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Polymer Precursor-Based Preparation of Carbon Nanotube–Silicon Carbide Nanocomposites
Article first published online: 22 NOV 2011
© 2011 The American Ceramic Society
Journal of the American Ceramic Society
Volume 95, Issue 1, pages 328–337, January 2012
How to Cite
Clark, M. D., Walker, L. S., Hadjiev, V. G., Khabashesku, V., Corral, E. L., Krishnamoorti, R. (2012), Polymer Precursor-Based Preparation of Carbon Nanotube–Silicon Carbide Nanocomposites. Journal of the American Ceramic Society, 95: 328–337. doi: 10.1111/j.1551-2916.2011.04922.x
Based in part on the dissertation submitted by M. D. Clark for a PhD in Chemical Engineering, at the University of Houston, Houston, Texas 77204-4004, USA.
MDC and RK were supported by the Air Force Office for Sponsored Research and the National Science Foundation under grant number FA9550-06-1-0422 and CMMI-0708096, respectively. MDC was also partially supported by the U.S. Department of Education through a GAANN scholarship administered by UH. This work is supported by a National Science Foundation Early Faculty Career Award under a Division of Materials Research Award Number 0954110 (LSW and ELC).
- Issue published online: 3 JAN 2012
- Article first published online: 22 NOV 2011
- Manuscript Accepted: 8 OCT 2011
- Manuscript Received: 28 JUL 2011
- Air Force Office for Sponsored Research
- National Science Foundation. Grant Numbers: FA9550-06-1-0422, CMMI-0708096
- U.S. Department of Education
- National Science Foundation Early Faculty Career Award. Grant Number: 0954110
Multiwalled carbon nanotubes were dispersed in a silicon carbide matrix to examine nanotube influence on mechanical properties of the resulting composite. The ceramic matrix was generated through high temperature conversion of poly(methylsilyne), a preceramic polymeric precursor. Nanotube alkylation was explored using two functionalization schemes: organic peroxide workup and alkyllithium displacement of fluorinated nanotubes, which promoted extensive mixing within precursor solutions, thereby ensuring nanotube dispersion within the polymer matrix while facilitating interfacial bonding. The former scheme was less effective at displacing inner nanotube shell bound fluorine and resulted in lower alkyl chain grafting density on the outer shell. Polymer nanocomposites were pyrolyzed and consolidated using an optimized spark plasma sintering scheme to generate fully densified ceramics. The pure polymer-derived ceramic displayed exceptional Young's modulus and Vickers microhardness of 126 ± 12 and 9.6 ± 0.5 GPa, respectively, while maintaining a fracture toughness of 2.8 ± 0.3 MPa·m1/2. Increased sintering time further augmented the fracture toughness to 3.6 ± 0.4 MPa·m1/2, approaching the 4 MPa·m1/2 that characterizes pure silicon carbide, while maintaining both Young's modulus and microhardness. Nanotube addition resulted in some loss of the intrinsic mechanical properties, but enhanced monolith damage tolerance behavior, raising the Vickers indent force needed to induce cracks to an excess of 98.1 N in contrast to the pure polymer-derived sample, which began crack propagation below 49.0 N.