 (2014), 2010–2017.
52. [52] Kerscher, B., Appel, A.K., Thomann, R., Mülhaupt, R., Treelike polymeric ionic liquids grafted onto graphene nanosheets. Macromolecules 46 (2013), 4395–4402.
53. [53] Xu, Y., Gao, C., Kong, H., Yan, D., Jin, Y.Z., Watts, P.C.P., Growing multihydroxyl hyperbranched polymers on the surfaces of carbon nanotubes by in situ ring-opening polymerization. Macromolecules 37 (2004), 8846–8853.
54. [54] Georgakilas, V., Tagmatarchis, N., Pantarotto, D., Bianco, A., Briand, J.P., Prato, M., Amino acid functionalisation of water soluble carbon nanotubes. Chem Commun, 2002, 3050–3051.
55. [55] Rana, S., Cho, J.W., Functionalization of carbon nanotubes via Cu (I)-catalyzed Huisgen [3 + 2] cycloaddition click chemistry. Nanoscale 2 (2010), 2550–2556.
56. [56] Sakellariou, G., Ji, H., Mays, J.W., Hadjichristidis, N., Baskaran, D., Controlled covalent functionalization of multiwalled carbon nanotubes using [4+2] cycloaddition of benzocyclobutenes. Chem Mater 19 (2007), 6370–6372.
57. [57] Li, J., Jia, G., Zhang, Y., Chen, Y., Bond-curvature effect of sidewall [2+1] cycloadditions of single-walled carbon nanotubes: a new criterion to the adduct structures. Chem Mater 18 (2006), 3579–3584.
58. [58] Majumder, N., Click chemistry in nano drug delivery system and its applications in biology. Int J Res Pharm Chem 5 (2015), 95–105.
59. [59] Pan, Y., Bao, H., Sahoo, N.G., Wu, T., Li, L., Water-soluble poly(N-isopropylacrylamide)-graphene sheets synthesized via click chemistry for drug delivery. Adv Funct Mater 21:14 (2011), 2754–2763.
60. [60] Su, X., Shuai, Y., Guo, Z., Feng, Y., Functionalization of multi-walled carbon nanotubes with thermo-responsive azide-terminated poly(N-isopropylacrylamide) via click reactions. Molecules 18 (2013), 4599–4612.
61. [61] Sarkar, K., Madras, G., Chatterjee, K., Dendron conjugation to graphene oxide using click chemistry for efficient gene delivery. RSC Adv 5:62 (2015), 50196–50211.
62. [62] Zhou, L., Shen, Q., Zhao, P., Xiang, B., Nie, Z., Huang, Y., et al. Fluorescent detection of copper(II) based on DNA-templated click chemistry and graphene oxide. Methods 64:3 (2013), 299–304.
63. [63] Wang, Z., Ge, Z., Zheng, X., Chen, N., Peng, C., Fan, C., et al. Polyvalent DNA-graphene nanosheets ‘click’ conjugates. Nanoscale 4 (2012), 394–399.
64. [64] Battigelli, A., Wang, J.t.w., Russier, J., Ros, T.D., Kostareols, K., Al-Jamal, K.T., et al. Ammonium and guanidinium dendron-carbon nanotubes by amidation and click chemistry and their use for siRNA delivery. Small 9 (2013), 3610–3619.
65. [65] Lis, H., Sharon, N., Lectins: carbohydrate-specific proteins that mediate cellular recognition. Chem Rev 98 (1998), 637–674.
66. [66] Bertozzi, C.R., Kiessling, L.L., Chemical glycobiology. Science 291:5512 (2001), 2357–2364.
67. [67] Ragoussi, M.E., Casado, S., Riberio-Viana, R., Torre, G.d.l., Rojo, J., Torres, T., Selective carbohydrate-lectin interactions in covalent graphene- and SWCNT-based molecular recognition systems. Chem Sci 4 (2013), 4035–4041.
68. [68] Moore, E., Wang, P.Y., Vogt, A.P., Gibson, C.T., Haridas, V., Voelcker, N.H., Clicking dendritic peptides onto single walled carbon nanotubes. RSC Adv 2:4 (2012), 1289–1291.
69. [69] Xu, G., Xu, P., Shi, D., Chen, M., Modification of graphene oxide by a facile coprecipitation method and click chemistry for use as a drug carrier. RSC Adv 4:54 (2014), 28807–28813.
70. [70] Ge, S., Sun, M., Liu, W., Wang, X., Chu, C., Yan, M., et al. Disposable electrochemical immunosensor based on peroxidase-like magnetic silica-graphene oxide composites for detection of cancer antigen 153. Sens Actuators B 192 (2014), 317–326.
71. [71] Zhang, Z.B., Wu, J.J., Su, Y., Zhou, J., Gao, Y., Yu, H.Y., et al. Layer-by-layer assembly of graphene oxide on polypropylene macroporous membranes via click chemistry to improve antibacterial and antifouling performance. Appl Surf Sci 332 (2015), 300–307.
72. [72] Namvari, M., Namazi, H., Sweet graphene I: toward hydrophilic graphene nanosheets via click grafting alkyne-saccharides onto azide functionalized graphene oxide. Carbohydr Res 396 (2014), 1–8.
73. [73] Ryu, H.J., Mahapatra, S.S., Yadav, S.K., Cho, J.W., Synthesis of click-coupled graphene sheet with chitosan: effective exfoliation and enhanced properties of their nanocomposites. Eur Polym J 49 (2013), 2627–2634.
74. [74] Huynh, W.U., Dittmer, J.J., Alivisatos, A.P., Hybrid nanorod-polymer solar cells. Science 295 (2002), 2425–2427.
75. [75] Feldheim, D.L., Grabar, K.C., Natan, M.J., Mallouk, T.E., Electron transfer in self-assembled inorganic polyelectrolyte/metal nanoparticle heterostructures. J Am Chem Soc 118 (1996), 7640–7641.
76. [76] Sun, S., Murray, C.B., Weller, D., Folks, L., Moser, A., Monodisperse FePt nanoparticles and ferromagnetic FePt nanocrystal superlattices. Science 287 (2000), 1989–1992.
77. [77] Na, H.B., Lee, J.H., An, K., Park, Y.I., Park, M., Lee, I.S., et al. Development of a T1 contrast agent for magnetic resonance imaging using MnO nanoparticles. Angew Chem Int Ed 46 (2007), 5397–5401.
78. [78] Besson, C., Finney, E.E., Finke, R.G., A mechanism for transition-metal nanoparticle self-assembly. J Am Chem Soc 127 (2005), 8179–8184.
79. [79] Eustis, S., El-Sayed, M.A., Why gold nanoparticles are more precious than pretty gold: noble metal surface plasmon resonance and its enhancement of the radiative and nonradiative properties of Nanocrystals of different shapes. Chem Soc Rev 35 (2006), 209–217.
80. [80] Hong, R., Fischer, N.O., Emrick, T., Rotello, V.M., Surface PEGylation and ligand exchange chemistry of FePt nanoparticles for biological applications. Chem Mater 17 (2005), 4617–4621.
81. [81] Kwon, T., Kim, T., Ali, F.B., Kang, D.J., Yoo, M., Bang, J., et al. Size-controlled polymer-coated nanoparticles as efficient compatibilizers for polymer blends. Macromolecules 44 (2011), 9852–9862.
82. [82] Lopez-Sanchez, J.A., Dimitratos, N., Hammond, C., Brett, G.L., Kesavan, L., White, S., et al. Facile removal of stabilizer-ligands from supported gold nanoparticles. Nat Chem 3 (2011), 551–556.
83. [83] Dong, A., Ye, X., Chen, J., Kang, Y., Gordon, T., Kikkawa, J.M., et al. A generalized ligand-exchange strategy enabling sequential surface functionalization of colloidal nanocrystals. J Am Chem Soc 133 (2011), 998–1006.
84. [84] Tangirala, R., Baker, J.L., Alivisatos, A.P., Milliron, D.J., Modular inorganic nanocomposites by conversion of nanocrystal superlattices. Angew Chem Int Ed 49 (2010), 2878–2882.
85. [85] Yang, H., Kwon, Y., Kwon, T., Lee, H., Kim, B.J., ‘Click’ preparation of CuPt nanorod-anchored graphene oxide as a catalyst in water. Small 8 (2012), 3161–3168.
86. [86] Nia, A.S., Rana, S., Döehler, D., Jirsa, F., Meister, A., Guadagno, L., et al. Carbon-supported copper nanomaterials: recyclable catalysts for Huisgen [3+2] cycloaddition reactions. Chem Eur J 21 (2015), 10763–10770.
87. [87] Zhao, L., Zeng, B., Zhao, F., Electrochemical determination of tartrazine using a molecularly imprinted polymer – multiwalled carbon nanotubes – ionic liquid supported Pt nanoparticles composite film coated electrode. Electrochim Acta 146 (2014), 611–617.
88. [88] Namvari, M., Namazi, H., Preparation of efficient magnetic biosorbents by clicking carbohydrates onto graphene oxide. ‎J Mater Sci 50 (2015), 5348–5361.
89. [89] He, H., Zhang, Y., Gao, C., Wu, J., ‘Clicked’ magnetic nanohybrids with a soft polymer interlayer. Chem Commun, 2009, 1655–1657.
90. [90] Lamanna, G., Garofalo, A., Popa, G., Wilhelm, C., Bégin-Colin, S., Felder-Flesch, D., et al. Endowing carbon nanotubes with superparamagnetic properties: applications for cell labeling, MRI cell tracking and magnetic manipulations. Nanoscale 5 (2013), 4412–4421.
91. [91] Yenchalwar, S.G., Devarapalli, R.R., Deshmukh, A.B., Shelke, M.V., Plasmon-enhanced photocurrent generation from click-chemically modified graphene. Chem Eur J 20 (2014), 7402–7409.
92. [92] Voggu, R., Suguna, P., Chandrasekaran, S., Rao, C.N.R., Assembling covalently linked nanocrystals and nanotubes through click chemistry. Chem Phys Lett 443 (2007), 118–121.
93. [93] Rana, S., Kumar, I., Yoo, H.J., Cho, J.W., Assembly of gold nanoparticles on single-walled carbon nanotubes by using click chemistry. J Nanosci Nanotechnol 9 (2009), 3261–3263.
94. [94] Yadav, S.K., Mahapatra, S.S., Yoo, H.J., Cho, J.W., Synthesis of multi-walled carbon nanotube/polyhedral oligomeric silsesquioxane nanohybrid by utilizing click chemistry. Nanoscale Res Lett, 6, 2011 122/1-6.
95. [95] Yadav, S.K., Madeshwaran, S.R., Cho, J.W., Synthesis of a hybrid assembly composed of titanium dioxide nanoparticles and thin multi-walled carbon nanotubes using click chemistry. J Colloid Interface Sci 358 (2011), 471–476.
96. 2 nanoparticles in PS-b-P2VP block copolymers by quaternization. J Mater Chem 19 (2009), 7322–7325.
97. 60 fullerene by use of amphiphilic block copolymers: preparation and nonlinear optical properties. J Phys Chem B 111 (2007), 4315–4319.
98. [98] Shen, J., Hu, Y., Li, C., Qin, C., Ye, M., Synthesis of amphiphilic graphene nanoplatelets. Small 5 (2009), 82–85.
99. [99] Peponi, L., Tercjak, A., Verdejo, R., Lopez-Manchado, M.A., Mondragon, I., Kenny, J.M., Confinement of functionalized graphene sheets by triblock copolymers. J Phys Chem C 113 (2009), 17973–17978.
100. [100] Kim, B.H., Kim, J.Y., Jeong, S.J., Hwang, J.O., Lee, D.H., Shin, D.O., et al. Surface energy modification by spin-cast, large-area graphene film for block copolymer lithography. ACS Nano 4 (2010), 5464–5470.
101. [101] Li, J., He, W.D., Yang, L.P., Sun, X.L., Hua, Q., Preparation of multi-walled carbon nanotubes grafted with synthetic poly(L-lysine) through surface-initiated ring-opening polymerization. Polymer 48 (2007), 4352–4360.
102. [102] Shaffer, M.s.p., Koziol, K., Polystyrene grafted multi-walled carbon nanotubes. Chem Commun, 2002, 2074–2075.
103. [103] Yang, M., Gao, Y., Li, H., Adronov, A., Functionalization of multi-walled carbon nanotubes with polyamide 6 by anionic ring-opening polymerization. Carbon 45 (2007), 2327–2333.
104. [104] Yao, Z., Braidy, N., Botton, G.A., Adronov, A., Polymerization from the surface of single-walled carbon nanotubes—preparation and characterization of nanocomposites. J Am Chem Soc 125 (2003), 16015–16024.
105. [105] Li, H., Cheng, F., Duft, A.M., Adronov, A., Functionalization of single-walled carbon nanotubes with well-defined polystyrene by click coupling. J Am Chem Soc 127 (2005), 14518–14524.
106. [106] Kumar, I., Rana, S., Cho, J.W., Cycloadditions reactions: a controlled appraoch for carbon nanotube functionalization. Chem A Eur J 17 (2011), 11092–11101.
107. [107] Sun, S., Cao, Y., Feng, J., Wu, P., Click chemistry as a route for the immobilization of well-defined polystyrene onto graphene sheets. J Mater Chem 20 (2010), 5605–5607.
108. [108] Ye, Y.S., Chen, Y.N., Wang, J.S., Rick, J., Huang, Y.J., Chang, F.C., et al. Versatile grafting approaches to functionalizing individually dispersed graphene nanosheets using RAFT polymerization and click chemistry. Chem Mater 24 (2012), 2987–2997.
109. [109] Yang, Y., Song, X., Yuan, L., Li, M., Liu, J., Ji, R., et al. Synthesis of PNIPAM polymer brushes on reduced graphene oxide based on click chemistry and RAFT polymerization. J Polym Sci A Polym Chem 50 (2012), 329–337.
110. [110] Cao, Y., Lai, Z., Feng, J., Wu, P., Graphene oxide sheets covalently functionalized with block copolymers via click chemistry as reinforcing fillers. J Mater Chem 21 (2011), 9271–9278.
111. [111] Yadav, S.K., Mahapatra, S.S., Cho, J.W., Lee, J.Y., Functionalization of multiwalled carbon nanotubes with poly(styrene-b-(ethylene-co-butylene)-b-styrene) by click coupling. J Phys Chem C 114 (2010), 11395–11400.
112. [112] Fang, M., Wang, K., Lu, H., Yanga, Y., Nuttb, S., Covalent polymer functionalization of graphene nanosheets and mechanical properties of composites. J Mater Chem 19 (2009), 7098–7105.
113. [113] Xie, L., Xu, F., Qiu, F., Lu, H., Yang, Y., Single-walled carbon nanotubes functionalized with high bonding density of polymer layers and enhanced mechanical properties of composites. Macromolecules 40 (2007), 3296–3305.
114. [114] Moniruzzaman, M., Winey, K.I., Polymer nanocomposites containing carbon nanotubes. Macromolecules 39 (2006), 5194–5205.
115. [115] Huang, W., Wang, S., Guo, C., Yang, X., Li, Y., Tu, Y., Synthesis and characterization of well-defined poly(L-lactide) functionalized graphene oxide sheets with high grafting ratio prepared through click chemistry and supramolecular interactions. Polymer 55 (2014), 4619–4626.
116. [116] Rana, S., Yoo, H.J., Cho, J.W., Chun, B.C., Park, J.S., Functionalization of multi-walled carbon nanotubes with poly(ε-caprolactone) using click chemistry. ‎J Appl Polym Sci 119 (2011), 31–37.
117. [117] Rana, S., Cho, J.W., Kumar, I., Synthesis and characterization of polyurethane-grafted single-walled carbon nanotubes via click chemistry. J Nanosci Nanotechnol 10 (2010), 5700–5707.
118. [118] Lee, R.S., Chen, W.H., Lin, J.H., Polymer-grafted multi-walled carbon nanotubes through surface-initiated ring-opening polymerization and click reaction. Polymer 52 (2011), 2180–2188.
119. [119] Yadav, S.K., Yoo, H.J., Cho, J.W., Click coupled graphene for fabrication of high-performance polymer nanocomposites. J Polym Sci B Polym Phys 51 (2013), 39–47.
120. [120] Mondal, T., Bhowmick, A.K., Krishnamoorti, R., Stress generation and tailoring of electronic properties of expanded graphite by click chemistry. ACS Appl Mater Interfaces 6 (2014), 7244–7253.
121. [121] Campidelli, S., Ballesteros, B., Filoramo, A., Díaz, D.D., Torre, G.D.L., Torres, T., et al. Facile decoration of functionalized single-wall carbon nanotubes with phthalocyanines via click chemistry. J Am Chem Soc 130 (2008), 11503–11509.
122. [122] Ragoussi, M.E., Katsukis, G., Roth, A., Malig, J., Torre, G.d.l., Guldi, D.M., et al. Electron-donating behavior of few-layer graphene in covalent ensembles with electron-accepting phthalocyanines. J Am Chem Soc 136 (2014), 4593–4598.
123. [123] Palacin, T., Khanh, H.L., Jousselme, B., Jegou, P., Filoramo, A., Ehli, C., et al. Efficient functionalization of carbon nanotubes with porphyrin dendrons via click chemistry. J Am Chem Soc 131 (2009), 15394–15402.
124. [124] Wang, H.X., Zhou, K.G., Xie, Y.L., Zeng, J., Chai, N.N., Li, J., et al. Photoactive graphene sheets prepared by click chemistry. Chem Commun 47 (2011), 5747–5749.
125. [125] Rosenblatt, S., Yaish, Y., Park, J., Gore, J., Sazonova, V., McEuen, P.L., High performance electrolyte gated carbon nanotube transistors. Nano Lett 2 (2002), 869–872.
126. [126] Banks, C.E., Davies, T.J., Wildgoose, G.G., Compton, R.G., Electrocatalysis at graphite and carbon nanotube modified electrodes: edge-plane sites and tube ends are the reactive sites. Chem Commun, 2005, 829–841.
127. [127] Ye, J.S., Liu, X., Cui, H.F., Zhang, W.D., Sheu, F.S., Lim, T.M., Electrochemical oxidation of multi-walled carbon nanotubes and its application to electrochemical double layer capacitors. Electrochem Commun 7 (2005), 249–255.
128. [128] Liu, C.M., Cao, H.B., Li, Y.P., Xu, H.B., Zhang, Y., The effect of electrolytic oxidation on the electrochemical properties of multi-walled carbon nanotubes. Carbon 44 (2006), 2919–2924.
129. [129] Unger, E., Graham, A., Kreupl, F., Liebau, M., Hoenlein, W., Electrochemical functionalization of multi-walled carbon nanotubes for solvation and purification. Curr Appl Phys 2 (2002), 107–111.
130. [130] Patil, A., Vaia, R., Dai, L., Surface modification of aligned carbon nanotube arrays for electron emitting applications. Synthetic Met 154 (2005), 229–232.
131. [131] Haddad, R., Cosnier, S., Maaref, A., Holzinger, M., Non-covalent biofunctionalization of single-walled carbon nanotubes via biotin attachment by π-stacking interactions and pyrrole polymerization. Analyst 134 (2009), 2412–2418.
132. [132] Ding, B., Lu, X., Yuan, C., Yang, S., Han, Y., Zhang, X., et al. One-step electrochemical composite polymerization of polypyrrole integrated with functionalized graphene/carbon nanotubes nanostructured composite film for electrochemical capacitors. Electrochim Acta 62 (2012), 132–139.
133. [133] Lindfors, T., Latonen, R.M., Improved charging/discharging behavior of electropolymerized nanostructured composite films of polyaniline and electrochemically reduced graphene oxide. Carbon 69 (2014), 122–131.
134. [134] Hassan, H.K., Atta, N.F., Galal, A., Electropolymerization of aniline over chemically converted graphene-systematic study and effect of dopant. Int J Electrochem Sci 7 (2012), 11161–11181.
135. [135] Asadian, E., Shahrokhian, S., Irajizad, A., Jokar, E., In-situ electro-polymerization of graphene nanoribbon/polyanilinecomposite film: application to sensitive electrochemical detection of dobutamine. Sens Actuators B 196 (2014), 582–588.
136. [136] Zhang, Y., Zhen, Z., Zhang, Z., Lao, J., Wei, J., Wang, K., et al. In-situ synthesis of carbon nanotube/graphene composite sponge and its application as compressible supercapacitor electrode. Electrochim Acta 157 (2015), 134–141.
137. [137] Chabi, S., Peng, C., Hu, D., Zhu, Y.Q., Ideal three-dimensional electrode structures for electrochemical energy storage. Adv Mater 26 (2014), 2440–2445.
138. [138] Tang, G., Jiang, Z.G., Li, X., Zhang, H.B., Dasari, A., Yu, Z.Z., Three dimensional graphene aerogels and their electrically conductive composites. Carbon 77 (2014), 592–599.
139. [139] Xu, Y., Lin, Z., Huang, X., Liu, Y., Huang, Y., Duan, X., Flexible solid-state supercapacitors based on three-dimensional graphene hydrogel films. ACS Nano 7 (2013), 4042–4049.
140. [140] Jiang, L., Fan, Z., Design of advanced porous graphene materials: from graphene nanomesh to 3D architectures. Nanoscale 6 (2014), 1922–1945.
141. [141] Sun, M., Li, H., Wang, J., Wang, G., Promising graphene/carbon nanotube foam@π-conjugated polymer self-supporting composite cathodes for high-performance rechargeable lithium batteries. Carbon 94 (2015), 864–871.
142. [142] Mittal, V., Carbon nanotubes surface modifications: an overview. Mittal, V., (eds.) Surface modification of nanotube fillers, 2011, Wiley-VCH Verlag GmbH & Co KgaA, Weinheim, 1–23.
143. [143] Choi, E.Y., Han, T.H., Hong, J., Kim, J.E., Lee, S.H., Kim, H.W., et al. Noncovalent functionalization of graphene with end-functional polymers. J Mater Chem 20 (2010), 1907–1912.
144. [144] Liu, J., Liu, Z., Luo, X., Zong, X., Liu, J., RAFT controlled synthesis of biodegradable polymer brushes on graphene for DNA binding and release. Macromol Chem Phys 214 (2013), 2266–2275.
145. [145] Wang, Q.H., Hersam, M.C., Room-temperature molecular-resolution characterization of self-assembled organic monolayers on epitaxial graphene. Nat Chem 1 (2009), 206–211.
146. [146] Su, Q., Pang, S., Alijani, V., Li, C., Feng, X., Müllen, K., Composites of graphene with large aromatic molecules. Adv Mater 21 (2009), 3191–3195.
147. [147] Liang, J., Huang, Y., Zhang, L., Wang, Y., Ma, Y., Guo, T., et al. Molecular-level dispersion of graphene into poly(vinyl alcohol) and effective reinforcement of their nanocomposites. Adv Funct Mater 19 (2009), 2297–2302.
148. [148] Liu, Y., Gao, L., Sun, J., Wang, Y., Zhang, J., Stable Nafion-functionalized graphene dispersions for transparent conducting films. Nanotechnology, 20, 2009 465605/1-7.
149. [149] Wang, Y., Li, Y., Tang, L., Lu, J., Li, J., Application of graphene-modified electrode for selective detection of dopamine. Electrochem Commun 11 (2009), 889–892.
150. [150] Zhang, D., Fu, L., Liao, L., Liu, N., Dai, B., Zhang, C., Preparation, characterization, and application of electrochemically functional graphene nanocomposites by one-step liquid-phase exfoliation of natural flake graphite with methylene blue. Nano Res 5 (2012), 875–887.
151. [151] Kim, T.Y., Lee, H.W., Stoller, M., Dreyer, D.R., Bielawski, C.W., Ruoff, R.S., et al. High-performance supercapacitors based on poly(ionic liquid)-modified graphene electrodes. ACS Nano 5 (2011), 436–442.
152. [152] Sun, X., Sun, H., Li, H., Peng, H., Developing polymer composite materials: carbon nanotubes or graphene. Adv Mater 25 (2013), 5153–5176.
153. [153] Paiva, M.C., Zhou, B., Fernando, K.a.s., Lin, Y., Kennedy, J.M., Sun, Y.P., Mechanical and morphological characterization of polymer-carbon nanocomposites from functionalized carbon nanotubes. Carbon 42 (2004), 2849–2854.
154. [154] Cheng, H.k.f., Sahoo, N.G., Tan, Y.P., Pan, Y., Bao, H., Li, L., et al. Poly(vinyl alcohol) nanocomposites filled with poly(vinyl alcohol)-grafted graphene oxide. ACS Appl Mater Interfaces 4 (2012), 2387–2394.
155. [155] Cano, M., Khan, U., Sainsbury, T., O'Neill, A., Wang, Z., McGovern, I.T., et al. Improving the mechanical properties of graphene oxide based materials by covalent attachment of polymer chains. Carbon 52 (2013), 363–371.
156. [156] Li, Y., Yang, T., Yu, T., Zheng, L., Liao, K., Synergistic effect of hybrid carbon nantube-graphene oxide as a nanofiller in enhancing the mechanical properties of PVA composites. J Mater Chem 21 (2011), 10844–10851.
157. [157] Zhang, C., Huang, S., Tjiu, W.W., Fan, W., Liu, T., Facile preparation of water-dispersible graphene sheets stabilized by acid-treated multi-walled carbon nanotubes and their poly(vinyl alcohol) composites. J Mater Chem 22 (2012), 2427–2434.
158. [158] Fujimori, K., Gopiraman, M., Kim, H.K., Kim, B.S., Kim, I.S., Mechanical and electromagnetic interference shielding properties of poly(vinyl alcohol)/graphene and poly(vinyl alcohol)/multi-walled carbon nanotube composite nanofiber mats and the effect of Cu top-layer coating. J Nanosci Nanotechnol 13 (2013), 1759–1764.
159. [159] Zhang, S., Yin, S., Rong, C., Huo, P., Jiang, Z., Wang, G., Synergistic effects of functionalized graphene and functionalized multi-walled carbon nanotubes on the electrical and mechanical properties of poly(ether sulfone) composites. Eur Polym J 49 (2013), 3125–3134.
160. [160] Dervishi, E., Hategekimana, F., Boyer, L., Watanabe, F., Mustafa, T., Biswas, A., et al. The effect of carbon nanotubes and graphene on the mechanical properties of multi-component polymeric composites. Chem Phys Lett 590 (2013), 126–130.
161. [161] El Achaby, M., Qaiss, A., Processing and properties of polyethylene reinforced by graphene nanosheets and carbon nanotubes. Mater Des 44 (2013), 81–89.
162. [162] Yang, S.Y., Lin, W.N., Huang, Y.L., Tien, H.W., Wang, J.Y., Ma, C.c.m., et al. Synergetic effects of graphene platelets and carbon nanotubes on the mechanical and thermal properties of epoxy composites. Carbon 49 (2011), 793–803.
163. [163] Pradhan, B., Srivastava, S.K., Synergistic effect of three-dimensional multi-walled carbon nanotube-graphene nanofiller in enhancing the mechanical and thermal properties of high-performance silicone rubber. Polymer Int 63 (2014), 1219–1228.
164. [164] Cardoso, P., Silva, J., Paleo, A.J., van Hattum, F.w.j., Simoes, R., Lanceros-Méndez, S., The dominant role of tunneling in the conductivity of carbon nanofiber-epoxy composites. Phys Status Solidi A 207 (2010), 407–410.
165. [165] Sandler, J.k.w., Kirk, J.E., Kinloch, I.A., Shaffer, M.s.p., Windle, A.H., Ultra-low electrical percolation threshold in carbon-nanotube-epoxy composites. Polymer 44 (2003), 5893–5899.
166. [166] Stankovich, S., Dikin, D.A., Dommett, G.h.b., Kohlhaas, K.M., Zimney, E.J., Stach, E.A., et al. Graphene-based composite materials. Nature 442 (2006), 282–286.
167. [167] Khan, M.O., Leung, S.N., Chan, E., Naguib, H.E., Dawson, F., Adinkrah, V., Effects of microsized and nanosized carbon fillers on the thermal and electrical properties of polyphenylene sulfide based composites. Polym Eng Sci 53 (2013), 2398–2406.
168. [168] He, Z., Zhang, X., Chen, M., Li, M., Gu, Y., Zhang, Z., et al. Effect of the filler structure of carbon nanomaterials on the electrical, thermal, and rheological properties of epoxy composites. J Appl Polym Sci 129 (2013), 3366–3372.
169. [169] Kong, K.t.s., Mariatti, M., Rashid, A.A., Busfield, J.J.C., Enhanced conductivity behavior of polydimethylsiloxane (PDMS) hybrid composites containing exfoliated graphite nanoplatelets and carbon nanotubes. Composites Part B 58 (2014), 457–462.
170. [170] Kumar, S., Sun, L.L., Caceres, S., Li, B., Wood, W., Perugini, A., et al. Dynamic synergy of graphitic nanoplatelets and multi-walled carbon nanotubes in polyetherimide nanocomposites. Nanotechnology, 21, 2010 105702/1-9.
171. [171] Du, J., Zhao, L., Zeng, Y., Zhang, L., Li, F., Liu, P., et al. Comparison of electrical properties between multi-walled carbon nanotube and graphene nanosheet/high density polyethylene composites with a segregated network structure. Carbon 49 (2011), 1094–1100.
172. [172] Ghislandi, M., Tkalya, E., Schillinger, S., Koning, C.E., de With, G., High performance graphene and MWCNTs-based PS/PPO composites obtained via organic solvent dispersion. Compos Sci Technol 80 (2013), 16–22.
173. [173] Lu, X., Dou, H., Yang, S., Hao, L., Zhang, L., Shen, L., et al. Fabrication and electrochemical capacitance of hierarchical graphene/polyaniline/carbon nanotube ternary composite film. Electrochim Acta 56 (2011), 9224–9232.
174. [174] Sachdev, V.K., Bhattacharya, S., Patel, K., Sharma, S.K., Mehra, N.C., Tandon, R.P., Electrical and EMI shielding characterization of multiwalled carbon nanotube/polystyrene composites. J Appl Polym Sci 131 (2014), 40201–40209.
175. [175] Wu, N., She, X., Yang, D., Wu, X., Su, F., Chen, Y., Synthesis of network reduced graphene oxide in polystyrene matrix by a two-step reduction method for superior conductivity of the composite. J Mater Chem 22 (2012), 17254–17261.
176. [176] Vadukumpully, S., Paul, J., Mahanta, N., Valiyaveettil, S., Flexible conductive graphene/poly(vinyl chloride) composite thin films with high mechanical strength and thermal stability. Carbon 49 (2011), 198–205.
177. [177] Broza, G., Piszczek, K., Schulte, K., Sterzynski, T., Nanocomposites of poly(vinyl chloride) with carbon nanotubes (CNT). Compos Sci Technol 67 (2007), 890–894.
178. [178] Sahoo, N.G., Cheng, H.k.f., Bao, H., Li, L., Chan, S.H., Zhao, J., Nitrophenyl functionalization of carbon nanotubes and its effect on properties of MWCNT/LCP composites. Macromol Res 19 (2011), 660–667.
179. [179] Biswas, S., Fukushima, H., Drzal, L.T., Mechanical and electrical property enhancement in exfoliated graphene nanoplatelet/liquid crystalline polymer nanocomposites. Composites Part A 42 (2011), 371–375.
180. [180] Hatui, G., Bhattacharya, P., Sahoo, S., Dhibar, S., Das, C.K., Combined effect of expanded graphite and multiwall carbon nanotubes on the thermo mechanical, morphological as well as electrical conductivity of in situ bulk polymerized polystyrene composites. Composites Part A 56 (2014), 181–191.
181. [181] Ajayan, P.M., Tour, J.M., Materials science nanotube composites. Nature 447 (2007), 1066–1068.
182. [182] Cheng, Q., Wang, B., Zhang, C., Liang, Z., Functionalized carbon-nanotube sheet/bismaleimide nanocomposites: mechanical and electrical performance beyond carbon-fiber composites. Small 6 (2010), 763–767.
183. [183] Du, F., Fischer, J.E., Winey, K.I., Effect of nanotube alignment on percolation conductivity in carbon nanotube/polymer composites. Phy Rev B, 72, 2005 121404(R)/1-4.
184. [184] Farahani, R.D., Dalir, H., Borgne, V.L., Gautier, L.A., Khakani, M.a.e., Lévesque, M., et al. Reinforcing epoxy nanocomposites with functionalized carbon nanotubes via biotin-streptavidin interactions. Compos Sci Technol 72 (2012), 1387–1395.
185. [185] Hubert, P., Ashrafi, B., Adhikari, K., Meredith, J., Vengallatore, S., Guan, J., et al. Synthesis and characterization of carbon nanotube reinforced epoxy: correlation between viscosity and elastic modulus. Compos Sci Technol 69 (2009), 2274–2280.
186. [186] Najeeb, C.K., Lee, J.H., Chang, J., Kim, J.H., The effect of surface modifications of carbon nanotubes on the electrical properties of inkjet-printed SWNT/PEDOT-PSS composite line patterns. Nanotechnology, 21, 2010 385302/1-6.
187. [187] Chang, C.M., Liu, Y.L., Functionalized of multi-walled carbon nanotubes with non-reactive polymer through an ozone-mediated process for the preparation of a wide range of high performance polymer/carbon nanotube composites. Carbon 48 (2010), 1289–1297.
188. [188] Pan, Y., Cheng, H.k.f., Chan, S.H., Zhao, J., Juay, Y.K., Annealing induced electrical conductivity jump of multi-walled carbon nanotube/polypropylene composites and influence of molecular weight of polypropylene. J Polym Sci B Polym Phys 48 (2010), 2238–2247.
189. [189] Leon, V., Parret, R., Almairac, R., Alvarez, L., Babaa, M.R., Doyle, B.P., et al. Spectroscopic study of double-walled carbon nanotube functionalization for preparation of carbon nanotube-epoxy composites. Carbon 50 (2012), 4987–4994.
190. [190] Guadagno, L., Vivo, B.D., Bartolomeo, A.D., Lamberti, P., Sorrentino, A., Tucci, V., et al. Effect of functionalization on the thermo-mechanicalm and electrical behavior of multi-wall carbon nanotube/epoxyn composites. Carbon 49 (2011), 1919–1930.
191. [191] Tchmutin, I.A., Ponomarenko, A.T., Krinichnaya, E.P., Kozub, G.I., Efimov, O.N., Electrical properties of composites based on conjugated polymers and conductive fillers. Carbon 41 (2003), 1391–1395.
192. [192] Thostenson, E.T., Ziaee, S., Chou, T.W., Processing and electrical properties of carbon nanotube/vinyl ester nanocomposites. Composites Sci Technol 69 (2009), 801–804.
193. [193] Gojny, F.H., Wichmann, M.h.g., Fiedler, B., Kinloch, I.A., Bauhofer, W., Windle, A.H., et al. Evaluation and identification of electrical and thermal conduction mechanisms in carbon nanotube/epoxy composites. Polymer 47 (2006), 2036–2045.
194. [194] Irshidat, M.R., Al-Saleh, M.H., Almashagbeh, H., Effect of carbon nanotubes on strengthening of RC beams retrofitted with carbon fiber/epoxy composites. Mater Des 89 (2016), 225–234.
195. [195] Gryshchuk, O., Karger, K.J., Thomann, R., Kónya, Z., Kiricsi, I., Multiwall carbon nanotube modified vinylester and vinylester based hybrid resins. Composites Part A 37 (2006), 1252–1259.
196. [196] Du, J., Cheng, H.M., The fabrication, properties, and uses of graphene/polymer composites. Macromol Chem Phys 213 (2012), 1060–1077.
197. [197] Yang, S.Y., Ma, C.c.m., Teng, C.C., Huang, Y.W., Liao, S.H., Huang, Y.L., et al. Effect of functionalized carbon nanotubes on the thermal conductivity of epoxy composites. Carbon 48 (2010), 592–603.
198. [198] Chatterjee, S., Nafezarefi, F., Tai, N.H., Schlagenhauf, L., Nüesch, F.A., Chu, B.T.T., Size and synergy effects of nanofiller hybrids including graphene nanoplatelets and carbon nanotubes in mechanical properties of epoxy composites. Carbon 50 (2012), 5380–5386.
199. [199] Song, W.L., Wang, W., Veca, L.M., Kong, C.Y., Cao, M.S., Wang, P., et al. Polymer/carbon nanocomposites for enhanced thermal transport properties carbon nanotubes versus graphene sheets as nanoscale fillers. J Mater Chem 22 (2012), 17133–17139.
200. [200] Yang, X., Zhan, Y., Yang, J., Zhong, J., Zhao, R., Liu, X., Synergetic effect of cyanogen functionalized carbon nanotube and graphene on the mechanical and thermal properties of poly(arylene ether nitrile). J Polym Res, 19, 2011 9806/1-6.
201. [201] Sundmacher, K., Fuel cell engineering: toward the design of efficient electrochemical power plants. Ind Eng Chem Res 49 (2010), 10159–10182.
202. [202] Wasmus, S., Küver, A., Methanol oxidation and direct methanol fuel cells: a selective review. J Electroanal Chem 461 (1999), 14–31.
203. [203] Winter, M., Brodd, R.J., What are batteries, fuel cells, and supercapacitors. Chem Rev 104 (2004), 4245–4270.
204. [204] Kuila, T., Khanra, P., Bose, S., Kim, N.H., Ku, B.C., Moon, B., et al. Preparation of water-dispersible graphene by facile surface modification of graphite oxide. Nanotechnology, 22, 2011 305710/1-8.
205. [205] Dong, H., Dong, L., Electrocatalytic activity of carbon nanotube-supported Pt-Cr-Co tri-metallic nanoparticles for methanol and ethanol oxidations. J Inorg Organomet Polym Mater 21 (2011), 754–757.
206. n. Phys Chem Chem Phys 15 (2013), 12846–12851.
207. [207] Hsu, C.H., Kuo, P.L., The use of carbon nanotubes coated with a porous nitrogen-doped carbon layer with embedded Pt for the methanol oxidation reaction. J Power Sources 198 (2012), 83–89.
208. [208] Zhang, L.S., Liang, X.Q., Song, W.G., Wu, Z.Y., Identification of the nitrogen species on N-doped graphene layers and Pt/NG composite catalyst for direct methanol fuel cell. Phys Chem Chem Phys 12 (2010), 12055–12059.
209. [209] Sheng, Z.H., Shao, L., Chen, J.J., Bao, W.J., Wang, F.B., Xia, X.H., Catalyst-free synthesis of nitrogen-doped graphene via thermal annealing graphite oxide with melamine and its excellent electrocatalysis. ACS Nano 5 (2011), 4350–4358.
210. [210] Oh, H.S., Oh, J.G., Lee, W.H., Kim, H.J., Kim, H., The influence of the structural properties of carbon on the oxygen reduction reaction of nitrogen modified carbon based catalysts. Int J Hydrogen Energy 36 (2011), 8181–8186.
211. [211] Zhang, M., Xie, J., Sun, Q., Yan, Z., Chen, M., Jing, J., Enhanced electrocatalytic activity of high Pt-loadings on surface functionalized graphene nanosheets for methanol oxidation. Int J Hydrogen Energy 38 (2013), 16402–16409.
212. [212] Liu, J., Lai, L., Sahoo, N.G., Zhou, W., Shen, Z., Chan, S.H., Carbon nanotube-based materials for fuel cell applications. Aust J Chem 65 (2012), 1213–1222.
213. [213] Qiu, J.D., Wang, G.C., Liang, R.P., Xia, X.H., Yu, H.W., Controllable deposition of platinum nanoparticles on graphene as an electrocatalyst for direct methanol fuel cells. J Phys Chem C 115 (2011), 15639–15645.
214. [214] Li, Y., Tang, L., Li, J., Preparation and electrochemical performance for methanol oxidation of Pt/graphene nanocomposites. Electrochem commun 11 (2009), 846–849.
215. [215] Seger, B., Kamat, P.V., Electrocatalytically active graphene-platinum nanocomposites: role of 2-D carbon support in PEM fuel cells. J Phys Chem C 113 (2009), 7990–7995.
216. [216] Jafri, R.I., Arockiados, T., Rajalakshmi, N., Ramaprabhu, S., Nanostructured Pt dispersed on graphene-multiwalled carbon nanotube hybrid nanomaterials as electrocatalyst for PEMFC. J Electrochem Soc 157 (2010), B874–9.
217. [217] Lei, M., Liang, C., Wang, Y.J., Huang, K., Ye, C.X., Liu, G., et al. Durable platinum/graphene catalysts assisted with polydiallyldimethylammonium for proton-exchange membrane fuel cells. Electrochim Acta 113 (2013), 366–372.
218. [218] Wei, L., Fan, Y.J., Ma, J.H., Tao, L.H., Wang, R.X., Zhong, J.P., et al. Highly dispersed Pt nanoparticles supported on manganese oxide-poly(3,4-ethylenedioxythiophene)-carbon nanotubes composite for enhanced methanol electrooxidation. J Power Sources 238 (2013), 157–164.
219. [219] Oh, H.S., Kim, K., Kim, H., Polypyrrole-modified hydrophobic carbon nanotubes as promising electrocatalyst supports in polymer electrolyte membrane fuel cells. Int J Hydrogen Energy 36 (2011), 11564–11571.
220. [220] Jiang, F., Yao, Z., Yue, R., Xu, J., Du, Y., Yang, P., et al. Electrocatalytic activity of Pd nanoparticles supported on poly(3,4-ethylenedioxythiophene)-graphene hybrid for ethanol electrooxidation. J Solid State Electrochem 17 (2013), 1039–1047.
221. [221] Cui, Z., Kulesza, P.J., Li, C.M., Xing, W., Jiang, S.P., Pd nanoparticles supported on HPMo-PDDA-MWCNT and their activity for formic acid oxidation reaction of fuel cells. Int J Hydrogen Energy 36 (2011), 8508–8517.
222. [222] Wang, S., Yu, D., Dai, L., Chang, D.W., Baek, J.B., Polyelectrolyte-functionalized graphene as metal-free electrocatalysts for oxygen reduction. ACS Nano 5 (2011), 6202–6209.
223. [223] Wang, S., Yu, D., Dai, L., Polyelectrolyte functionalized carbon nanotubes as efficient metal-free electrocatalysts for oxygen reduction. J Am Chem Soc 133 (2011), 5182–5185.
224. [224] Cele, N.P., Ray, S.S., Pillai, S.K., Ndwandwe, M., Nonjola, S., Sikhwivhilu, L., et al. Carbon nanotubes based nafion composite membranes for fuel cell applications. Fuel Cells 10 (2010), 64–71.
225. [225] Ye, Y.S., Cheng, M.Y., Xie, X.L., Rick, J., Huang, Y.J., Chang, F.C., et al. Alkali doped polyvinyl alcohol/graphene electrolyte for direct methanol alkaline fuel cells. J Power Sources 239 (2013), 424–432.
226. [226] Pan, W.H., Lue, S.J., Chang, C.M., Liu, Y.L., Alkali doped polyvinyl alcohol/multi-walled carbon nano-tube electrolyte for direct methanol alkaline fuel cell. J Memb Sci 376 (2011), 225–232.
227. [227] Yoo, M., Kim, M., Hwang, Y., Kim, J., Fabrication of highly selective PVA-g-GO/SPVA membranes via cross-linking method for direct methanol fuel cells. Ionics 20 (2014), 875–886.
228. [228] Yun, S., Im, H., Heo, Y., Kim, J., Crosslinked sulfonated poly(vinyl alcohol)/sulfonated multi-walled carbon nanotubes nanocomposite membranes for direct methanol fuel cells. J Memb Sci 380 (2011), 208–215.
229. [229] Cao, Y.C., Xu, C., Wu, X., Wang, X., Xing, L., Scott, K., A poly (ethylene oxide)/graphene oxide electrolyte membrane for low temperature polymer fuel cells. J Power Sources 196 (2011), 8377–8382.
230. [230] Yu, D.M., Sung, I.H., Yoon, Y.J., Kim, T.H., Lee, J.Y., Hong, Y.T., Properties of sulfonated poly(arylene ether sulfone)/functionalized carbon nanotube composite membrane for high temperature PEMFCs. Fuel Cells 13 (2013), 843–850.
231. [231] Jiang, X., Drzal, L.T., Exploring the potential of exfoliated graphene nanoplatelets as the conductive filler in polymeric nanocomposites for bipolar plates. J Power Sources 218 (2012), 297–306.
232. [232] Tjong, S.C., Polymer nanocomposite bipolar plates reinforced with carbon nanotubes and graphite nanosheets. Energy Environ Sci 4 (2011), 605–626.
233. [233] Liao, S.H., Hsiao, M.C., Yen, C.Y., Ma, C.c.m., Lee, S.J., Su, A., et al. Novel functionalized carbon nanotubes as cross-links reinforced vinyl ester/nanocomposite bipolar plates for polymer electrolyte membrane fuel cells. J Power Sources 195 (2010), 7808–7817.
234. [234] Kauffman, D.R., Star, A., Graphene versus carbon nanotubes for chemical sensor and fuel cell applications. Analyst 135 (2010), 2790–2797.
235. [235] Helgesen, M., Sondergaard, R., Krebs, F.C., Advanced materials and processes for polymer solar cell devices. J Mater Chem 20 (2009), 36–60.
236. [236] Yu, G., Gao, J., Hummelen, J.C., Wudl, F., Heeger, A.J., Polymer photovoltaic cells: enhanced efficiencies via a network of internal donor-acceptor heterojunctions. Science 270 (1995), 1789–1791.
237. [237] Nair, R.R., Blake, P., Grigorenko, A.N., Novoselov, K.S., Booth, T.J., Stauber, T., et al. Fine structure constant defines visual transparency of graphene. Science 320 (2008), 1308–1315.
238. [238] Bounioux, C., Katz, E.A., Yerushalmi-Rozen, R., Conjugated polymers—carbon nanotubes-based functional materials for organic photovoltaics: a critical review. Polym Adv Technol 23 (2012), 1129–1140.
239. [239] Wang, S.H., Hsiao, Y.J., Fang, T.H., Lin, M.H., Kang, S.H., Enhancing performance and nanomechanical properties of carbon nanotube doped P3HT:PCBM solar cells. ECS J Solid State Sci Technol 2 (2013), M52–5.
240. [240] Derbal-Habak, H., Bergeret, C., Cousseau, J., Nunzi, J.M., Improving the current density Jsc of organic solar cells P3HT:PCBM by structuring the photoactive layer with functionalized SWCNTs. Sol Energy Mater Sol C 95 (2011), S53–6.
241. [241] Yan, J., Ni, T., Zou, F., Zhang, L., Yang, D., Yang, S., et al. Towards optimization of functionalized single-walled carbon nanotubes adhering with poly(3-hexylthiophene) for highly efficient polymer solar cells. Diam Relat Mater 41 (2014), 79–83.
242. [242] Lu, L., Xu, T., Chen, W., Lee, J.M., Luo, Z., Jung, I.H., et al. The role of N-doped multiwall carbon nanotubes in achieving highly efficient polymer bulk heterojunction solar cells. Nano Lett 13 (2013), 2365–2369.
243. [243] Chaudhary, S., Lu, H., Müllerr, A.M., Bardeen, C.J., Ozkan, M., Hierarchical placement and associated optoelectronic impact of carbon nanotubes in polymer-fullerene solar cells. Nano Lett 7 (2007), 1973–1979.
244. [244] Dabera, G.d.m.r., Jayawardena, K.d.g.i., Prabhath, M.r.r., Yahya, I., Tan, Y.Y., Nismy, N.A., et al. Hybrid carbon nanotube networks as efficient hole extraction layers for organic photovoltaics. ACS Nano 7 (2013), 556–565.
245. [245] Cho, D.Y., Eun, K., Choa, S.H., Kim, H.K., Highly flexible and stretchable carbon nanotube network electrodes prepared by simple brush painting for cost-effective flexible organic solar cells. Carbon 66 (2014), 530–538.
246. [246] Tenent, R.C., Barnes, T.M., Bergeson, J.D., Ferguson, A.J., To, B., Gedvilas, L.M., et al. Ultrasmooth, large-area, high-uniformity, conductive transparent single-walled-carbon-nanotube films for photovoltaics produced by ultrasonic spraying. Adv Mater 21 (2009), 3210–3216.
247. [247] Liu, Z., Liu, Q., Huang, Y., Ma, Y., Yin, S., Zhang, X., et al. Organic photovoltaic devices based on a novel acceptor material: graphene. Adv Mater 20 (2008), 3924–3930.
248. [248] Wang, H., He, D., Wang, Y., Liu, Z., Wu, H., Wang, J., Organic photovoltaic devices based on graphene as an electron-acceptor material and P3OT as a donor material. Phys Status Solidi A 208 (2011), 2339–2343.
249. [249] Yu, D., Park, K., Durstock, M., Dai, L., Fullerene-grafted graphene for efficient bulk heterojunction polymer photovoltaic devices. J Phys Chem Lett 2 (2011), 1113–1118.
250. [250] Sookhakian, M., Amin, Y.M., Baradaran, S., Tajabadi, M.T., Golsheikh, A.M., Basirun, W.J., A layer-by-layer assembled graphene/zinc sulfide/polypyrrole thin-film electrode via electrophoretic deposition for solar cells. Thin Solid Films 552 (2014), 204–211.
251. 2 composite layer as optical spacer in polymer bulk heterojunction solar cells. Org Electron 15 (2014), 348–355.
252. [252] Wang, D.H., Kim, J.K., Seo, J.H., Park, I., Hong, B.H., Park, J.H., et al. Transferable graphene oxide by stamping nanotechnology: electron-transport layer for efficient bulk-heterojunction solar cells. Angew Chem Int Ed 52 (2013), 2874–2880.
253. [253] Yeo, J.S., Yun, J.M., Jung, Y.S., Kim, D.Y., Noh, Y.J., Kim, S.S., et al. Sulfonic acid-functionalized, reduced graphene oxide as an advanced interfacial material leading to donor polymer-independent high-performance polymer solar cells. J Mater Chem A 2 (2013), 292–298.
254. [254] Sahoo, N.G., Pan, Y., Li, L., Chan, S.H., Graphene-based materials for energy conversion. Adv Mater 24 (2012), 4203–4210.
255. [255] Lee, R.H., Huang, J.L., Chi, C.H., Conjugated polymer-functionalized graphite oxide sheets thin films for enhanced photovoltaic properties of polymer solar cells. J Polym Sci B Polym Phys 51 (2013), 137–148.
256. [256] Wang, Y., Tong, S.W., Xu, X.F., Özyilmaz, B., Loh, K.P., Interface engineering of layer-by-layer stacked graphene anodes for high-performance organic solar cells. Adv Mater 23 (2011), 1514–1518.
257. [257] Wang, Z., Puls, C.P., Staley, N.E., Zhang, Y., Todd, A., Xu, J., et al. Technology ready use of single layer graphene as a transparent electrode for hybrid photovoltaic devices. Physica E 44 (2011), 521–524.
258. [258] Cox, M., Gorodetsky, A., Kim, B., Kim, K.S., Jia, Z., Kim, P., et al. Single-layer graphene cathodes for organic photovoltaics. Appl Phys Lett, 98, 2011 123303/1-3.
259. [259] Lee, Y.Y., Tu, K.H., Yu, C.C., Li, S.S., Hwang, J.Y., Lin, C.C., et al. Top laminated graphene electrode in a semitransparent polymer solar cell by simultaneous thermal annealing/releasing method. ACS Nano 5 (2011), 6564–6570.
260. [260] Pumera, M., Graphene-based nanomaterials for energy storage. Energy Environ Sci 4 (2010), 668–674.
261. [261] Sheng, K., Sun, Y., Li, C., Yuan, W., Shi, G., Ultrahigh-rate supercapacitors based on eletrochemically reduced graphene oxide for ac line-filtering. Sci Rep, 2, 2012 247/1-5.
262. [262] Sun, Y., Shi, G., Graphene/polymer composites for energy applications. J Polym Sci B Polym Phys 51 (2013), 231–253.
263. [263] Pieta, P., Obraztsov, I., D'Souza, F., Kutner, W., Composites of conducting polymers and various carbon nanostructures for electrochemical supercapacitors. ECS J Solid State Sci Technol 2 (2013), M3120–34.
264. [264] Ye, T., Kuang, Y., Xie, C., Huang, Z., Zhang, C., Shan, D., et al. Enhanced performance by polyaniline/tailored carbon nanotubes composite as supercapacitor electrode material. J Appl Polym Sci. 131 (2014), 39971–39979.
265. [265] Fan, H., Wang, H., Zhao, N., Zhang, X., Xu, J., Hierarchical nanocomposite of polyaniline nanorods grown on the surface of carbon nanotubes for high-performance supercapacitor electrode. J Mater Chem 22 (2011), 2774–2780.
266. [266] Lin, H., Li, L., Ren, J., Cai, Z., Qiu, L., Yang, Z., et al. Conducting polymer composite film incorporated with aligned carbon nanotubes for transparent, flexible and efficient supercapacitor. Sci Rep, 3, 2013 1353/1-6.
267. 3+ codoped polyaniline/MWCNTs nanocomposite: superior electrode material for supercapacitor application. Appl Surf Sci 276 (2013), 120–128.
268. [268] Giri, S., Ghosh, D., Malas, A., Das, C.K., A facile synthesis of a palladium-doped polyaniline-modified carbon nanotube composites for supercapacitors. J Electron Mater 42 (2013), 2595–2605.
269. [269] Bavio, M.A., Acosta, G.G., Kessler, T., Synthesis and characterization of polyaniline and polyaniline-carbon nanotubes nanostructures for electrochemical supercapacitors. J Power Sources 245 (2014), 475–481.
270. [270] Sun, X., Xu, Y., Wang, J., Mao, S., The composite film of polypyrrole and functionalized multi-walled carbon nanotubes as an electrode material for supercapacitors. Int J Electrochem Sci 7 (2012), 3205–3214.
271. [271] Dhibar, S., Sahoo, S., Das, C.K., Fabrication of transition-metal-doped polypyrrole/multiwalled carbon nanotubes nanocomposites for supercapacitor applications. J Appl Polym Sci 130 (2013), 554–562.
272. [272] Paul, S., Choi, K.S., Lee, D.J., Sudhagar, P., Kang, Y.S., Factors affecting the performance of supercapacitors assembled with polypyrrole/multi-walled carbon nanotube composite electrodes. Electrochim Acta 78 (2012), 649–655.
273. [273] Zhang, D., Dong, Q.Q., Wang, X., Yan, W., Deng, W., Shi, L.Y., Preparation of a three-dimensional ordered macroporous carbon nanotube/polypyrrole composite for supercapacitors and diffusion modeling. J Phys Chem C 117 (2013), 20446–20455.
274. [274] Abdiryim, T., Ubul, A., Jamal, R., Xu, F., Rahman, A., Electrochemical properties of the poly(3,4-ethylenedioxythiophene)/single-walled carbon nanotubes composite synthesized by solid-state heating method. Synth Met 162 (2012), 1604–1608.
275. [275] Kim, M., Lee, C., Jang, J., Fabrication of highly flexible, scalable, and high-performance supercapacitors using polyaniline/reduced graphene oxide film with enhanced electrical conductivity and crystallinity. Adv Funct Mater 24 (2014), 2489–2499.
276. [276] Giri, S., Ghosh, D., Das, C.K., In situ synthesis of cobalt doped polyaniline modified graphene composites for high performance supercapacitor electrode materials. J Electroanal Chem 697 (2013), 32–45.
277. [277] Liu, Y., Ma, Y., Guang, S., Xu, H., Su, X., Facile fabrication of three-dimensional highly ordered structural polyaniline-graphene bulk hybrid materials for high performance supercapacitor electrodes. J Mater Chem A 2 (2014), 813–823.
278. [278] Yu, P., Li, Y., Zhao, X., Wu, L., Zhang, Q., In situ growth of ordered polyaniline nanowires on surfactant stabilized exfoliated graphene as high-performance supercapacitor electrodes. Synth Met, 2013, 185–186 89–95.
279. [279] Lai, L., Wang, L., Yang, H., Sahoo, N.G., Tam, Q.X., Liu, J., et al. Tuning graphene surface chemistry to prepare graphene/polypyrrole supercapacitors with improved performance. Nano Energy 1 (2012), 723–731.
280. [280] Mini, P.A., Balakrishnan, A., Nair, S.V., Subramanian, K.R.V., Highly super capacitive electrodes made of graphene/poly(pyrrole). Chem Commun 47 (2011), 5753–5755.
281. [281] Li, J., Xie, H., Li, Y., Fabrication of graphene oxide/polypyrrole nanowire composite for high performance supercapacitor electrodes. J Power Sources 241 (2013), 388–395.
282. [282] Shen, J., Yang, C., Li, X., Wang, G., High-performance asymmetric supercapacitor based on nanoarchitectured polyaniline/graphene/carbon nanotube and activated graphene electrodes. ACS Appl Mater Interfaces 5 (2013), 8467–8476.
283. [283] Lu, X., Zhang, F., Dou, H., Yuan, C., Yang, S., Hao, L., et al. Preparation and electrochemical capacitance of hierarchical graphene/polypyrrole/carbon nanotube ternary composites. Electrochim Acta 69 (2012), 160–166.
284. [284] Ohzuku, T., Brodd, R.J., An overview of positive-electrode materials for advanced lithium-ion batteries. J Power Sources 174 (2007), 449–456.
285. [285] Lee, H., Yoo, J.K., Park, J.H., Kim, J.H., Kang, K., Jung, Y.S., A stretchable polymer-carbon nanotube composite electrode for flexible lithium-ion batteries: porosity engineering by controlled phase separation. Adv Energy Mater 2 (2012), 976–982.
286. [286] Wang, Z.L., Xu, D., Wang, H.G., Wu, Z., Zhang, X.B., In situ fabrication of porous graphene electrodes for high-performance energy storage. ACS Nano 7 (2013), 2422–2430.
287. [287] Mahmood, N., Zhang, C., Yin, H., Hou, Y., Graphene-based nanocomposites for energy storage and conversion in lithium batteries, supercapacitors and fuel cells. J Mater Chem A 2 (2014), 15–32.
288. [288] Xue, D.J., Xin, S., Yan, Y., Jiang, K.C., Yin, Y.X., Guo, Y.G., et al. Improving the electrode performance of Ge through Ge@C core-shell nanoparticles and graphene networks. J Am Chem Soc 134 (2012), 2512–2515.
289. [289] Reddy, A.l.m., Srivastava, A., Gowda, S.R., Gullapalli, H., Dubey, M., Ajayan, P.M., Synthesis of nitrogen-doped graphene films for lithium battery application. ACS Nano 4 (2010), 6337–6342.
290. [290] Pan, D.Y., Wang, S., Zhao, B., Wu, M., Zhang, H., Wang, Y., et al. Li storage properties of disordered graphene nanosheets. Chem Mater 21 (2009), 3136–3142.
291. [291] Wang, G., Shen, X., Yao, J., Park, J., Graphene nanosheets for enhanced lithium storage in lithium ion batteries. Carbon 47 (2009), 2049–2053.
292. [292] Gerouki, A., Goldner, M.A., Goldner, R.B., Haas, T.E., Liu, T.Y., Slaven, T.Y., Density of states calculations of small diameter single graphene sheets. J Electrochem Soc 143 (1996), L262–3.
293. [293] Sun, Y., Wu, Q., Shi, G., Graphene based new energy materials. Energy Environ Sci 4 (2011), 1113–1132.
294. [294] Song, Z., Xu, T., Gordin, M.L., Jiang, Y.B., Bae, I.T., Xiao, Q., et al. Polymer-graphene nanocomposites as ultrafast-charge and-discharge cathodes for rechargeable lithium batteries. Nano Lett 12 (2012), 2205–2211.
295. [295] Moon, S., Jung, Y.H., Kim, D.K., Enhanced electrochemical performance of a crosslinked polyaniline-coated graphene oxide-sulfur composite for rechageable lithium-sulfur batteries. J Power Sources 294 (2015), 386–392.
296. [296] Zhang, Y., Zhao, Y., Konarov, A., Gosselink, D., Soboleski, H.G., Chen, P., A novel nano-sulfur/polypyrrole/graphene nanocomposite cathode with a dual-layered structure for lithium rechargeable batteries. J Power Sources 241 (2013), 517–521.
297. 2/graphene composites with excellent electrochemical performances for lithium ion batteries. ACS Nano 5 (2011), 4720–4728.
298. 4-graphene nanocomposite as an anode material for lithium-ion batteries. Electrochim Acta 56 (2010), 834–840.
299. 4 nanoparticles with 3D laminated structure as superior anode in lithium ion batteries. Chem Eur J 17 (2011), 661–667.
300. 4-graphene nanocomposites for Li ion battery anodes. Chem Commun 47 (2011), 10371–10373.
301. 4 nanospheres for enhanced lithium storage. Adv Mater 25 (2013), 2909–2914.
302. 4 nanorods on graphene for lithium ion batteries with high rate capacity and cycle stability. Electrochem Commun 28 (2013), 139–142.
303. [303] Yang, S.B., Feng, X.L., Ivanovici, S., Mullen, K., Fabrication of graphene-encapsulated oxide nanoparticles: towards high-performance anode materials for lithium storage. Angew Chem Int Ed 49 (2010), 8408–8411.
304. 4/graphene hybrid anode for lithium rechargeable batteries. Carbon 49 (2011), 326–332.
305. 4 composite microspheres for high-performance lithium ion batteries. J Mater Chem 22 (2012), 17278–17283.
306. 2-graphene hybrid nanostructures for enhanced Li-ion insertion. ACS Nano 3 (2009), 907–914.
307. [307] Yang, S.B., Feng, X.L., Müllen, K., Sandwich-like, graphene-based titania nanosheets with high surface area for fast lithium storage. Adv Mater 23 (2011), 3575–3579.
308. 2@reduced graphene oxide nanocomposites for lithium ion batteries. J Mater Chem 22 (2012), 9759–9766.
309. 2 nanoparticles on graphene for high-performance lithium ion batteries. J Am Chem Soc 135 (2013), 18300–18303.
310. 2-coated three-dimensional graphene networks for high-performance anode material in lithium-ion batteries. Small 9 (2013), 3433–3438.
311. 2/graphene composites: cationic surfactant-assisted hydrothermal synthesis and electrochemical reversible storage of lithium. Small 9 (2013), 3693–3703.
312. 2 nanosheets incorporated into hierarchical porous carbon for lithium-ion batteries. Chem Eng J, 2016, 179–184.
313. x/graphene hydrogel composite anode for lithium-ionbattery. J Power Sources 306 (2016), 42–48.
314. [314] Jiang, H., Zhou, X., Liu, G., Zhou, Y., Ye, H., Liu, Y., et al. Free-standing Si/graphene paper using Si nanoparticles synthesized by acid-etching Al-Si alloy powder for high-stability Li-ion battery anodes. Electrochim Acta 188 (2016), 777–784.
315. 2 pillared carbon using long chain alkylamine grafted graphene oxide: an efficient anode material for lithium ion batteries. Nanoscale 8 (2016), 471–482.
316. [316] Binitha, G., Ashish, A.G., Ramasubramonian, D., Manikandan, P., 3D interconnected networks of graphene and flower-like cobalt oxide microstructures with improved lithium storage. Adv Mater Interfaces, 3, 2016 1500419/1-9.
317. 3 supported by graphene and carbon-nanofibers for advanced Li-ion batteries. Mater Res Bull 73 (2016), 211–218.
318. [318] Sun, W., Hu, R., Zhang, H., Wang, Y., Yang, L., Liu, J., et al. A long-life nano-silicon anode for lithium ion batteries: supporting of graphene nanosheets exfoliated from expanded graphite by plasma-assisted milling. Electrochim Acta 187 (2016), 1–10.
319. 29/reduced graphene oxide composites with enhanced lithium storage capability. J Power Sources 300 (2015), 272–278.
320. [320] Wang, X., Huang, Y., Jia, D., Pang, W.K., Guo, Z., Du, Y., et al. Self-assembled sandwich-like vanadium oxide/graphene mesoporous composite as high-capacity anode material for lithium ion batteries. Inorg Chem 54 (2015), 11799–11806.
321. 4/N-doped graphene nanosheets with robust chemical interaction for superior lithium storage. Nanotechnology, 27, 2015 045405/1-10.
322. [322] Ding, Y.L., Wu, C., Kopold, P., van Aken, P.A., Maier, J., Yu, Y., Graphene-protected 3D Sb-based anodes fabricated via electrostatic assembly and confinement replacement for enhanced lithium and sodium storage. Small 11 (2015), 6026–6035.
323. [323] Guo, G.C., Wang, D., Wei, X.L., Zhang, Q., Liu, H., Lau, W.M., et al. First-principles study of phosphorene and graphene heterostructure as anode materials for rechargeable Li batteries. J Phys Chem Lett 6 (2015), 5002–5008.
324. 4 nanowire arrays supported on macroporous graphene foam as binder-free 3D anodes for high-performance lithium storage. Phys Chem Chem Phys 18 (2016), 908–915.
325. 2-quantum-dots-anchored graphene nanosheets as superior-capability anode for lithium-ion batteries. Electrochim Acta 182 (2015), 424–429.
326. [326] Kammoun, M., Berg, S., Ardebili, H., Flexible thin-film battery based on graphene-oxide embedded in solid polymer electrolyte. Nanoscale 7 (2015), 17516–17522.
327. [327] Chen, S., Chen, P., Wu, M., Pan, D., Wang, Y., Graphene supported Sn-Sb@carbon core-shell particles as a superior anode for lithium ion batteries. Electrochem Commun 12 (2010), 1302–1306.
328. [328] Wang, D., Li, X., Yang, J., Wang, J., Geng, D., Li, R., et al. Hierarchical nanostructured core-shell Sn@C nanoparticles embedded in graphene nanosheets: spectroscopic view and their application in lithium ion batteries. Phys Chem Chem Phys 15 (2013), 3535–3542.
329. [329] Wang, G., Wang, B., Wang, X., Park, J., Dou, S., Ahn, H., et al. Sn/graphene nanocomposite with 3D architecture for enhanced reversible lithium storage in lithium ion batteries. J Mater Chem 19 (2009), 8378–8384.
330. [330] Chen, S.Q., Wang, Y., Ahn, H., Wang, G.X., Microwave hydrothermal synthesis of high performance tin-graphene nanocomposites for lithium ion batteries. J Power Sources 216 (2012), 22–27.
331. [331] Beck, F.R., Epur, R., Hong, D.H., Manivannan, A., Kumta, A.N., Microwave derived facile approach to Sn/graphene composite anodes for lithium-ion batteries. Electrochim Acta 127 (2014), 299–306.
332. [332] Ji, L., Tan, Z., Kuykendall, T., An, E.J., Fu, Y., Battaglia, V., et al. Multilayer nanoassembly of Sn-nanopillar arrays sandwiched between graphene layers for high-capacity lithium storage. Energy Environ Sci 4 (2011), 3611–3616.
333. 4/carbon nanotubes composite with enhanced electrochemical performance as anode materials for lithium-ion batteries. Mater Lett 164 (2016), 44–47.
334. 4 with a novel porous polyhedral structure as anodes for lithium ion batteries with improved performances. J Alloys Compd 654 (2016), 586–592.
335. [335] Zhang, X.L., Wang, T., Jiang, C.L., Zhang, F., Li, W.Y., Tang, Y.B., Manganese dioxide/cabon nanotubes composite with optimized microstructure via room temperature solution approach for high performance lithium-ion battery anodes. Electrochim Acta 187 (2016), 465–472.
336. [336] Yuan, D., Cheng, J., Qu, G., Li, X., Ni, W., Wang, B., et al. Amorphous red phosphorous embedded in carbon nanotubes scaffold as promising anode materials for lithium-ion batteries. J Power Sources 301 (2016), 131–137.
337. [337] Khan, I.A., Nasim, F., Choucair, M., Ullah, S., Badshah, A., Nadeem, M.A., Cobalt oxide nanoparticle embedded N-CNTs: lithium ion battery applications. RSC Adv 5 (2016), 1129–1135.
338. [338] Jiang, X., Yu, W., Wang, H., Xu, H., Liu, X., Ding, Y., Enhancing the performance of MnO by double carbon modification for advanced lithium-ion battery anodes. J Mater Chem A 4 (2016), 920–925.
339. [339] Ye, M., Hu, C., Lv, L., Qu, L., Graphene-winged carbon nanotubes as high-performance lithium-ion batteries anode with super-long cycle life. J Power Sources 305 (2016), 106–114.
340. [340] Li, X., Gittleson, F., Carmo, M., Sekol, R.C., Taylor, A.D., Scalable fabrication of multifunctional freestanding carbon nanotube/polymer composite thin films for energy conversion. ACS Nano 6 (2012), 1347–1356.
341. [341] Sivakkumer, S.R., Kim, D.W., Polyaniline/carbon nanotube composite cathode for rechargeable lithium polymer batteries assembled with gel polymer electrolyte. J Electrochem Soc 154 (2007), A134–9.
342. [342] Wu, H., Wang, K., Meng, Y., Lua, K., Wei, Z., An organic cathode material based on a polyimide/CNT nanocomposite for lithium ion batteries. J Mater Chem A 1 (2013), 6366–6372.
343. [343] Lia, H., Chena, Y.M., Maa, X.T., Shia, J.L., Zhua, B.K., Zhua, L.P., Gel polymer electrolytes based on active PVDF separator for lithium ion battery. I: preparation and property of PVDF/poly(dimethylsiloxane) blending membrane. J Memb Sci 379 (2011), 397–402.
344. [344] Sivakkumar, S.R., Howlett, P.C., Winther-Jensen, B., Forsyth, M., MacFarlane, D.R., Polyterthiophene/CNT composite as a cathode material for lithium batteries employing an ionic liquid electrolyte. Electrochim Acta 54 (2009), 6844–6849.
345. 4/carbon nanotube composites as anodes for lithium ion batteries. Electrochim Acta 55 (2010), 1140–1144.
346. [346] Dileo, R.A., Castiglia, A., Ganter, M.J., Rogers, R.E., Cress, C.D., Raffaelle, R.P., et al. Enhanced capacity and rate capability of carbon nanotube based anodes with titanium contacts for lithium ion batteries. ACS Nano 4 (2010), 6121–6131.
347. 12/carbon nano-tubes for lithium ion battery. Electrochim Acta 53 (2008), 7756–7759.
348. [348] Wei, W., Wang, J., Zhou, L., Yang, J., Schumann, B., NuLi, Y., CNT enhanced sulfur composite cathode material for high rate lithium battery. Electrochem Commun 13 (2011), 399–402.
349. [349] Zhou, G., Li, F., Cheng, H.M., Progress in flexible lithium batteries and future prospects. Energy Environ Sci 7 (2014), 1307–1338.
350. 4/graphene hybrids. J Power Sources 255 (2014), 170–178.
351. [351] He, Y., Chen, W., Gao, C., Zhou, J., Li, X., Xie, E., An overview of carbon materials for flexible electrochemical capacitors. Nanoscale 5 (2013), 8799–8820.
352. [352] Cao, Q., Kim, H.S., Pimparkar, N., Kulkarni, J.P., Wang, C., Shim, M., et al. Medium-scale carbon nanotube thin-film integrated circuits on flexible plastic substrates. Nature 454 (2008), 495–500.
353. [353] Jung, M., Kim, J., Noh, J., Lim, N., Lim, C., Lee, G., et al. All-printed and roll-to-roll-printable 13.56-MHz-operated 1-bit RF tag on plastic foils. IEEE Trans Electron Dev 57 (2010), 571–580.
354. [354] Gelinck, G.H., Huitema, H.e.a., Veenendaal, E.V., Cantatore, E., Schrijnemakers, L., van der Putten, J.b.h., et al. Flexible active-matrix displays and shift registers based on solution-processed organic transistors. Nat Mater 3 (2004), 106–110.
355. [355] Lipomi, D.J., Tee, B.c.k., Vosgueritchian, M., Bao, Z., Stretchable organic solar cells. Adv Mater 23 (2011), 1771–1775.
356. [356] Rogers, J.A., Bao, Z., Baldwin, K., Dodabalapur, A., Crone, B., Raju, V.R., et al. Paper-like electronic displays: large-area rubber-stamped plastic sheets of electronics and microencapsulated electrophoretic inks. Proc Natl Acad Sci U S A 98 (2001), 4835–4840.
357. [357] Bae, S., Kim, H., Lee, Y., Xu, X., Park, J.S., Zheng, Y., et al. Roll-to-roll production of 30-inch graphene films for transparent electrodes. Nat Nanotechnol 5 (2010), 574–578.
358. [358] Snow, E.S., Perkins, F.K., Houser, E.J., Badescu, S.C., Reinecke, T.L., Chemical detection with a single-walled carbon nanotube capacitor. Science 307 (2005), 1942–1945.
359. [359] Kauffman, D.R., Star, A., Electronically monitoring biological interactions with carbon nanotub field-effect transistors. Chem Soc Rev 37 (2008), 1197–1206.
360. [360] Kymakis, E., Savva, K., Stylianakis, M.M., Fotakis, C., Stratakis, E., Flexible organic photovoltaic cells with in-situ non-thermal photoreduction of spin coated graphene oxide. Adv Funct Mater 23 (2013), 2742–2749.
361. [361] Dikin, D.A., Stankovich, S., Zimney, E.J., Piner, R.D., Dommett, G.h.b., Evmenenko, G., et al. Preparation and characterization of graphene oxide paper. Nature 448 (2007), 457–460.
362. [362] Wang, X., Shi, G., Flexible graphene devices related to energy conversion and storage. Energy Environ Sci 8 (2015), 790–823.
363. [363] Xiang, X., Young, C.C., Wang, X., Yan, J., Hwang, C.C., Cerioti, G., et al. Large flake graphene oxide fibers with unconventional 100% knot efficiency and highly aligned small flake graphene oxide fibers. Adv Mater 25 (2013), 4592–4597.
364. [364] Jalili, R., Aboutalebi, S.H., Esrafilzadeh, D., Shepherd, R.L., Chen, J., Aminorroaya-Yamini, S., et al. Scalable one-step wet-spinning of graphene fibers and yarns from liquid crystalline dispersions of graphene oxide: towards multifunctional textiles. Adv Funct Mater 23 (2013), 5345–5354.
365. [365] Kou, L., Gao, C., Bioinspired design and macroscopic assembly of poly(vinyl alcohol)-coated graphene into kilometers-long fibers. Nanoscale 5 (2013), 4370–4378.
366. 2 nanostructured sponges as high performance supercapacitor electrodes. Nano Energy 2 (2013), 505–513.
367. 2-carbon nanotube-graphene-Ni hybrid foam as a binder-free supercapacitor electrode. Nanoscale 6 (2014), 1079–1085.
368. [368] Worsley, M.A., Pauzauskie, P.J., Olson, T.Y., Biener, J., Satcher, J.H., Baumann, T.F., Synthesis of graphene aerogel with high electrical conductivity. J Am Chem Soc 132 (2010), 14067–14069.
369. [369] Xu, Z., Zhang, Y., Li, P., Gao, C., Strong, conductive, lightweight, neat graphene aerogel fibers with aligned pores. ACS Nano 6 (2012), 7103–7113.
370. [370] Kwak, Y.H., Choi, D.S., Kim, Y.N., Kim, H., Yoon, D.H., Ahn, S.S., et al. Flexible glucose sensor using CVD-grown graphene-based field effect transistor. Biosens Bioelectron 37 (2012), 82–87.
371. [371] Huang, L., Guo, G., Liu, Y., Chang, Q., Shi, W., Synthesis of reduced graphene oxide/ZnO nanorods composites on graphene coated PET flexible substrates. Mater Res Bull 48 (2013), 4163–4167.
372. [372] Cong, H.P., Ren, X.C., Wang, P., Yu, S.H., Flexible graphene-polyaniline composite paper for high performance supercapacitor. Energy Environ Sci 6 (2013), 1185–1191.
373. [373] Wang, X.L., Bai, H., Yao, Z.Y., Liu, A.R., Shi, G.Q., Electrically conductive and mechanically strong biomimetic chitosan/reduced graphene oxide composite films. J Mater Chem 20 (2010), 9032–9036.
374. [374] X, Dong, Y, Ma, G, Zhu, Wang, J., B, Chan-Park, Wang, L., et al. Synthesis of graphene-carbon nanotube hybrid foam and its use as a novel three-dimensional electrode for electrochemical sensing. J Mater Chem 22 (2012), 17044–17048.
375. [375] Huang, L., Li, C., Shi, G.Q., High-performance and flexible electrochemical capacitors based on graphene/polymer composite films. J Mater Chem A 2 (2014), 968–974.
376. [376] Huang, Z.D., Liang, R., Zhang, B., He, Y.B., Kim, J.K., Evolution of flexible 3D graphene oxide/carbon nanotube/polyaniline composite papers and their supercapacitive. Compos Sci Technol 88 (2013), 126–133.
377. [377] Zhu, Y., Sun, Z., Yan, Z., Jin, Z., Tour, J.M., Rational design of hybrid graphene films for high-performance transparent electrodes. ACS Nano 5 (2011), 6472–6479.
378. [378] Xiang, J., Drzal, L.T., Improving thermoelectric properties of graphene/polyaniline paper by folding. Chem Phys Lett 593 (2014), 109–114.
379. [379] Liu, A.R., Yuan, W.J., Shi, G.Q., Electrochemical actuator based on polypyrrole/sulfonated graphene/graphene tri-layer film. Thin Solid Films 520 (2012), 6307–6312.
380. [380] Li, N., Oida, S., Tulevski, G.S., Han, S., Hannon, J.B., Sadana, D.K., et al. Efficient and bright organic light-emitting diodeson single-layer graphene electrodes. Nat Commun 4 (2013), 2294–2298.
381. [381] Wu, Q., Xu, Y., Yao, Z., Liu, A., Shi, G., Supercapacitors based on flexible graphene/polyaniline nanofiber composite films. ACS Nano 4 (2010), 1963–1970.
382. [382] Liu, J., Zhang, L., Wu, H.B., Lin, J., Shen, Z., Lou, X.W., High-performance flexible asymmetric supercapacitors based on a new graphene foam/carbon nanotube hybrid film. Energy Environ Sci 7 (2014), 3709–3719.
383. [383] Kwon, O.S., Park, S.J., Hong, J.Y., Han, A.R., Lee, J.S., Lee, J.S., et al. Flexible FET-type VEGF aptasensor based on nitrogen-doped graphene converted from conducting polymer. ACS Nano 6 (2012), 1486–1493.
384. [384] Yin, Z., Sun, S., Salim, T., Wu, S., Huang, X., He, Q., et al. Organic photovoltaic devices using highly flexible reduced graphene oxide films as transparent electrodes. ACS Nano 4 (2010), 5263–5268.
385. [385] Han, T.H., Lee, Y., Choi, M.R., Woo, S.H., Bae, S.H., Hong, B.H., et al. Extremely efficient flexible organic light-emitting diodes with modified graphene anode. Nat Photonics 6 (2012), 105–110.
386. [386] Zhai, P., Chang, Y.H., Huang, Y.T., Wei, T.C., Su, H., Feng, S.P., Water-soluble microwave-exfoliated graphene nanosheet/platinum nanoparticle composite and its application in dye-sensitized solar cells. Electrochim Acta 132 (2014), 186–192.
387. [387] Hong, W., Xu, Y., Lu, G., Li, C., Shi, G., Transparent graphene/PEDOT-PSS composite films as counter electrodes of dye-sensitized solar cells. Electrochem Commun 10 (2008), 1555–1558.
388. [388] Lee, K.S., Lee, Y., Lee, J.Y., Ahn, J.H., Park, J.H., Flexible and platinum-free dye-sensitized solar cells with conducting-polymer-coated graphene counter electrodes. ChemSusChem 5 (2012), 379–382.
389. [389] Roy-Mayhew, J.D., Bozym, D.J., Punckt, C., Aksay, I.A., Functionalized graphene as a catalytic counter electrode in dye-sensitized solar cells. ACS Nano 4 (2010), 6203–6211.
390. [390] Liu, W., Yan, X., Lang, J., Peng, C., Xue, Q., Flexible and conductive nanocomposite electrode based on graphene sheets and cotton cloth for supercapacitor. J Mater Chem 22 (2012), 17245–17253.
391. [391] Weng, Z., Su, Y., Wang, D.W., Li, F., Du, J., Cheng, H.M., Graphene-cellulose paper flexible supercapacitors. Adv Energy Mater 1 (2011), 917–922.
392. [392] Wang, S., Dryfe, R.A.W., Graphene oxide-assisted deposition of carbon nanotubes on carbon cloth as advanced binder-free electrodes for flexible supercapacitors. J Mater Chem A 1 (2013), 5279–5283.
393. [393] Aboutalebi, S.H., Jalili, R., Esrafilzadeh, D., Salari, M., Gholamvand, Z., Yamini, S.A., et al. High-performance multifunctional graphene yarns: toward wearable all-carbon energy storage textiles. ACS Nano 8 (2014), 2456–2466.
394. [394] Javey, A., Kim, H., Brink, M., Wang, Q., Ural, A., Guo, J., et al. High-kappa dielectrics for advanced carbon-nanotube transistors and logic gates. Nat Mater 1 (2002), 241–246.
395. [395] Seidel, R., Graham, A.P., Unger, E., Duesberg, G.S., Liebau, M., Steinhoegl, W., et al. High-current nanotube transistors. Nano Lett 4 (2004), 831–834.
396. [396] Zhou, Y., Gaur, A., Hur, S.H., Kocabas, C., Meitl, M.A., Shim, M., et al. p-Channel, n-channel thin Film transistors and p-n diodes based on single wall carbon nanotube networks. Nano Lett 4 (2004), 2031–2035.
397. [397] Chimot, N., Derycke, V., Goffman, M.F., Bourgoin, J.P., Happy, H., Dambrine, G., Gigahertz frequency flexible carbon nano transistors. Appl Phys Lett, 91, 2007 153111/1-3.
398. [398] Tseng, S.H., Tai, N.H., Fabrication of a transparent and flexible thin film transistor based on single-walled carbon nanotubes using the direct transfer method. Appl Phys Lett, 95, 2009 204104/1-3.
399. [399] Sun, D., Timmermans, M.Y., Tian, Y., Nasibulin, A.G., Kauppinen, E.I., Kishimoto, S., et al. Flexible high-performance carbon nanotube integrated circuits. Nat Nanotechnol 6 (2011), 156–161.
400. [400] Takenobu, T., Takahashi, T., Kanbara, T., Tsukagoshi, K., Aoyagi, Y., Iwasa, Y., High-performance transparent flexible transistors using carbon nanotube films. Appl Phys Lett, 88, 2006 033511/1-3.
401. [401] Wang, C., Chien, J.C., Takei, K., Takahashi, T., Nah, J., Niknejad, A.M., et al. Extremely bendable, high-performance integrated circuits using semiconducting carbon nanotube networks for digital, analog, and radio-frequency applications. Nano Lett 12 (2012), 1527–1533.
402. [402] Vaillancourt, J., Zhang, H., Vasinajindakaw, P., Xia, H., Lu, X., Han, X., et al. All ink-jet-printed carbon nanotube thin-film transistor on a polyimide substrate with an ultrahigh operating frequency of over 5 GHz. Appl Phys Lett, 93, 2008 243301/1-3.
403. [403] Jiao, L., Fan, B., Xian, X., Wu, Z., Zhang, J., Liu, Z., Creation of nanostructures with poly(methyl methacrylate)-mediated nanotransfer printing. J Am Chem Soc 130 (2008), 12612–12613.
404. [404] Hur, S.H., Park, O.O., Rogers, J.A., Extreme bendability of single-walled carbon nanotube networks transferred from high-temperature growth substrates to plastic and their use in thin-film transistors. Appl Phys Lett, 86, 2005 243502/1-3.
405. [405] Meng, C., Liu, C., Fan, S., Flexible carbon nanotube/polyaniline paper-like films and their enhanced electrochemical properties. Electrochem Commun 11 (2009), 186–189.
406. [406] Lin, J.Y., Wang, W.Y., Chou, S.W., Flexible carbon nanotube/polypropylene composite plate decorated with poly(3,4-ethylenedioxythiophene) as efficient counter electrodes for dye-sensitized solar cells. J Power Sources 282 (2015), 348–357.
407. [407] Jeong, H.J., Jeong, H.D., Kim, H.Y., Kim, J.S., Jeong, S.Y., Han, J.T., et al. All-carbon nanotube-based flexible field-emission devices: from cathode to anode. Adv Funct Mater 21 (2011), 1526–1532.
408. [408] Kim, H.M., Kim, K., Lee, C.Y., Joo, J., Cho, S.J., Yoon, H.S., et al. Electrical conductivity and electromagnetic interference shielding of multiwalled carbon nanotube composites containing Fe catalyst. Appl Phys Lett 84 (2004), 589–591.
409. [409] Lammers, T., Aime, S., Hennink, W.E., Storm, G., Kiessling, F., Theranostic nanomedicine. Acc Chem Res 44 (2011), 1029–1038.
410. [410] Chou, L.y.t., Ming, K., Chan, W.C.W., Strategies for the intracellular delivery of nanoparticles. Chem Soc Rev 40 (2011), 233–245.
411. [411] Kostarelos, K., Lacerda, L., Pastorin, G., Wu, W., Wieckowski, S., Luangsivilay, J., et al. Cellular uptake of functionalized carbon nanotubes is independent of functional group and cell type. Nat Nano 2 (2007), 108–113.
412. [412] Liu, X., Chen, Y., Li, H., Huang, N., Jin, Q., Ren, K., et al. Enhanced retention and cellular uptake of nanoparticles in tumors by controlling their aggregation behavior. ACS Nano 7 (2013), 6244–6257.
413. [413] Vranic, S., Boggetto, N., Contremoulins, V., Mornet, S., Reinhardt, N., Marano, F., et al. Deciphering the mechanisms of cellular uptake of engineered nanoparticles by accurate evaluation of internalization using imaging flow cytometry. Part Fibre Toxicol, 10, 2013 2/1-16.
414. [414] Ali-Boucetta, H., Al-Jamal, K.T., McCarthy, D., Prato, M., Bianco, A., Kostarelos, K., Multiwalled carbon nanotube-doxorubicin supramolecular complexes for cancer therapeutics. Chem Commun, 2008, 459–461.
415. [415] Feazell, R.P., Nakayama-Ratchford, N., Dai, H., Lippard, S.J., Soluble single-walled carbon nanotubes as longboat delivery systems for platinum(IV) anticancer drug design. J Am Chem Soc 129 (2007), 8438–8439.
416. [416] Liu, Z., Robinson, J.T., Sun, X., Dai, H., PEGylated nanographene oxide for delivery of water-insoluble cancer drugs. J Am Chem Soc 130 (2008), 10876–10877.
417. [417] Liu, Z., Li, X., Tabakman, S.M., Jiang, K., Fan, S., Dai, H., Multiplexed multicolor raman imaging of live cells with isotopically modified single walled carbon nanotubes. J Am Chem Soc 130 (2008), 13540–13541.
418. [418] Wang, J., Carbon-nanotube based electrochemical biosensors: a review. Electroanalysis 17 (2005), 7–14.
419. [419] Kam, N.w.s., Liu, Z., Dai, H., Carbon nanotubes as intracellular transporters for proteins and DNA: an investigation of the uptake mechanism and pathway. Angew Chem Int Ed 45 (2006), 577–581.
420. [420] Thordarson, P., Droumaguet, B., Velonia, K., Well-defined protein-polymer conjugates—synthesis and potential applications. Appl Microbiol Biotechnol 73 (2006), 243–254.
421. [421] Roy, K., Mao, H.Q., Huang, S.K., Leong, K.W., Oral gene delivery with chitosan-DNA nanoparticles generates immunologic protection in a murine model of peanut allergy. Nat Med 5 (1999), 387–391.
422. [422] Panyam, J., Labhasetwar, V., Biodegradable nanoparticles for drug and gene delivery to cells and tissue. Adv Drug Deliv Rev 55 (2003), 329–347.
423. [423] Panyam, J., Zhou, W.Z., Prabha, S., Sahoo, S.K., Labhasetwar, V., Rapid endo-lysosomal escape of poly(dl-lactide-co-glycolide) nanoparticles: implications for drug and gene delivery. FASEB J 16 (2002), 1217–1226.
424. [424] Joshi, M., Pathak, S., Sharma, S., Patravale, V., Design and in vivo pharmacodynamic evaluation of nanostructured lipid carriers for parenteral delivery of artemether: nanoject. Int J Pharm 364 (2008), 119–126.
425. [425] Ku, S.H., Lee, M., Park, C.B., Carbon-based nanomaterials for tissue engineering. Adv Healthc Mater 2 (2013), 244–260.
426. [426] Kalbacova, M., Broz, A., Kalbac, M., Influence of the fetal bovine serum proteins on the growth of human osteoblast cells on graphene. J Biomed Mater Res A 100A (2012), 3001–3007.
427. [427] Ryu, S., Kim, B.S., Culture of neural cells and stem cells on graphene. Tissue Eng Regener Med 10 (2013), 39–46.
428. [428] Li, N., Zhang, X., Song, Q., Su, R., Zhang, Q., Kong, T., et al. The promotion of neurite sprouting and outgrowth of mouse hippocampal cells in culture by graphene substrates. Biomaterials 32 (2011), 9374–9382.
429. [429] Vashist, S.K., Zheng, D., Pastorin, G., Al-Rubeaan, K., Luong, J.h.t., Sheu, F.S., Delivery of drugs and biomolecules using carbon nanotubes. Carbon 49 (2011), 4077–4097.
430. [430] Bianco, A., Kostarelos, K., Partidos, C.D., Prato, M., Biomedical applications of functionalised carbon nanotubes. Chem Commun, 2005, 571–577.
431. [431] Banks, C.E., Crossley, A., Salter, C., Wilkins, S.J., Compton, R.G., Carbon nanotubes contain metal impurities which are responsible for the electrocatalysis seen at some nanotube-modified electrodes. Angew Chem Int Ed 45 (2006), 2533–2537.
432. [432] Yang, K., Zhang, S., Zhang, G., Sun, X., Lee, S.T., Liu, Z., Graphene in mice: ultrahigh in vivo tumor uptake and efficient photothermal therapy. Nano Lett 10 (2010), 3318–3323.
433. [433] Zhang, W., Guo, Z., Huang, D., Liu, Z., Guo, X., Zhong, H., Synergistic effect of chemo-photothermal therapy using PEGylated graphene oxide. Biomaterials 32 (2011), 8555–8561.
434. [434] Gillies, E.R., Fréchet, J.M., pH-responsive copolymer assemblies for controlled release of doxorubicin. Bioconjug Chem 16 (2005), 361–368.
435. [435] Lynch, D.R., Snyder, S.H., Neuropeptides: multiple molecular forms, metabolic pathways, and receptors. Annu Rev Biochem 55 (1986), 773–799.
436. [436] Depan, D., Shah, J., Misra, R.D.K., Controlled release of drug from folate-decorated and graphene mediated drug delivery system: synthesis, loading efficiency, and drug release response. Mater Sci Eng C 31 (2011), 1305–1312.
437. [437] Liu, G., Shen, H., Mao, J., Zhang, L., Jiang, Z., Sun, T., et al. Transferrin modified graphene oxide for glioma-targeted drug delivery: in vitro and in vivo evaluations. ACS Appl Mater Interfaces 5 (2013), 6909–6914.
438. [438] Hu, H., Yu, J., Li, Y., Zhao, J., Dong, H., Engineering of a novel pluronic F127/graphene nanohybrid for pH responsive drug delivery. J Biomed Mater Res A 100A (2012), 141–148.
439. [439] Wang, C., Li, J., Amatore, C., Chen, Y., Jiang, H., Wang, X.M., Gold nanoclusters and graphene nanocomposites for drug delivery and imaging of cancer cells. Angew Chem Int Ed 50 (2011), 11644–11648.
440. [440] Yang, X., Wang, Y., Huang, X., Ma, Y., Huang, Y., Yang, R., et al. Multi-functionalized graphene oxide based anticancer drug-carrier with dual-targeting function and pH-sensitivity. J Mater Chem 21 (2011), 3448–3454.
441. [441] Zhang, L., Xia, J., Zhao, Q., Liu, L., Zhang, Z., Functional graphene oxide as a nanocarrier for controlled loading and targeted delivery of mixed anticancer drugs. Small 6 (2010), 537–544.
442. [442] Liu, L.F., Desai, S.D., Li, T.K., Mao, Y., Sun, M., Sim, S.P., Mechanism of action of camptothecin. Ann N Y Acad Sci 922 (2000), 1–10.
443. [443] Kavitha, T., Kang, I.K., Park, S.Y., Poly(N-vinyl caprolactam) grown on nanographene oxide as an effective nanocargo for drug delivery. Colloids Surf B 115 (2014), 37–45.
444. [444] O'Donnell, S.E., Sprong, K.R., Haltli, B.M., Potential impact of carbon nanotube reinforced polymer composite on commercial aircraft performance and economics. Proc AIAA 4th Aviation Technology, Integration and Operations, 2004 2005-6402/1-10.
445. [445] Kireitseu, M., Hui, D., Tomlinson, G., Advanced shock-resistant and vibration damping of nanoparticle-reinforced composite material. Composites Part B 39 (2008), 128–138.
446. [446] Joshi, S.C., Dikshit, V., Enhancing interlaminar fracture characteristics of woven CFRP prepreg composites through CNT dispersion. J Compos Mater 46 (2011), 665–675.
447. [447] de Villoria, R.G., Ydrefors, L., Hallander, P., Ishiguro, K., Nordin, P., Wardle, B., Aligned carbon nanotube reinforcement of aerospace carbon fiber composites: substructural strength evaluation for aerostructure applications. Proc 53rd AIAA/ASME/ASCE/AHS/ASC Structures, 2012 2012-1566/1-7.
448. [448] Loos, M.R., Yang, J., Feke, D.L., Manas-Zloczower, I., Unal, S., Younes, U., Enhancement of fatigue life of polyurethane composites containing carbon nanotubes. Composites Part B 44 (2013), 740–744.
449. [449] Mannov, E., Schmutzler, H., Chandrasekaran, S., Viets, C., Buschhorn, S., Tölle, F., et al. Improvement of compressive strength after impact in fibre reinforced polymer composites by matrix modification with thermally reduced graphene oxide. Compos Sci Technol 87 (2013), 36–41.
450. [450] Balasubramanian, K., Reinforcement of poly ether sulphones (PES) with exfoliated graphene oxide for aerospace applications. IOP Conf Ser Mater Sci Eng, 40, 2012 012022/1-5.
451. [451] Kuilla, T., Bhadra, S., Yao, D., Kim, N.H., Bose, S., Lee, J.H., Recent advances in graphene based polymer composites. Prog Polym Sci 35 (2010), 1350–1375.