Effect of Growth Temperature on Carbon Nanotube Grafting Morphology and Mechanical Behavior of Carbon Fibers and Carbon/Carbon Composites

doi:10.1016/j.jmst.2016.08.015

Abstract

Abstract:

High-purity carbon nanotubes (CNTs) with different orientation and lengths were grafted on carbon fibers (CFs) in woven fabrics by using double injection chemical vapor deposition and adjusting the growth temperature. Scanning electron microscopy (SEM), transmission electron microscopy (TEM) and Raman investigations reveal that the grafted CNTs change from being predominantly aligned and uniform in diameter to absolutely disordered and variable in diameter, whilst they show significantly increased crystallinity, as the growth temperature is increased from 730?°C to 870?°C. In tensile tests of fiber bundles, much more strength degradation of CFs was observed after the growth process at higher temperature than that at lower temperature. These hybrid preforms produced at different growth temperatures were used to reinforce carbon/carbon (C/C) composites. An increment of 34.4% in out-of-plane compressive strength (OCS) was obtained for the composites containing CNTs grown at 730?°C, while the OCS increment exhibits an obvious decrease with increasing the growth temperature. Compared with the higher growth temperature, the lower temperature contributes to the decrease in the strength loss of reinforcing fibers and meanwhile the growth of large extending length of CNTs, which can provide long reinforcement to the pyrocarbon matrix, and thus increase the compressive strength better.

Key words: Carbon nanotubes, Carbon fibers, Chemical vapor deposition, Carbon/carbon composites, Mechanical strength

Feng Lei,Li Ke-Zhi,Lu Jin-Hua,Qi Le-Hua. Effect of Growth Temperature on Carbon Nanotube Grafting Morphology and Mechanical Behavior of Carbon Fibers and Carbon/Carbon Composites[J]. J. Mater. Sci. Technol., 2017, 33(1): 65-70.

Figures/Tables 9

Table 1 Physical and mechanical properties of the various composites

Composites	V_CF (%)	V_CNT (%)	Apparent density, ρ (g/cm³)	OCS (MPa)
C0	46	0	1.60	160?±?8
C730	42	2.0	1.61	215?±?14
C800	42.5	1.8	1.61	182?±?12
C870	45.5	1.2	1.63	156?±?10

Fig.1 SEM images of CNT-grafted CFs synthesized at different growth temperatures: (a, b) 730?°C; (c, d) 800?°C; (e, f) 870?°C

Fig.2 TEM images of CNTs synthesized at different growth temperatures: (a) 730?°C; (b) 800?°C; (c) 870?°C. Insets are the enlarged views of the nanotube walls

Fig.3 Raman spectra of CFs before and after grafting CNTs at different growth temperatures

Fig.4 Out diameter distributions of CNTs synthesized at different growth temperatures

Fig.5 (a) TEM image of a CNT root with a pyramid-like catalyst particle on it, (b) SEM image of the interface between CNTs and CFs. Insets are the EDX spectra taken from the square areas marked in (a) and (b), respectively

Fig.6 Effect of different growth temperatures on the tensile strength of CF bundles (error bars denote the standard deviation of the measurement)

Fig.7 Compressive stress-strain curves of the C/C and CNT-C/C composites

Fig.8 SEM images of the compressively fractured surface of C/C and CNT-C/C composites: (a) C0; (b) C730; (c) an enlarged view of the square area marked in (b); (d) C870

References

[1]	Q. Song, K.Z. Li, H.L. Li, H.J. Li, C. Ren,Carbon 50 (2012) 3943-3960.
[2]	L. Feng, K.Z. Li, Z.S. Si, Q. Song, H.J. Li, J.H. Lu, L.J. Guo,Mater. Sci. Eng. A 626 (2015) 449-457.
[3]	J.S. Li, R.Y. Luo, Compos. Part A-Appl. S. 39(2008) 1700-1704.
[4]	P. Xiao, X.F. Lu, Y.Q. Liu, L.L. He,Mater. Sci. Eng. A 528 (2011) 3056-3061.
[5]	Q. Song, K.Z. Li, H.J. Li, Q.G. Fu, J. Mater. Sci.Technol. 29(2013) 711-714.
[6]	Q. An, N.R. Andrew, E.T. Thostenson,Carbon 50 (2012) 4130-4143.
[7]	S.S. Wicks, R.G. de Villoria, B.L.Wardle, Compos. Sci. Technol. 70(2010) 20-28.
[8]	H. Qian, E.S. Greenhalgh, M.S.P.Shaffer, A. Bismarck, J.Mater. Chem. 20(2010) 4751-4762.
[9]	W.B. Downs, R.T.K.Baker, J. Mater. Res. 10(1995) 625-633.
[10]	H. Qian, A. Bismarck, E.S. Greenhalgh, M.S.P.Shaffer, Compos. Sci. Technol. 70(2010) 393-399.
[11]	L. Feng, K.Z. Li, J.J. Sun, Y.J. Jia, H.J. Li, L.L. Zhang, Appl. Surf. Sci. 355(2015) 1020-1027.
[12]	S.W.Wang, B.C. Yang, J.Y. Yuan, Y.B. Si, H.Y. Chen, Sci. Rep. 5(2015) 14957-14965.
[13]	H. Qian, A. Bismarck, E.S. Greenhalgh, M.S.P. Shaffer,Carbon 48 (2010) 277-286.
[14]	C. Singh, M.S.P. Shaffer, A.H. Windle,Carbon 41 (2003) 359-368.
[15]	W.Z. Li,J.G.Wen, Y. Tu, Z.F. Ren, Appl. Phys. A-Mater. 73(2001) 259-264.
[16]	Q.H. Zhang, J.W. Liu, R. Sager, L.M. Dai, J. Baur, Compos. Sci. Technol. 69(2009) 594-601.
[17]	P. Lespade, A. Marchand, M. Couzi, F. Cruege,Carbon 22 (1984) 375-385.
[18]	L.M. Malard, M.A. Pimenta, G. Dresselhaus, M.S. Dresselhaus, Phys. Rep. 473(2009) 51-87.
[19]	A. Jorio, M.A. Pimenta, A.G. Souza, R. Saito, G. Dresselhaus, M.S. Dresselhaus,New J. Phys. 5(2003) 1-17.
[20]	W.Z. Li,J.G.Wen, Z.F. Ren, Appl. Phys. A-Mater. 74(2002) 397-402.
[21]	N. Sonoyama, M. Ohshita, A. Nijubu, H. Nishikawa, H. Yanase, J.I. Hayashi,T.Chiba,Carbon 44 (2006) 1754-1761.
[22]	M. Kumar, Y. Ando, J. Nanosci. Nanotechnol. 10(2010) 3739-3758.
[23]	P. Lv, Y.Y. Feng, P. Zhang, H.M. Chen, N.Q. Zhao, W. Feng,Carbon 49 (2011) 4665-4673.
[24]	H. Qian, A. Bismarck, E.S. Greenhalgh, G. Kalinka,M.S.P.Shaffer, Chem. Mater.20(2008) 1862-1869.
[25]	S.W. Wang, B.C. Yang, S.R. Zhang, J.Y. Yuan, Y.B. Si, H.Y. Chen,Chemphyschem 15 (2014) 2749-2755.
[26]	B.C. Yang,S.W.Wang, Y.Z. Guo, J.Y. Yuan, Y.B. Si, S.R. Zhang, H.Y. Chen, RSC Adv.4(2014) 54677-54683.
[27]	Q. Song, K.Z. Li, L.L. Zhang, L.H. Qi, H.J. Li, Q.G. Fu, H.L. Deng, Mater. Sci. Eng. A56(2013) 831-836.
[28]	H.L. Li, H.J. Li, J.H. Lu, K.Z. Li, C. Sun, D.S. Zhang,Mater. Sci. Eng. A 547 (>2012) 138-141.
[29]	R.B. Mathur, S. Chatterjee, B.P. Singh, Compos. Sci. Technol. 68(2008) 1608-1615.