Carbon Nanotube Reinforced Composites: Metal and Ceramic ...

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Nomenclature ~a 1 , ~a 2 Unit vectors in two-dimensional hexagonal lattice ~C h Chiral vector d Diameter of carbon nanotube e Electronic charge Go Conductance quantum (Go) h Planck s constant. n, m Integers q Chiral angle References 1 Tjong, S.C. (2007) Novel nanoparticlereinforced metal matrix composites with enhanced mechanical properties. Advanced Engineering Materials, 9, 588–593. 2 Ma, Z.Y., Li, Y.L., Liang, Y., Zheng, F., Bi, J. and Tjong, S.C. (1996) Nanometric Si 3N 4 particulate-reinforced aluminum composite. Materials Science and Engineering A, 219, 229–231. 3 Ma, Z.Y., Tjong, S.C. and Li, Y.L. (1999) The performance of aluminum-matrix composites with nanometric particulate Si-N-C reinforcement. Composites Science and Technology, 59, 263–270. 4 Kang, Y.C. and Chan, S.L. (2004) Tensile properties of nanometric Al 2O 3 particulate-reinforced aluminum matrix composites. Materials Chemistry and Physics, 85, 438–443. 5 Ijima, F S. (1991) Helical microtubules of graphite carbon. Nature, 354, 56–68. 6 Tjong, S.C. (2006) Structural and mechanical properties of polymer nanocomposites. Materials Science and Engineering R, 53, 73–197. 7 Tjong, S.C., Liang, G.D. and Bao, S.P. (2007) Electrical behavior of polypropylene/multi-walled carbon nanotube nanocomposites with low percolation threshold. Scripta Materialia, 57, 461–464. Referencesj33 8 Tjong, S.C., Liang, G.D. and Bao, S.P. (2008) Effects of crystallization on dispersion of carbon nanofibers and electrical properties of polymer nanocomposites. Polymer Engineering and Science, 48, 177–183. 9 Heimann, R.B., Evsyukov, S.E. and Koga, Y. (1997) Carbon allotropes: A suggested classification scheme based on valence orbital hybridization. Carbon, 35, 1654–1658. 10 Kroto, H.W., Heath, J.R., O Brien, S.C., Curl, R.F. and Smalley, R.H. (1985) C-60buckminsterfullerene. Nature, 318, 162–163. 11 Rao, C.N., Seshadri, R., Govindaraj, A. and Sen, R. (1995) Fullerenes, nanotubes, onions and related carbon structures. Materials Science and Engineering R, 15, 209–262. 12 Yamabe, T. (1995) Recent development of carbon nanotubes. Synthetic Metals, 70, 1511–1518. 13 Uchida, T., Anderson, D.P., Minus, M.L. and Kumar, S. (2006) Morphology and modulus of vapor grown carbon nanofibers. Journal of Materials Science, 41, 5851–5856. 14 Melechko, A.V., Merkulov, V.I., McKnight, T.E., Guillorn, M.A., Klein, K.L., Lowndes, D.H. and Simpson, M.L. (2005) Vertically aligned carbon nanofibers and related structures:
34j 1 Introduction Controlled synthesis and directed assembly. Journal of Applied Physics, 97, 041301(1)–041301(39). 15 Thostenson, E., Ren, Z. and Chou, T. (2001) Advances in science and technology of carbon nanotubes and their applications: a review. Composites Science and Technology, 61, 1899–1912. 16 Dresselhaus, M.S., Dresselhaus, G. and Saito, R. (1995) Physics of carbon nanotubes. Carbon, 33, 883–891. 17 Tibbets, G.G. (1989) Vapor-grown fibers: status and prospects. Carbon, 27, 745–747. 18 Laplaze, D., Bernier, P., Maser, W.K., Flamant, G., Guillard, T. and Loiseau, A. (1998) Carbon nanotubes: The solar approach. Carbon, 36, 685–688. 19 Ebbesen, T.W. (1994) Carbon nanotubes. Annual Review of Materials Science, 24, 235. 20 Iijima, S., Ajayan, P.M. and Ichihashi, T. (1992) Growth model for carbon nanotubes. Physical Review Letters, 69, 3100–3103. 21 Ijiima, S. (1993) Growth of carbon nanotubes. Materials Science and Engineering B, 19, 172–180. 22 Ebbesen, T.W. and Ajayan, P.M. (1992) Large-scale synthesis of carbon nanotubes. Nature, 358, 220. 23 Lee, S.J., Baik, H.K., Yoo, J.E. and Han, J.H. (2002) Large scale synthesis of carbon nanotubes by plasma rotating arc discharge technique. Diamond and Related Materials, 11, 914–917. 24 Jung, S.H., Kim, M.R., Jeong, S.H., Kim, S.U., Lee, O.J., Lee, K.H., Suh, J.H. and Park, C.K. (2003) High-yield synthesis of multi-walled carbon nanotubes by arc discharge in liquid nitrogen. Applied Physics A, 76, 285–286. 25 Ijima, S. and Ichihashi, T. (1993) Singleshell carbon nanotubes of 1-nm diameter. Nature, 363, 603–605. 26 Bethune, D.S., Kiang, C.H., de Vries, M.S., Gorman, G., Savoy, R., Vasquez, J. and Beyers, R. (1993) Cobalt-catalyzed growth of carbon nanotubes with single- atomic-layer walls. Nature, 363, 603–605. 27 Ajayan, P.M., Lambert, J.M., Bernier, P., Barbedette, L., Colliex, C. and Planeix, J.M. (1993) Growth morphologies during cobalt-catalyzed single-shell carbon nanotube synthesis. Chemical Physics Letters, 215, 509–517. 28 Journet, C. and Bernier, P. (1998) Production of carbon nanotubes. Applied Physics A, 67, 1–9. 29 Saito, Y., Nishikubo, K., Kawabata, K. and Matsumoto, T. (1996) Carbon nanocapsules and single-layered nanotubes produced with platinumgroup metals (Ru, Rh, Pd, Os, Ir, Pt) by arc discharge method. Journal of Applied Physics, 80, 3062–3067. 30 Zhao, X., Ohkohchi, M., Inoue, S., Suzuki, T., Kadoya, T. and Ando, Y. (2006) Large-scale purification of single-wall nanotubes prepared electric arc discharge. Diamond and Related Materials, 15, 1098–1102. 31 Farhat, S., de La Chapelle, M.L., Loiseau, A., Scott, C.D., Lefrant, S., Journet, C. and Bernier, P. (2001) Diameter control of single-walled carbon nanotubes using argon-helium mixtures gases. Journal of Chemical Physics, 115, 6752–6759. 32 Lambert, J.M., Ajayan, P.M., Bernier, P., Planeix, J.M., Brontons, V., Coq, B. and Castaing, J. (1994) Improving conditions towards isolating single-shell carbon nanotubes. Chemical Physics Letters, 226, 364–371. 33 Guo, T., Nikolev, P., Thess, A., Colbert, D.T. and Smalley, R.E. (1995) Catalytic growth of single-walled nanotubes by laser vaporization. Chemical Physics Letters, 243, 49–54. 34 Scott, C.D., Arepalli, S., Nikolaev, P. and Smalley, R.E. (2001) Growth mechanisms for single-wall carbon nanotubes in a laser-ablation process. Applied Physics A, 72, 573–580. 35 Bandow, S. and Asaka, S. (1998) Effect of growth temperature on the diameter distribution and chirality of single-wall
Page 2 and 3: Sie Chin Tjong Carbon Nanotube Rein
Page 4 and 5: Sie Chin Tjong Carbon Nanotube Rein
Page 6 and 7: Contents Preface IX List of Abbrevi
Page 8 and 9: 5 Carbon Nanotube-Ceramic Nanocompo
Page 10: Preface Carbon nanotubes are nanost
Page 13 and 14: XII List of Abbreviations HIP hot i
Page 16 and 17: 1 Introduction 1.1 Background Compo
Page 18 and 19: Figure 1.2 Transmission electron mi
Page 20 and 21: 1.3 Synthesis of Carbon Nanotubes 1
Page 22 and 23: MWNTs can be as high as 70% of the
Page 24 and 25: Figure 1.7 In situ TEM images recor
Page 26 and 27: 1.3 Synthesis of Carbon Nanotubesj1
Page 28 and 29: show TEM images of MWNTs synthesize
Page 30 and 31: Since then, large efforts have been
Page 32 and 33: 1.3.4 Patent Processes Carbon nanot
Page 34 and 35: 1.4 Purification of Carbon Nanotube
Page 36 and 37: Table 1.3 Patent processes for the
Page 38 and 39: Figure 1.13 Schematic illustration
Page 40 and 41: 1.5 Mechanical Properties of Carbon
Page 42 and 43: Figure 1.14 Carbon nanotubes in hig
Page 44 and 45: Figure 1.15 In situ tensile deforma
Page 46 and 47: Table 1.7 Theoretical and experimen
Page 50 and 51: carbon nanotubes. Physical Review L
Page 52 and 53: 70 Jang, I., Uh, H.S., Cho, H.J., L
Page 54 and 55: 108 Shelimov, K.B., Esenaliev, R.O.
Page 56 and 57: Bonnamy, S., Beguin, F., Burnham, N
Page 58 and 59: 2 Carbon Nanotube-Metal Nanocomposi
Page 60 and 61: isostatic pressing. In certain case
Page 62 and 63: This implies the absence of effecti
Page 64 and 65: coating material, the plasma gun an
Page 66 and 67: Table 2.4 Changes in the size and v
Page 68 and 69: Figure 2.6 (a) Low and (b) high mag
Page 70 and 71: Figure 2.8 SEM micrographs showing
Page 72 and 73: Figure 2.11 Bright field TEM microg
Page 74 and 75: Figure 2.13 TEM image of bulk Al/5
Page 76 and 77: 2.5 Magnesium-Based Nanocomposites
Page 78 and 79: limited improvement in ultimate ten
Page 80 and 81: Figure 2.18 SEM micrographs of the
Page 82 and 83: Figure 2.19 (a) Low and (b) high ma
Page 84 and 85: Figure 2.22 SEM micrographs of (a)
Page 86 and 87: Figure 2.25 (a) TEM micrograph show
Page 88 and 89: 2.8 Transition Metal-Based Nanocomp
Page 90 and 91: Figure 2.27 TEM image of electrodep
Page 92 and 93: Figure 2.29 SEM micrographs of (a)
Page 94 and 95: Figure 2.31 Schematic representatio
Page 96 and 97: einforcement content SiCp/Al compos
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Materials Science Forum, 534-536 (P
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composite. Materials Science and En
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111 Cha, S.I., Kim, K.T., Arshad, S
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90j 3 Physical Properties of Carbon
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100j 3 Physical Properties of Carbo
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104j 4 Mechanical Characteristics o
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132j 5 Carbon Nanotube-Ceramic Nano
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186j 7 Mechanical Properties of Car
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Table 8.1 Patent processes for maki
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218j 8 Conclusions development of c
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220j 8 Conclusions Figure 8.2 TEM m
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222j 8 Conclusions increase in Vick
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224j 8 Conclusions References 1 Cha
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226j 8 Conclusions nano-matrix. Scr
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228j Index l laser ablation 7 load
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