Effects of heat treatment on the thermal properties of highly nanoporous graphene aerogels using the infrared microscopy technique

International Journal of Heat and Mass Transfer

Volumn 76, Issue , 2014, Pages 122-127

  Fan, Zeng ^a,b   Marconnet, Amy ^c   Nguyen, Son T ^a   Lim, Christina Y H ^a   Duong, Hai M ^a  

^a NATIONAL UNIVERSITY OF SINGAPORE   (Singapore)

^b MASSACHUSETTS INSTITUTE OF TECHNOLOGY   (United States)

^c Purdue University   (United States)

Author keywords

Graphene aerogels; Thermal conduction; Thermal interface materials

Indexed keywords

AEROGELS; GRAPHENE; INTERFACES (MATERIALS); POROUS MATERIALS; THERMODYNAMIC PROPERTIES;

ANNEALING TREATMENTS; CHEMICAL REDUCTION METHODS; EFFECTS OF HEAT TREATMENT; GRAPHENE AEROGELS; INFRARED MICROSCOPY; THERMAL CONDUCTION; THERMAL INTERFACE MATERIALS; THERMAL MEASUREMENT TECHNIQUE;

THERMAL CONDUCTIVITY OF GASES;

EID: 84900819451     PISSN: 00179310     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijheatmasstransfer.2014.04.023     Document Type: Article

References (55)

1. A.A. Balandin Thermal properties of graphene and nanostructured carbon materials Nat. Mater. 30 2011 569 581
2. C.K. Leong, and D.D.L. Chung Carbon black dispersions as thermal pastes that surpass solder in providing high thermal contact conductance Carbon 41 13 2003 2459 2469
3. A.A. Balandin, S. Ghosh, W. Bao, I. Calizo, D. Teweldebrhan, and F. Miao et al. Superior thermal conductivity of single-layer graphene Nano Lett. 8 3 2008 902 907
4. F. Yavari, H.R. Fard, K. Pashayi, M.A. Rafiee, A. Zamiri, and Z. Yu et al. Enhanced thermal conductivity in a nanostructured phase change composite due to low concentration graphene additives J. Phys. Chem. C 115 17 2011 8753 8758
5. K.M. Shahil, and A.A. Balandin Graphene-multilayer graphene nanocomposites as highly efficient thermal interface materials Nano Lett. 12 2 2012 861 867
6. A. Yu, P. Ramesh, M.E. Itkis, E. Bekyarova, and R.C. Haddon Graphite nanoplatelet-epoxy composite thermal interface materials J. Phys. Chem. C 111 21 2007 7565 7569 (Pubitemid 46918242)
7. J. Loomis, X. Fan, F. Khosravi, P. Xu, M. Fletcher, and R.W. Cohn et al. Graphene/elastomer composite-based photo-thermal nanopositioners Sci. Rep. 3 2013 1900
8. M.T. Pettes, H. 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
9. J.H. Seol, I. Jo, A.L. Moore, L. Lindsay, Z.H. Aitken, and M.T. Pettes et al. Two-dimensional phonon transport in supported graphene Science 328 5975 2010 213 216
10. M.T. Pettes, I. Jo, Z. Yao, and L. Shi Influence of polymeric residue on the thermal conductivity of suspended bilayer graphene Nano Lett. 11 3 2011 1195 1200
11. V. Singh, D. Joung, L. Zhai, S. Das, S.I. Khondaker, and S. Seal Graphene based materials: past, present and future Prog. Mater. Sci. 56 8 2011 1178 1271
12. S. Stankovich, D.A. Dikin, G.H. Dommett, K.M. Kohlhaas, E.J. Zimney, and E.A. Stach et al. Graphene-based composite materials Nature 442 7100 2006 282 286 (Pubitemid 44114900)
13. R. Verdejo, F. Barroso-Bujans, M.A. Rodriguez-Perez, J. Antonio de Saja, and M.A. Lopez-Manchado Functionalized graphene sheet filled silicone foam nanocomposites J. Mater. Chem. 18 19 2008 2221 2226 (Pubitemid 351671697)
14. H.C. Schniepp, J.-L. Li, M.J. Mcallister, H. Sai, M.H. Alonso, and D.H. Adamson et al. Functionalized single graphene sheets derived from splitting graphite oxide J. Phys. Chem. B 110 2006 8535 8539 (Pubitemid 43798555)
15. S. Gilje, S. Han, M. Wang, K.L. Wang, and R.B. Kaner A chemical route to graphene for device applications Nano Lett. 7 11 2007 3394
16. Y. Xu, K. Sheng, C. Li, and G. Shi Self-assembled graphene hydrogel via a one-step hydrothermal process ACS Nano 4 7 2010 4324 4330
17. X. Jiang, Y. Ma, J. Li, Q. Fan, and W. Huang Self-assembly of reduced graphene oxide into three-dimensional architecture by divalent ion linkage J. Phys. Chem. C 114 51 2010 22462 22465
18. X. Zhang, Z. Sui, B. Xu, S. Yue, Y. Luo, and W. Zhan et al. Mechanically strong and highly conductive graphene aerogel and its use as electrodes for electrochemical power sources J. Mater. Chem. 21 18 2011 6494 6497
19. L. Zhang, and G. Shi Preparation of highly conductive graphene hydrogels for fabricating supercapacitors with high rate capability J. Phys. Chem. C 115 34 2011 17206 17212
20. W. Chen, and L. Yan In situ self-assembly of mild chemical reduction graphene for three-dimensional architectures Nanoscale 3 8 2011 3132 3137
21. M.A. Worsley, P.J. Pauzauskie, T.Y. Olson, J. Biener, J.H. Satcher, and T.F. Baumann Synthesis of graphene aerogel with high electrical conductivity J. Am. Chem. Soc. 132 40 2010 14067 14069
22. M.A. Worsley, T.Y. Olson, J.R.I. Lee, T.M. Willey, M.H. Nielsen, and S.K. Roberts et al. High surface area, sp2-cross-linked three-dimensional graphene monoliths J. Phys. Chem. Lett. 2 8 2011 921 925
23. Y. Zhong, M. Zhou, F. Huang, T. Lin, and D. Wan Effect of graphene aerogel on thermal behavior of phase change materials for thermal management Sol. Energy Mater. Sol. C 113 2013 195 200
24. A.J. McNamara, Y. Joshi, and Z.M. Zhang Characterization of nanostructured thermal interface materials - a review Int. J. Therm. Sci. 62 2012 2 11
25. W. Lin, C.P. Wong, Vertically aligned carbon nanotubes for thermal interface materials: quality control, alignment improvement and laser flash measurement, in: Electronic Components and Technology Conference (ECTC), IEEE, Las Vegas, 2010, pp. 967-972.
26. B. Debelak, and K. Lafdi Use of exfoliated graphite filler to enhance polymer physical properties Carbon 45 9 2007 1727 1734 (Pubitemid 47069253)
27. J. Xu, and T.S. Fisher Enhancement of thermal interface materials with carbon nanotube arrays Int. J. Heat Mass Transfer 49 9-10 2006 1658 1666
28. P. Bonnet, D. Sireude, B. Garnier, and O. Chauvet Thermal properties and percolation in carbon nanotube-polymer composites Appl. Phys. Lett. 91 20 2007 201910
29. X.J. Hu, A.A. Padilla, J. Xu, T.S. Fisher, and K.E. Goodson 3-Omega measurements of vertically oriented carbon nanotubes on silicon J. Heat Transfer 128 11 2006 1109 1113 (Pubitemid 46117409)
30. M.T. Hung, O. Choi, Y.S. Ju, and H.T. Hahn Heat conduction in graphite-nanoplatelet-reinforced polymer nanocomposites Appl. Phys. Lett. 89 2 2006 023117
31. A.M. Marconnet, N. Yamamoto, M.A. Panzer, B.L. Wardle, and K.E. Goodson Thermal conductivity in aligned carbon nanotube-polymer nanocomposites with high packing density ACS Nano 5 6 2011 4818 4825
32. X.J. Hu, M.A. Panzer, and K.E. Goodson Infrared microscopy thermal characterization of opposing carbon nanotube arrays J. Heat Transfer 129 1 2007 91 93 (Pubitemid 46744657)
33. A. McNamara, V. Sahu, Y. Joshi, Z. Zhang, Infrared imaging microscope as an effective tool for measuring thermal resistance of emerging interface materials, American Society of Mechanical Engineering, ASME, Chicago, 2011, 189-194.
34. Z. Fan, D.Z.Y. Tng, S.T. Nguyen, J. Feng, C. Lin, and P. Xiao et al. Morphology effects on electrical and thermal properties of binderless graphene aerogels Chem. Phys. Lett. 561-562 2013 92 96
35. S.T. Nguyen, H.T. Nguyen, A. Rinaldi, N.P.V. Nguyen, Z. Fan, and H.M. Duong Morphology control and thermal stability of binderless-graphene aerogels from graphite for energy storage applications Colloids Surf. A 414 2012 352 358
36. W.S. Hummers, and R.E. Offeman Preparation of graphitic oxide J. Am. Chem. Soc. 80 1958 1339
37. S. Stankovich, R.D. Piner, S.T. Nguyen, and R.S. Ruoff Synthesis and exfoliation of isocyanate-treated graphene oxide nanoplatelets Carbon 44 15 2006 3342 3347 (Pubitemid 44634397)
38. L.Q. Xu, Y.L. Liu, K.G. Neoh, E.T. Kang, and G.D. Fu Reduction of graphene oxide by aniline with its concomitant oxidative polymerization Macromol. Rapid Commun. 32 8 2011 684 688
39. Z. Sui, X. Zhang, Y. Lei, and Y. Luo Easy and green synthesis of reduced graphite oxide-based hydrogels Carbon 49 13 2011 4314 4321
40. G. Chen, Nanoscale energy transport and conversion: a parallel treatment of electrons, molecules, phonons, and photons, Mit-Pappalardo Series in Mechanical Engineering, Oxford University Press, USA, 2005.
41. E. Pop, V. Varshney, and A.K. Roy Thermal properties of graphene: fundamentals and applications MRS Bull. 37 12 2012 1273 1281
42. R. Singh, and H.S. Kasana Computational aspects of effective thermal conductivity of highly porous metal foams Appl. Therm. Eng. 24 13 2004 1841 1849
43. S.N. Schiffres, K.H. Kim, L. Hu, A.J.H. McGaughey, M.F. Islam, and J.A. Malen Gas diffusion, energy transport, and thermal accommodation in single-walled carbon nanotube aerogels Adv. Funct. Mater. 22 24 2012 5251 5258
44. J.Y. Kim, J.-H. Lee, and J.C. Grossman Thermal transport in functionalized graphene ACS Nano 6 10 2012 9050 9057
45. W. Yu, H. Xie, X. Wang, and X. Wang Significant thermal conductivity enhancement for nanofluids containing graphene nanosheets Phys. Lett. A 375 10 2011 1323 1328
46. C. Gomez-Navarro, J.C. Meyer, R.S. Sundaram, A. Chuvilin, S. Kurasch, and M. Burghard et al. Atomic structure of reduced graphene oxide Nano Lett. 10 4 2010 1144 1148
47. S. Ghosh, W. Bao, D.L. Nika, S. Subrina, E.P. Pokatilov, and C.N. Lau et al. Dimensional crossover of thermal transport in few-layer graphene Nat. Mater. 10 2010 555 558
48. I. Ivanov, A. Puretzky, G. Eres, H. Wang, Z. Pan, and H. Cui et al. Fast and highly anisotropic thermal transport through vertically aligned carbon nanotube arrays Appl. Phys. Lett. 89 22 2006 223110
49. W.D. Kingery Thermal conductivity: XIV, conductivity of multicomponent systems J. Am. Ceram. Soc. 42 12 1959 617 627
50. C.W. Nan, R. Birringer, D.R. Clarke, and H. Gleiter Effective thermal conductivity of particulate composites with interfacial thermal resistance J. Appl. Phys. 81 10 1997 6692 6699 (Pubitemid 127589874)
51. V.A. Ermakov, A.V. Alaferdov, A.R. Vaz, A.V. Baranov, and S.A. Moshkalev Nonlocal laser annealing to improve thermal contacts between multi-layer graphene and metals Nanotechnology 24 15 2013 155301
52. H.D. Wang, J.H. Lin, Z.Y. Guo, X. Zhang, R.F. Zhang, and F. Wei et al. Thermal transport across the interface between a suspended single-walled carbon nanotube and air Nanoscale Microscale Thermophys. Eng. 17 4 2013 349 365
53. Y. Zhang, L. Liu, N. Xi, Y. Wang, Z. Dong, and U.C. Wejinya Dielectrophoretic assembly and atomic force microscopy modification of reduced graphene oxide J. Appl. Phys. 110 11 2011 114515
54. V.C. Tung, M.J. Allen, Y. Yang, and R.B. Kaner High-throughput solution processing of large-scale graphene Nat. Nanotechnol. 4 1 2009 25 29
55. K.M.F. Shahil, and A.A. Balandin Thermal properties of graphene and multilayer graphene: applications in thermal interface materials Solid State Commun. 152 15 2012 1331 1340