A three-dimensional nanostructure of graphite intercalated by carbon nanotubes with high cross-plane thermal conductivity and bending strength

Carbon

Volumn 77, Issue , 2014, Pages 1054-1064

  Feng, Wei ^a   Qin, Mengmeng ^a   Lv, Peng ^a   Li, Jianpeng ^a   Feng, Yiyu ^a  

^a TIANJIN UNIVERSITY   (China)

Author keywords

[No Author keywords available]

Indexed keywords

BENDING STRENGTH; CARBON NANOTUBES; CHEMICAL VAPOR DEPOSITION; GRAPHITE; INTERCALATION;

EXPANDED GRAPHITE; GRAPHITE LAYERS; LONG NANOTUBE; OPEN POROSITY; PULL-OUT EFFECTS; THREE-DIMENSIONAL NANOSTRUCTURES; VACUUM IMPREGNATION; WELL-DISPERSED;

THERMAL CONDUCTIVITY;

EID: 84905665306     PISSN: 00086223     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbon.2014.06.021     Document Type: Article

References (49)

1. M.T. Pettes, H.X. Ji, R.S. Ruoff, and L. Shi Thermal transport in three-dimensional foam architectures of few-layer graphene and ultrathin graphite Nano Lett 12 6 2012 2959 2964
2. J.K. Yu, S. Mitrovic, D. Tham, J. Varghese, and J.R. Heath Reduction of thermal conductivity in phononic nanomesh structures Nat Nanotechnol 5 2010 718 721
3. G.J. Snyder, and E.S. Toberer Complex thermoelectric materials Nat Mater 7 2008 105 114
4. G.M. Yuan, X.K. Li, Z.J. Dong, A. Westwood, Z.W. Cui, and Y. Cong et al. Graphite blocks with preferred orientation and high thermal conductivity Carbon 50 1 2012 175 182
5. Q.Z. Liang, X.X. Yao, W. Wang, Y. Liu, and C.P. Wong A three-dimensional vertically aligned functionalized multilayer graphene architecture: an approach for graphene-based thermal interfacial materials ACS Nano 5 3 2011 2392 2401
6. S. Chatterjee, F. Nafezarefi, N.H. Tai, L. Schlagenhauf, F.A. Nuesch, and B.T.T. Chu Size and synergy effects of nanofiller hybrids including graphene nanoplatelets and carbon nanotubes in mechanical properties of epoxy composites Carbon 50 15 2012 5380 5386
7. M. Wang, C.Y. Wang, T.Q. Li, and Z.J. Hu Preparation and characterization of mesophase-pitch-based foam/natural graphite composites Compos Sci Technol 68 11 2008 2220 2223
8. Z.H. Feng, T.Q. Li, Z.J. Hu, G.W. Zhao, J.S. Wang, and B.Y. Huang Low cost preparation of high thermal conductivity carbon blocks with ultra-high anisotropy from a commercial graphite paper Carbon 50 10 2012 3947 3948
9. Y. Zhao, Z.J. Liu, H.Q. Wang, J.L. Shi, J.C. Zhang, and Z.C. Tao et al. Microstructure and thermal/mechanical properties of short carbon fiber-reinforced natural graphite flake composites with mesophase pitch as the binder Carbon 53 2013 313 320
10. S. Cravanzola, G. Haznedar, D. Scarano, A. Zecchina, and F. Cesano Carbon-based piezoresistive polymer composites: structure and electrical properties Carbon 62 2013 270 277
11. H. Wu, and L.T. Drzal Graphene nanoplatelet paper as a light-weight composite with excellent electrical and thermal conductivity and good gas barrier properties Carbon 50 3 2012 1135 1145
12. E. Fitzer The future of carbon-carbon composites Carbon 25 2 1987 163 190
13. L.M. Manocha, A. Warrier, S. Manocha, D. Sathiyamoorthy, and S. Banerjee Thermophysical properties of densified pitch based carbon/carbon materials-I. Unidirectional composites Carbon 44 3 2006 480 487
14. Z.J. Liu, Q.J. Guo, J.L. Shi, G.T. Zhai, and L. Liu Graphite blocks with high thermal conductivity derived from natural graphite flake Carbon 46 3 2008 414 421
15. L.W. Wang, S.J. Metcalf, R.E. Critoph, R. Thorpe, and Z. Tamainot-Telto Thermal conductivity and permeability of consolidated expanded natural graphite treated with sulphuric acid Carbon 49 14 2011 4812 4819
16. A. Yadav, R. Kumar, G. Bhatia, and G.L. Verma Development of mesophase pitch derived high thermal conductivity graphite foam using a template method Carbon 49 11 2011 3622 3630
17. W.W. Focke, H. Badenhorst, S. Ramjee, H.J. Kruger, R.V. Schalkwyk, and B. Rand Graphite foam from pitch and expandable graphite Carbon 73 2014 41 50
18. S.X. Zhou, J.Z. Xu, Q.H. Yang, S. Chiang, B.H. Li, and H.D. Du et al. Experiments and modeling of thermal conductivity of flake graphite/polymer composites affected by adding carbon-based nano-fillers Carbon 57 2013 452 459
19. G.M. Yuan, X.K. Li, Z.J. Dong, X.Q. Xiong, B. Rand, and Z.W. Cui et al. Pitch-based ribbon-shaped carbon-fiber-reinforced one-dimensional carbon/carbon composites with ultrahigh thermal conductivity Carbon 68 2014 413 425
20. L. Yu, J.S. Park, Y.S. Lim, C.S. Lee, K. Shin, and H.J. Moon et al. Carbon hybrid fillers composed of carbon nanotubes directly grown on graphene nanoplatelets for effective thermal conductivity in epoxy composites Nanotechnology 24 15 2013 155604
21. W.J. Evans, and P. Keblinski Thermal conductivity of carbon nanotube cross-bar structures Nanotechnology 21 2010 475704
22. Y. Zhao, J.L. Shi, H.Q. Wang, Z.C. Tao, Z.J. Liu, and Q.G. Guo et al. A sandwich structure graphite block with excellent thermal and mechanical properties reinforced by in-situ grown carbon nanotubes Carbon 51 2013 427 430
23. H.F. Lu, W.S. Kuo, and T.H. Ko Microstructures and thermal conductivities of carbon nanotube/graphite nanosheet compacts Nanoscale Microscale Thermophys Eng 15 4 2011 209 219
24. M.F.L. De Volder, S.H. Tawfick, R.H. Baughman, and A. John Hart Carbon nanotubes: present and future commercial applications Science 339 2013 535 539
25. K. Zhang, V. Dwivedi, C.Y. Chi, and J.S. Wu Graphene oxide/ferric hydroxide composites for efficient arsenate removal from drinking water J Hazard Mater 182 2010 162 168
26. J. Martinez1, T.D. Yuzvinsky1, A.M. Fennimore1, A. Zettl, R. Garcia, and C. Bustamante Length control and sharpening of atomic force microscope carbon nanotube tips assisted by an electron beam Nanotechnology 16 11 2005 2493 2496
27. K. Chu, Q. Wu, C. Jia, X. Liang, J. Nie, and W. Tian Fabrication and effective thermal conductivity of multi-walled carbon nanotubes reinforced Cu matrix composites for heat sink applications Compos Sci Technol 70 2 2010 298 304
28. C.Q. Ru Effective bending stiffness of carbon nanotubes Phys Rev B 62 2000 9973 9976
29. E.C. Vermisoglou, E. Devlin, T. Giannakopoulou, G. Romanos, N. Boukos, and V. Psycharis et al. Reduced graphene oxide/iron carbide nanocomposites for magnetic and supercapacitor application J Alloys Compd 590 2014 102 109
30. W.R. Collins, W. Lewandowski, E. Schmois, J. Walish, and T.M. Swager Claisen rearrangement of graphite oxide: a route to covalently functionalized graphenes Angew Chem Int Ed 50 38 2011 8848 8852
31. L.J. Lanticse-Diaz, Y. Tanabe, T. Enami, K. Nakamura, M. Endo, and E. Yasuda The effect of nanotube alignment on stress graphitization of carbon/carbon nanotube composites Carbon 47 4 2009 974 980
32. R.J. Zaldivar, and G.S. Rellick Some observations on stress graphitization in carbon-carbon composites Carbon 29 8 1991 1155 1163
33. S.A. Solin, and R.J. Nemanich First and second-order Raman scattering from finite-size crystals of graphite Phys Rev B 20 1979 392 401
34. A.P. Yu, P. Ramesh, X.B. Sun, E. Bekyarova, M.E. Itkis, and R.C. Haddon Enhanced thermal conductivity in a hybrid graphite nanoplatelet-carbon nanotube filler for epoxy composites Adv Mater 20 2008 4740 4744
35. S.S. Gupta, V.M. Siva, S. Krishnan, T.S. Sreeprasad, P.K. Singh, and T. Pradeep Thermal conductivity enhancement of nanofluids containing graphene nanosheets J Appl Phys 110 8 2011 084302
36. H. Babaei, P. Keblinski, and J.M. Khodadadi Thermal conductivity enhancement of paraffins by increasing the alignment of molecules through adding CNT/graphene Int J Heat Mass Transfer 58 1-2 2013 209 216
37. X.J. Tian, M.E. Itkis, E.B. Bekyarova, and R.C. Haddon Anisotropic thermal and electrical properties of thin thermal interface layers of graphite nanoplatelet-based composites Sci Rep 3 2013 1710
38. W.S. Kuo, T.H. Ko, and H.F. Lu On the thermally conductive behaviour of compacted graphite nanosheets Micro Nano Lett 5 4 2010 219 221
39. A.E. Aliev, M.H. Lima, E.M. Silverman, and R.H. Baughman Thermal conductivity of multi-walled carbon nanotube sheets: radiation losses and quenching of phonon modes Nanotechnology 21 2010 035709
40. R.S. Prasher, X.J. Hu, Y. Chalopin, N. Mingo, K. Lofgreen, and S. Volz Turning carbon nanotubes from exceptional heat conductors into insulators Phys Rev Lett 102 2009 105901
41. L. Hu, T. Desai, and P. Keblinski Thermal transport in graphene-based nanocomposite J Appl Phys 110 2011 33517
42. D.K.L. Tsang, B.J. Marsden, S.L. Fok, and G. Hall Graphite thermal expansion relationship for different temperature ranges Carbon 43 14 2005 2902 2906
43. X.M. Chen, M. Zheng, C. Park, and C.H. Ke Direct measurements of the mechanical strength of carbon nanotube-poly(methyl methacrylate) interfaces Small 9 19 2013 3345 3351
44. G. Yamamoto, G. Shirasu, T. Hashida, T. Takagi, J.W. Suk, and J. An Nanotube fracture during the failure of carbon nanotube/alumina composites Carbon 49 12 2011 3709 3716
45. Y. Li, Y.L. Liu, X.H. Peng, C. Yan, S. Liu, and N. Hu Pull-out simulations on interfacial properties of carbon nanotube-reinforced polymer nanocomposites Comput Mater Sci 50 2011 1854 1860
46. S.S. Wicks, R.G. Villoria, and B.L. Wardle Interlaminar and intralaminar reinforcement of composite laminates with aligned carbon nanotubes Compos Sci Technol 70 2010 20 28
47. M.R. Loos, J. Yang, D.L. Feke, I. Manas-Zloczower, S. Unal, and U. Younes Enhancement of fatigue life of polyurethane composites containing carbon nanotubes Compos B 44 2013 740 744
48. B. Boesl, D. Lahiri, S. Behdad, and A. Agarwal Direct observation of carbon nanotube induced strengthening in aluminum composite via in situ tensile tests Carbon 69 2014 79 85
49. S.R. Dhakate, and O.P. Bahl Effect of carbon fiber surface functional groups on the mechanical properties of carbon-carbon composites with HTT Carbon 41 6 2003 1193 1203