Carbon Nanotube Reinforced Composites: Metal and Ceramic ...
Carbon Nanotube Reinforced Composites: Metal and Ceramic ...
Carbon Nanotube Reinforced Composites: Metal and Ceramic ...
Create successful ePaper yourself
Turn your PDF publications into a flip-book with our unique Google optimized e-Paper software.
22 Orowan, E. (1942) A type of plastic<br />
deformation new in metals. Nature, 149,<br />
643–644.<br />
23 Kochs, U.F. (1966) Spacing of dispersed<br />
obstacles. Acta <strong>Metal</strong>lurgica, 14,1629–1631.<br />
24 Hassan, S.F. <strong>and</strong> Gupta, M. (2006) Effect of<br />
type of primary processing on the<br />
microstructure, CTE <strong>and</strong> mechanical<br />
properties of magnesium/alumina<br />
nanocomposites. Composite Structures, 72,<br />
19–26.<br />
25 Hassan, S.F. <strong>and</strong> Gupta, M. (2007)<br />
Development of nano-Y 2O 3 containing<br />
magnesium nanocomposites using<br />
solidification processing. Journal of Alloys<br />
<strong>and</strong> Compounds, 429, 176–183.<br />
26 Tun, K.S. <strong>and</strong> Gupta, M. (2007) Improving<br />
mechanical properties of magnesium<br />
using nano-yttria reinforcement <strong>and</strong><br />
microwave assisted powder metallurgy<br />
method. <strong>Composites</strong> Science <strong>and</strong> Technology,<br />
67, 2657–2664.<br />
27 Archard, F. (1953) Contact <strong>and</strong> rubbing of<br />
flat surfaces. Journal of Applied Physics, 24,<br />
981–988.<br />
28 Suh, N.P. (1977) Overview of delamination<br />
theory of wear. Wear, 44, 1–16.<br />
29 Riahi, A.R. <strong>and</strong> Alpas, A.T. (2001) The role<br />
of tribo-layers on the sliding wear behavior<br />
of graphitic aluminum matrix composites.<br />
Wear, 251, 1396–1407.<br />
30 Akhlaghi, F. <strong>and</strong> Pelaseyyed, S.A. (2004)<br />
Characterization of aluminum/graphite<br />
particulate composites synthesized using a<br />
novel method termed in-situ powder<br />
metallurgy . Materials Science <strong>and</strong><br />
Engineering A, 385, 258–266.<br />
31 Flores-Zamora, M.I., Estrada-Guel, I.,<br />
Gonzalez-Hern<strong>and</strong>ez, J., Miki-Yoshida, M.<br />
<strong>and</strong> Martinez-Sanchez, R. (2007)<br />
Aluminum-graphite composite produced<br />
by mechanical milling <strong>and</strong> hot extrusion.<br />
Journal of Alloys <strong>and</strong> Compounds, 434–435,<br />
518–521.<br />
32 Kestursatya, M., Kim, J.K. <strong>and</strong> Rohatgi,<br />
P.K. (2003) Wear performance of coppergraphite<br />
composite <strong>and</strong> a leaded copper<br />
alloy. Materials Science <strong>and</strong> Engineering A,<br />
339, 150–158.<br />
Referencesj129<br />
33 Chen, X., Zhang, G., Chen, C., Zhou, L., Li,<br />
S. <strong>and</strong> Li, X. (2003) <strong>Carbon</strong> nanotube<br />
composite deposits with high hardness<br />
<strong>and</strong> high wear resistance. Advanced<br />
Engineering Materials, 5, 514–518.<br />
34 Wu, S.Q., Zhu, H.G. <strong>and</strong> Tjong, S.C.<br />
(1999) Wear behavior of in-situ Al-based<br />
composites containing TiB2, Al2O3 <strong>and</strong><br />
Al3Ti particles. Materials Science <strong>and</strong><br />
Engineering A, 30, 243–248.<br />
35 Tjong, S.C. <strong>and</strong> Lau, K.C. (2000) Dry<br />
sliding wear of TiB2 particle-reinforced<br />
aluminum alloy composites. Materials<br />
Science & Technology, 16, 99–102.<br />
36 Bhushan, B. <strong>and</strong> Sundararajan, S. (1998)<br />
Micro/nanoscle friction <strong>and</strong> wear<br />
mechanisms of thin films using atomic<br />
force <strong>and</strong> friction force microscopy. Acta<br />
Materialia, 46, 3793–3804.<br />
37 Bhushan, B. (2001) Nano- to microscale<br />
wear <strong>and</strong> mechanical characterization<br />
using scanning probe microscopy. Wear,<br />
251, 1105–1123.<br />
38 Bhushan, B. (2008) Nanotribology of<br />
carbon nanotubes. Journal of Physics:<br />
Condensed Matter, 20, 3652141–36521414.<br />
39 L<strong>and</strong>man, U., Luedtke, W.D., Burham,<br />
N.A. <strong>and</strong> Colton, R.J. (1990) Atomistic<br />
mechanisms <strong>and</strong> dynamics of adhesion,<br />
nanoindentation <strong>and</strong> fracture. Science, 248,<br />
454–461.<br />
40 Buldum, A. <strong>and</strong> Lu, J.P. (1999) Atomic scale<br />
sliding <strong>and</strong> rolling of carbon nanotubes.<br />
Physical Review Letters, 83, 5050–5053.<br />
41 Ni, B. <strong>and</strong> Sinnott, S.B. (2001) Tribological<br />
properties of carbon nanotubes bundles<br />
predicted from atomistic simulations.<br />
Surface Science, 487, 87–96.<br />
42 Falvo, M.R., Taylor, R.M. II, Helser, A., Chi,<br />
V. Jr, Brooks, F.P., Washburn, S. <strong>and</strong><br />
Superfine, R. (1999) Nanometre-scale<br />
rolling <strong>and</strong> sliding of carbon nanotubes.<br />
Science, 397, 236–238.<br />
43 Bhushan, B., Gupta, B.K., Van Cleef, G.W.,<br />
Capp, C. <strong>and</strong> Coe, J.V. (1993) Fullerene<br />
(C60) films for solid lubrication. Tribology<br />
Transactions, 36, 573–580.<br />
44 Zhang, P., Lu, J., Xue, Q. <strong>and</strong> Liu, W. (2001)<br />
Microfrictional behavior of C 60 particles in