Thermally conductive composite film filled with highly dispersed graphene nanoplatelets via solvent-free one-step fabrication

Composites Part B: Engineering

Volumn 110, Issue , 2017, Pages 171-177

  Yu, Jaesang ^a   Cha, Ji Eun ^a   Kim, Seong Yun ^a  

^a Korea Institute of Science and Technology   (South Korea)

Author keywords

Compression moulding; Non destructive testing; Polymer matrix composites (PMCs); Thermal properties

Indexed keywords

COMPRESSION MOLDING; COMPUTERIZED TOMOGRAPHY; DISPERSIONS; FILLED POLYMERS; FILLERS; NANOCOMPOSITE FILMS; NONDESTRUCTIVE EXAMINATION; POLYMER FILMS; POLYMER MATRIX COMPOSITES; THERMAL CONDUCTIVITY; THERMAL CONDUCTIVITY OF SOLIDS; THERMODYNAMIC PROPERTIES;

CONDUCTIVE COMPOSITES; ELECTRICAL CONDUCTIVITY; GRAPHENE NANOPLATELETS; NON DESTRUCTIVE TESTING; POLYMER MATRIX COMPOSITES (PMCS); THEORETICAL CALCULATIONS; THREE-DIMENSIONAL (3D) ANALYSIS; X RAY MICRO-COMPUTED TOMOGRAPHY;

COMPOSITE FILMS;

EID: 84995773096     PISSN: 13598368     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.compositesb.2016.11.014     Document Type: Article

References (50)

1. [1] Han, Z., Fina, A., Thermal conductivity of carbon nanotubes and their polymer nanocomposites: a review. Prog Polym Sci 36 (2011), 914–944.
2. [2] Kim, S.Y., Noh, Y.J., Yu, J., Improved thermal conductivity of polymeric composites fabricated by solvent-free processing for the enhanced dispersion of nanofillers and a theoretical approach for composites containing multiple heterogeneities and geometrized nanofillers. Compos Sci Technol 101 (2014), 79–85.
3. [3] Kim, H.S., J-u, Jang, Yu, J., Kim, S.Y., Thermal conductivity of polymer composites based on the length of multi-walled carbon nanotubes. Compos Pt B – Eng 79 (2015), 505–512.
4. [4] Sengupta, R., Bhattacharya, M., Bandyopadhyay, S., Bhowmick, A.K., A review on the mechanical and electrical properties of graphite and modified graphite reinforced polymer composites. Prog Polym Sci 36 (2011), 638–670.
5. [5] Kim, S.Y., Noh, Y.J., Yu, J., Thermal conductivity of graphene nanoplatelets filled composites fabricated by solvent-free processing for the excellent filler dispersion and a theoretical approach for the composites containing the geometrized fillers. Compos Pt A – Appl Sci Manuf 69 (2015), 219–225.
6. [6] Balandin, A.A., Thermal properties of graphene and nanostructured carbon materials. Nat Mater 10 (2011), 569–581.
7. [7] Shahil, K.M.F., Balandin, A.A., Graphene-multilayer graphene nanocomposites as highly efficient thermal interface materials. Nano Lett 12 (2012), 861–867.
8. [8] Kim, P., Shi, L., Majumdar, A., McEuen, P.L., Thermal transport measurements of individual multiwalled nanotubes. Phys Rev Lett 36 (2011), 914–944.
9. [9] Yu, C., Shi, L., Yao, Z., Li, D., Majumdar, A., Thermal conductance and thermopower of an individual single-wall carbon nanotube. Nano Lett 5 (2005), 1842–1846.
10. [10] Noh, Y.J., Kim, S.Y., Synergistic improvement of thermal conductivity in polymer composites filled with pitch based carbon fiber and graphene nanoplatelets. Polym Test 45 (2015), 132–138.
11. [11] Noh, Y.J., Kim, H.S., Ku, B.-C., Khil, M.-S., Kim, S.Y., Thermal conductivity of polymer composites with geometric characteristics of carbon allotropes. Adv Eng Mater 18 (2016), 1127–1132.
12. [12] 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.
13. [13] Noh, Y.J., Joh, H.-I., Yu, J., Hwang, S.H., Lee, S., Lee, C.H., et al. Ultra-high dispersion of graphene in polymer composite via solvent free fabrication and functionalization. Sci Rep, 5, 2015, 9141.
14. [14] Noh, Y.J., Pak, S.Y., Hwang, S.H., Hwang, J.Y., Kim, S.Y., Youn, J.R., Enhanced dispersion for electrical percolation behavior of multi-walled carbon nanotubes in polymer nanocomposites using simple powder mixing and in situ polymerization with surface treatment of the fillers. Compos Sci Technol 89 (2013), 29–37.
15. [15] Kim, S.Y., Noh, Y.J., Yu, J., Prediction and experimental validation of electrical percolation by applying a modified micromechanics model considering multiple heterogeneous inclusions. Compos Sci Technol 106 (2015), 156–162.
16. [16] He, Y., Tian, G., Pan, M., Chen, D., Non-destructive testing of low-energy impact in CFRP laminates and interior defects in honeycomb sandwich using scanning pulsed eddy current. Compos Pt B – Eng 59 (2014), 196–203.
17. [17] Amenabar, I., Mendikute, A., López-Arraiza, A., Lizaranzu, M., Aurrekoetxea, J., Comparison and analysis of non-destructive testing techniques suitable for delamination inspection in wind turbine blades. Compos Pt B – Eng 42 (2011), 1298–1305.
18. [18] Park, J.-M., Kim, P.-G., Jang, J.-H., Wang, Z., Kim, J.-W., Lee, W.-I., et al. Self-sensing and dispersive evaluation of single carbon fiber/carbon nanotube (CNT)-epoxy composites using electro-micromechanical technique and nondestructive acoustic emission. Compos Pt B – Eng 39 (2008), 1170–1182.
19. [19] Ayorinde, E., Gibson, R., Kulkarni, S., Deng, F., Mahfuz, H., Islam, S., et al. Reliable low-cost NDE of composite marine sandwich structures. Compos Pt B – Eng 39 (2008), 226–241.
20. [20] Park, J.-M., Lee, S.-I., Lawrence DeVries, K., Nondestructive sensing evaluation of surface modified single-carbon fiber reinforced epoxy composites by electrical resistivity measurement. Compos Pt B – Eng 37 (2006), 612–626.
21. [21] Gao, C., Wei, T., Du, F., Lu, Y., Xiang, X.-D., High spatial resolution quantitative microwave impedance microscopy by a scanning tip microwave near-field microscope. Appl Phys Lett 71 (1997), 1872–1874.
22. [22] Lübbert, D., Baumbach, T., Härtwig, J., Boller, E., Pernot, E., μm-resolved high resolution X-ray diffraction imaging for semiconductor quality control. Nucl Instrum Methods Phys Res Sect B – Beam Interact Mater Atoms 160 (2000), 521–527.
23. [23] Lee, J.-R., Molimard, J., Vautrin, A., Surrel, Y., Diffraction grating interferometers for mechanical characterisations of advanced fabric laminates. Opt Laser Technol 38 (2006), 51–66.
24. [24] Nalladega, V., Sathish, S., Jata, K.V., Blodgett, M.P., Development of eddy current microscopy for high resolution electrical conductivity imaging using atomic force microscopy. Rev Sci Instrum, 79, 2008, 073705.
25. [25] Singh, Y., Electrical resistivity measurements: a review. Int J Mod Phys: Conf Ser 22 (2013), 745–756.
26. [26] Cheng, L., Gao, B., Tian, G.Y., Woo, W.L., Berthiau, G., Impact damage detection and identification using eddy current pulsed thermography through integration of PCA and ICA. IEEE Sens J 14 (2014), 1655–1663.
27. [27] Niemann, R., Kopeček, J., Heczko, O., Romberg, J., Schultz, L., Fähler, S., et al. Localizing sources of acoustic emission during the martensitic transformation. Phys Rev B, 89, 2014, 214118.
28. [28] Harizi, W., Chaki, S., Bourse, G., Ourak, M., Mechanical damage characterization of glass fiber-reinforced polymer laminates by ultrasonic maps. Compos Pt B – Eng 70 (2015), 131–137.
29. [29] Grosso, M., Lopez, J.E.C., Silva, V.M.A., Soares, S.D., Rebello, J.M.A., Pereira, G.R., Pulsed thermography inspection of adhesive composite joints: computational simulation model and experimental validation. Compos Pt B – Eng 106 (2016), 1–9.
30. [30] Mizukami, K., Mizutani, Y., Todoroki, A., Suzuki, Y., Detection of in-plane and out-of-plane fiber waviness in unidirectional carbon fiber reinforced composites using eddy current testing. Compos Pt B – Eng 86 (2016), 84–94.
31. [31] Kim, H.S., Bae, H.S., Yu, J., Kim, S.Y., Thermal conductivity of polymer composites with the geometrical characteristics of graphene nanoplatelets. Sci Rep, 6, 2016, 26825.
32. [32] Yu, J., Lacy, T.E. Jr., Toghiani, H., Pittman, C.U. Jr., Micromechanically-based effective thermal conductivity estimates for polymer nanocomposites. Compos Pt B – Eng 53 (2013), 267–273.
33. [33] Mori, T., Tanaka, K., Average stress in matrix and average elastic energy of materials with misfitting inclusions. Acta Metall 21 (1973), 571–574.
34. [34] Benveniste, Y., A new approach to the application of Mori-Tanaka's theory in composite materials. Mech Mater 6 (1987), 147–157.
35. [35] Nemat-Nasser, S., Hori, M., Micromechanics: overall properties of heterogeneous materials. 1993, North-Holland, Amsterdam.
36. [36] Lee, H.S., S-y, Kim, Noh, Y.J., Kim, S.Y., Design of microwave plasma and enhanced mechanical properties of thermoplastic composites reinforced with microwave plasma-treated carbon fiber fabric. Compos Pt B – Eng 60 (2014), 621–626.
37. [37] Yu, J., Lacy, T.E. Jr., Toghiani, H., Pittman, C.U. Jr., Hwang, Y., Classical micromechanics modeling of nanocomposites with carbon nanofibers and interphase. J Compos Mater 45 (2011), 2401–2413.
38. [38] Yu, J., Lacy, T.E. Jr., Toghiani, H., Pittman, C.U. Jr., Effective property estimates for composites containing multiple nanoheterogeneities: Part I nanospheres, nanoplatelets, and voids. J Compos Mater 47 (2013), 549–558.
39. [39] Yu, J., Lacy, T.E. Jr., Toghiani, H., Pittman, C.U. Jr., Effective property estimates for composites containing multiple nanoheterogeneities: Part II nanofibers and voids. J Compos Mater 47 (2012), 1273–1282.
40. [40] Yu, J., Lacy, T.E. Jr., Toghiani, H., Pittman, C.U. Jr., Schneider, J., Determination of carbon nanofiber morphology in vinyl ester nanocomposites. J Compos Mater 46 (2012), 1943–1953.
41. [41] Eshelby, J.D., The determination of the elastic field of an ellipsoidal inclusion, and related problems. P. R Soc A A241 (1957), 376–396.
42. [42] Hatta, H., Taya, M., Effective thermal conductivity of a misoriented short fiber composite. J Appl Phys 58 (1985), 2478–2486.
43. [43] Chen, C.-H., Wang, Y.-C., Effective thermal conductivity of misoriented short-fiber reinforced thermoplastics. Mech Mater 23 (1996), 217–228.
44. [44] Nan, C.-W., Liu, G., Lin, Y., Li, M., Interface effect on thermal conductivity of carbon nanotube composites. Appl Phys Lett 85 (2004), 3549–3551.
45. [45] Song, Y.S., Youn, J.R., Evaluation of effective thermal conductivity for carbon nanotube/polymer composites using control volume finite element method. Carbon 44 (2006), 710–717.
46. [46] Song, Y.S., Youn, J.R., Influence of dispersion states of carbon nanotubes on physical properties of epoxy nanocomposites. Carbon 43 (2005), 1378–1385.
47. [47] Shenogina, N., Shenogin, S., Xue, L., Keblinski, P., On the lack of thermal percolation in carbon nanotube composites. Appl Phys Lett, 87, 2005, 133106.
48. [48] Huxtable, S.T., Cahill, D.G., Shenogin, S., Xue, L., Ozisik, R., Barone, P., et al. Interfacial heat flow in carbon nanotube suspensions. Nat Mater 2 (2003), 731–734.
49. [49] Shenogin, S., Xue, L., Ozisik, R., Keblinski, P., Cahill, D.G., Role of thermal boundary resistance on the heat flow in carbon-nanotube composites. J Appl Phys 95 (2004), 8136–8144.
50. [50] Pak, S.Y., Kim, H.M., Kim, S.Y., Youn, J.R., Synergistic improvement of thermal conductivity of thermoplastic composites with mixed boron nitride and multi-walled carbon nanotube fillers. Carbon 50 (2012), 4830–4838.