Carbon Nanotube Reinforced Composites: Metal and Ceramic ...
Carbon Nanotube Reinforced Composites: Metal and Ceramic ...
Carbon Nanotube Reinforced Composites: Metal and Ceramic ...
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6 Fischer, H., Waindich, A. <strong>and</strong> Telle, R.<br />
(2008) Influence of preparation of ceramic<br />
SEVNB specimens on fracture toughness<br />
testing results. Dental Materials, 24,<br />
618–622.<br />
7 Picard, D., Lequillon, D. <strong>and</strong> Putot, C.<br />
(2006) A method to estimate the influence<br />
of the notch-root radius on the fracture<br />
toughness measurement of ceramics.<br />
Journal of the European <strong>Ceramic</strong> Society,<br />
26, 1421–1427.<br />
8 Nishida, T., Hanaki, Y. <strong>and</strong> Pezzotti, G.<br />
(1994) Effect of notch-root radius on the<br />
fracture toughness of a fine-grained<br />
alumina. Journal of the American <strong>Ceramic</strong><br />
Society, 77, 606–608.<br />
9 Hertzberg, R.W. (1989) Deformation <strong>and</strong><br />
Fracture Mechanics of Engineering Materials,<br />
Wiley, New York.<br />
10 Kubler, J. (1997) Fracture toughness of<br />
ceramics using the SEVNB method:<br />
Preliminary results. <strong>Ceramic</strong> Engineering<br />
<strong>and</strong> Science Proceedings, 18, 155–162.<br />
11 Sakai, M. <strong>and</strong> Bradt, R.C. (1993)<br />
Fracture toughness testing of brittle<br />
materials. International Materials Reviews,<br />
38, 53–78.<br />
12 Antis, G.R., Chantikul, P., Lawn, B.R. <strong>and</strong><br />
Marshall, D.B. (1981) A critical evaluation<br />
of indentation techniques for measuring<br />
fracture toughness: I., Direct crack<br />
measurements. Journal of the American<br />
<strong>Ceramic</strong> Society, 64, 533–538.<br />
13 Chantikul, P., Antis, G.R., Lawn, B.R. <strong>and</strong><br />
Marshall, D.B. (1981) A critical evaluation<br />
of indentation techniques for measuring<br />
fracture toughness: II, Strength methods.<br />
Journal of the American <strong>Ceramic</strong> Society,<br />
64, 539–543.<br />
14 Niihara, K. (1983) Indentation fracture<br />
toughness of brittle materials for<br />
Palmqvist cracks, in Fracture Mechanics<br />
of <strong>Ceramic</strong>s, vol. 5 (eds R.C. Bradt<br />
<strong>and</strong> M. Sakai), Plenum, New York,<br />
pp. 97–105.<br />
15 Niihara, K. (1983) A fracture mechanics<br />
analysis of indentation-induced Palmqvist<br />
cracks in ceramics. Journal of Materials<br />
Science Letters, 2, 221–223.<br />
Referencesj213<br />
16 Miyoshi, T. (1985) A study on evaluation of<br />
KIC for structural ceramics. Transactions of<br />
the Japan Society of Mechanical Engineers,<br />
Series A, 51, 2489–2497.<br />
17 Quinn, G.D. <strong>and</strong> Bradt, R.C. (2007) On the<br />
Vickers indentation fracture toughness<br />
test. Journal of the American <strong>Ceramic</strong><br />
Society, 90, 673–680.<br />
18 Fischer, H. <strong>and</strong> Marx, R. (2002) Fracture<br />
toughness of dental ceramics: Comparison<br />
of bending <strong>and</strong> indentation method.<br />
Dental Materials, 18, 12–19.<br />
19 Maensiri, S., Laokul, P., Klinkaewnarong,<br />
J. <strong>and</strong> Amornkitbamrung, V. (2007)<br />
<strong>Carbon</strong>-nanofiber-reinforced alumina<br />
nanocomposites: Fabrication <strong>and</strong><br />
mechanical properties. Materials Science<br />
<strong>and</strong> Engineering A, 447, 44–50.<br />
20 Liu, T.X., Phang, I.Y., Shen, L. <strong>and</strong> Liu, T.X.<br />
(2004) <strong>Carbon</strong> nanotubes reinforced nylon<br />
6 composite prepared by simple meltcompounding.<br />
Macromolecules, 37,<br />
7214–7222.<br />
21 Wang, X., Padture, N.P. <strong>and</strong> Tanaka, H.<br />
(2004) Contact-damage-resistant<br />
ceramic/single-wall carbon nanotubes <strong>and</strong><br />
ceramic/graphite composites. Nature<br />
Materials, 3, 539–544.<br />
22 Padture, N.P. <strong>and</strong> Curtin, W.A. (2008)<br />
Comment on Effect of sintering<br />
temperature on a single-wall carbon<br />
nanotube toughened alumina-based<br />
nanocomposite . Scripta Materialia, 58,<br />
989–990.<br />
23 Jiang, D. <strong>and</strong> Mukherjee, A.K. (2008)<br />
Response to comment on Effect of<br />
sintering temperature on single-wall<br />
carbon nanotube toughened aluminabased<br />
nanocomposite . Scripta Materialia,<br />
58, 991–993.<br />
24 Chen, Y., Balani, K. <strong>and</strong> Agarwal, A. (2008)<br />
Analytical model to evaluate interface<br />
characteristics of carbon nanotube<br />
reinforced aluminum oxide<br />
nanocomposites. Applied Physics Letters,<br />
92, 0119161–0119163.<br />
25 Guo, S., Sivakumar, R. <strong>and</strong> Kagawa, Y.<br />
(2007) Multiwall carbon nanotube-SiO2<br />
nanocomposites: Sintering, elastic