Carbon Nanotube Reinforced Composites: Metal and Ceramic ...

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22 Orowan, E. (1942) A type of plastic deformation new in metals. Nature, 149, 643–644. 23 Kochs, U.F. (1966) Spacing of dispersed obstacles. Acta Metallurgica, 14,1629–1631. 24 Hassan, S.F. and Gupta, M. (2006) Effect of type of primary processing on the microstructure, CTE and mechanical properties of magnesium/alumina nanocomposites. Composite Structures, 72, 19–26. 25 Hassan, S.F. and Gupta, M. (2007) Development of nano-Y 2O 3 containing magnesium nanocomposites using solidification processing. Journal of Alloys and Compounds, 429, 176–183. 26 Tun, K.S. and Gupta, M. (2007) Improving mechanical properties of magnesium using nano-yttria reinforcement and microwave assisted powder metallurgy method. Composites Science and Technology, 67, 2657–2664. 27 Archard, F. (1953) Contact and rubbing of flat surfaces. Journal of Applied Physics, 24, 981–988. 28 Suh, N.P. (1977) Overview of delamination theory of wear. Wear, 44, 1–16. 29 Riahi, A.R. and Alpas, A.T. (2001) The role of tribo-layers on the sliding wear behavior of graphitic aluminum matrix composites. Wear, 251, 1396–1407. 30 Akhlaghi, F. and Pelaseyyed, S.A. (2004) Characterization of aluminum/graphite particulate composites synthesized using a novel method termed in-situ powder metallurgy . Materials Science and Engineering A, 385, 258–266. 31 Flores-Zamora, M.I., Estrada-Guel, I., Gonzalez-Hernandez, J., Miki-Yoshida, M. and Martinez-Sanchez, R. (2007) Aluminum-graphite composite produced by mechanical milling and hot extrusion. Journal of Alloys and Compounds, 434–435, 518–521. 32 Kestursatya, M., Kim, J.K. and Rohatgi, P.K. (2003) Wear performance of coppergraphite composite and a leaded copper alloy. Materials Science and Engineering A, 339, 150–158. Referencesj129 33 Chen, X., Zhang, G., Chen, C., Zhou, L., Li, S. and Li, X. (2003) Carbon nanotube composite deposits with high hardness and high wear resistance. Advanced Engineering Materials, 5, 514–518. 34 Wu, S.Q., Zhu, H.G. and Tjong, S.C. (1999) Wear behavior of in-situ Al-based composites containing TiB2, Al2O3 and Al3Ti particles. Materials Science and Engineering A, 30, 243–248. 35 Tjong, S.C. and Lau, K.C. (2000) Dry sliding wear of TiB2 particle-reinforced aluminum alloy composites. Materials Science & Technology, 16, 99–102. 36 Bhushan, B. and Sundararajan, S. (1998) Micro/nanoscle friction and wear mechanisms of thin films using atomic force and friction force microscopy. Acta Materialia, 46, 3793–3804. 37 Bhushan, B. (2001) Nano- to microscale wear and mechanical characterization using scanning probe microscopy. Wear, 251, 1105–1123. 38 Bhushan, B. (2008) Nanotribology of carbon nanotubes. Journal of Physics: Condensed Matter, 20, 3652141–36521414. 39 Landman, U., Luedtke, W.D., Burham, N.A. and Colton, R.J. (1990) Atomistic mechanisms and dynamics of adhesion, nanoindentation and fracture. Science, 248, 454–461. 40 Buldum, A. and Lu, J.P. (1999) Atomic scale sliding and rolling of carbon nanotubes. Physical Review Letters, 83, 5050–5053. 41 Ni, B. and Sinnott, S.B. (2001) Tribological properties of carbon nanotubes bundles predicted from atomistic simulations. Surface Science, 487, 87–96. 42 Falvo, M.R., Taylor, R.M. II, Helser, A., Chi, V. Jr, Brooks, F.P., Washburn, S. and Superfine, R. (1999) Nanometre-scale rolling and sliding of carbon nanotubes. Science, 397, 236–238. 43 Bhushan, B., Gupta, B.K., Van Cleef, G.W., Capp, C. and Coe, J.V. (1993) Fullerene (C60) films for solid lubrication. Tribology Transactions, 36, 573–580. 44 Zhang, P., Lu, J., Xue, Q. and Liu, W. (2001) Microfrictional behavior of C 60 particles in
130j 4 Mechanical Characteristics of Carbon Nanotube–Metal Nanocomposites different C60 LB films by AFM/FFM. Langmuir, 17, 2143–2145. 45 Chen, W.X., Tu, J.P., Wang, L.Y., Gan, H.Y., Xu, Z.D. and Zhang, X.B. (2003) Tribological application of carbon nanotubes in a metal-based composite coating and composites. Carbon, 41, 215–222. 46 Dong, S.R., Tu, J.P. and Zhang, X.B. (2001) An investigation of the sliding wear behavior of Cu-matrix composite reinforced by carbon nanotubes. Materials Science and Engineering A, 313, 83–87. 47 Chen, X.H., Chen, C.S., Xiao, H.N., Liu, H.B., Zhou, L.P., Li, S.L. and Zhang, G. (2006) Dry sliding and wear characteristics of nickel/carbon nanotube electrodeless composite deposits. Tribology International, 39, 22–28. 48 Li, Z.H., Wang, X.Q., Wang, M., Wang, F.F. and Ge, H.L. (2006) Preparation and tribological properties of the carbon nanotubes-Ni-P composite coating. Tribology International, 39, 953–957. 49 Wang, L.Y., Tu, J.P., Chen, W.X., Wang, Y.C., Liu, X.K., Olk, C., Cheng, D.H. and Zhang, X.B. (2003) Friction and wear behavior of electrodeless Ni-based CNT composite coating. Wear, 254, 1289–1293.
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Sie Chin Tjong Carbon Nanotube Rein
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Sie Chin Tjong Carbon Nanotube Rein
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Contents Preface IX List of Abbrevi
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5 Carbon Nanotube-Ceramic Nanocompo
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Preface Carbon nanotubes are nanost
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XII List of Abbreviations HIP hot i
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1 Introduction 1.1 Background Compo
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Figure 1.2 Transmission electron mi
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1.3 Synthesis of Carbon Nanotubes 1
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MWNTs can be as high as 70% of the
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Figure 1.7 In situ TEM images recor
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1.3 Synthesis of Carbon Nanotubesj1
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show TEM images of MWNTs synthesize
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Since then, large efforts have been
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1.3.4 Patent Processes Carbon nanot
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1.4 Purification of Carbon Nanotube
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Table 1.3 Patent processes for the
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Figure 1.13 Schematic illustration
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1.5 Mechanical Properties of Carbon
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Figure 1.14 Carbon nanotubes in hig
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Figure 1.15 In situ tensile deforma
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Table 1.7 Theoretical and experimen
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Nomenclature ~a 1 , ~a 2 Unit vecto
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carbon nanotubes. Physical Review L
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70 Jang, I., Uh, H.S., Cho, H.J., L
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108 Shelimov, K.B., Esenaliev, R.O.
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Bonnamy, S., Beguin, F., Burnham, N
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2 Carbon Nanotube-Metal Nanocomposi
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isostatic pressing. In certain case
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This implies the absence of effecti
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coating material, the plasma gun an
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Table 2.4 Changes in the size and v
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Figure 2.6 (a) Low and (b) high mag
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Figure 2.8 SEM micrographs showing
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Figure 2.11 Bright field TEM microg
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Figure 2.13 TEM image of bulk Al/5
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2.5 Magnesium-Based Nanocomposites
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limited improvement in ultimate ten
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Figure 2.18 SEM micrographs of the
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Figure 2.19 (a) Low and (b) high ma
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Figure 2.22 SEM micrographs of (a)
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Figure 2.25 (a) TEM micrograph show
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2.8 Transition Metal-Based Nanocomp
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Figure 2.27 TEM image of electrodep
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Figure 2.29 SEM micrographs of (a)
Page 94 and 95: Figure 2.31 Schematic representatio
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Page 98 and 99: Materials Science Forum, 534-536 (P
Page 100 and 101: composite. Materials Science and En
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Page 115 and 116: 100j 3 Physical Properties of Carbo
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180j 6 Physical Properties of Carbo
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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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