Heat treating carbon nanofibers for optimal composite performance

J.Y. Howe; G.G. Tibbetts; C. Kwag; M.L. Lake

doi:10.1557/jmr.2006.0325

Abstract

Partial graphitization of carbon nanofibers by high-temperature heat treatment can give improved composite properties. The intrinsic electrical conductivity of the bulk carbon nanofibers measured under compression is maximized by giving the fibers an initial heat treatment at 1500 °C. Similarly, for carbon nanofiber/polypropylene composites containing up to 12 vol% fiber, initial fiber heat treatments near 1500 °C give tensile modulus and strength superior even to composites made from fibers graphitized at 2900 °C. However, optimum composite conductivity is obtained with a somewhat lower heat-treatment temperature, near 1300 °C. Transmission electron microscopy (TEM) along with x-ray diffraction (XRD) explains these results, showing that heat treating the fibers alters the exterior planes from continuous, coaxial, and poorly crystallized to discontinuous nested conical crystallites inclined at about 25° to the fiber axis.

References

REFERENCES

1.Tibbetts, G.G., Doll, G.L., Gorkiewicz, D.W., Moleski, J.J., Perry, T.A., Dasch, C.J., Balogh, M.P.: Physical properties of vapor-grown carbon fibers. Carbon 31, 1039 (1993).Google Scholar

2.Koyama, T.: Formation of carbon fibers from benzene. Carbon 10, 757 (1970).CrossRef Google Scholar

3.Finegan, I.C., Tibbetts, G.G.: Electrical conductivity of vapor-grown carbon fiber/thermoplastic composites. J. Mater. Res. 16, 1668 (2001).Google Scholar

4.Science and Application of Nanotubes, edited by Tománek, D. and Enbody, R.J., (Kluwer, New York, 2000), p. 46.Google Scholar

5.Watt, W., Johnson:, W. in Proc. of the 3rd Conf. on Industrial Carbon and Graphite, edited by Gregory, J.G. and Rawlins, C.J. (Society of Chemical Industry, London, 1971) p. 417.Google Scholar

6.Gordeyev, S.A., Macedo, F.J., Ferreira, J.A., van Hattum, F.W.J., Bernardo, C.A.: Transport properties of polymer-vapour grown carbon fibre composites. Physica B (Amsterdam) 279, 33 (2000).CrossRef Google Scholar

7.Bernardo, C.A., Gordeyev, S.A., Ferreira, J.A. Tensile, electrical and thermal properties of vapour grown carbon fibre/thermoplastic composites, edited by Biro, L.P., Bernardo, C.A., Tibbetts, G.G., and Lambin, P. (NATO ASI Series Carbon Filaments and Nanotubes: Common Origins, Differing Applications? Kluwer Academic Publishers, Dordrecht, 2001), p. 301.Google Scholar

8.Tibbetts, G.G., McHugh, J.J.: Mechanical properties of vapor-grown carbon-fiber composites with thermoplastic matrices. J. Mater. Res. 14, 2871 (1999).CrossRef Google Scholar

9.Howe, J.Y., Rawn, C.J., Jones, L.E., Ow, H.: Improved crystallographic data for graphite. Powder Diffr. 18, 150 (2003).CrossRef Google Scholar

10.Howe, J.Y., Burchell, T.D., Lake, M.L. A study of graphitization of vapor grown carbon nanofibers using high-resolution TEM (Carbon '01, Beijing, China, 2001), (unpublished).Google Scholar

11.Finegan, I.C., Tibbetts, G.G., Glasgow, D.G., Ting, J-M., Lake, M.L.: Surface treatments for improving the mechanical properties of carbon nanofiber/thermoplastic composites. J. Mater. Sci. 38, 3485 (2003).Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

van Hattum, F. W. J. Leer, C. Viana, J. C. Carneiro, O. S. Lake, M. L. and Bernardo, C. A. 2006. Conductive long fibre reinforced thermoplastics by using carbon nanofibres. Plastics, Rubber and Composites, Vol. 35, Issue. 6-7, p. 247.

Yoon, Mina Howe, Jane Tibbetts, Gary Eres, Gyula and Zhang, Zhenyu 2007. Polygonization and anomalous graphene interlayer spacing of multi-walled carbon nanofibers. Physical Review B, Vol. 75, Issue. 16,

Sui, Gang Zhong, Wei‐Hong Fuqua, Mike A. and Ulven, Chad A. 2007. Crystalline Structure and Properties of Carbon Nanofiber Composites Prepared by Melt Extrusion. Macromolecular Chemistry and Physics, Vol. 208, Issue. 17, p. 1928.

Lee, Sungho Da, Shuang-Ye Ogale, Amod A. and Kim, Myung-Soo 2008. Effect of heat treatment of carbon nanofibers on polypropylene nanocomposites. Journal of Physics and Chemistry of Solids, Vol. 69, Issue. 5-6, p. 1407.

Khanna, Vikas Bakshi, Bhavik R. and James Lee, L. 2008. Assessing life cycle environmental implications of polymer nanocomposites. p. 1.

McNally, Tony Boyd, Peter McClory, Caroline Bien, Daniel Moore, Ian Millar, Bronagh Davidson, John and Carroll, Tony 2008. Recycled carbon fiber filled polyethylene composites. Journal of Applied Polymer Science, Vol. 107, Issue. 3, p. 2015.

Garcia, A.B. Cameán, I. Suelves, I. Pinilla, J.L. Lázaro, M.J. Palacios, J.M. and Moliner, R. 2009. The graphitization of carbon nanofibers produced by the catalytic decomposition of natural gas. Carbon, Vol. 47, Issue. 11, p. 2563.

Lake, Max Glasgow, D Tibbetts, Gary and Burton, D 2009. Polymer Nanocomposites Handbook.

Khanna, Vikas and Bakshi, Bhavik R. 2009. Carbon Nanofiber Polymer Composites: Evaluation of Life Cycle Energy Use. Environmental Science & Technology, Vol. 43, Issue. 6, p. 2078.

Parrott, Edward P. J. Zeitler, J. Axel McGregor, James Oei, Shu-Pei Unalan, Husnu Emrah Tan, Swee-Ching Milne, William I. Tessonnier, Jean-Philippe Schlögl, Robert and Gladden, Lynn F. 2009. Understanding the Dielectric Properties of Heat-Treated Carbon Nanofibers at Terahertz Frequencies: a New Perspective on the Catalytic Activity of Structured Carbonaceous Materials. The Journal of Physical Chemistry C, Vol. 113, Issue. 24, p. 10554.

Mahanta, Nayandeep K. Abramson, Alexis R. Lake, Max L. Burton, David J. Chang, John C. Mayer, Helen K. and Ravine, Jessica L. 2010. Thermal conductivity of carbon nanofiber mats. Carbon, Vol. 48, Issue. 15, p. 4457.

Lee, Sung-Ho Hahn, Jae-Ryang Ku, Bon-Cheol and Kim, Jun-Kyung 2011. Effect of Carbon Nanofiber Structure on Crystallization Kinetics of Polypropylene/Carbon Nanofiber Composites. Bulletin of the Korean Chemical Society, Vol. 32, Issue. 7, p. 2369.

Memon, Muhammad Omar Haillot, Sylvain and Lafdi, Khalid 2011. Carbon nanofiber based buckypaper used as a thermal interface material. Carbon, Vol. 49, Issue. 12, p. 3820.

2012. Polymer Composites with Carbonaceous Nanofillers. p. 1.

Merugula, Laura Khanna, Vikas and Bakshi, Bhavik R. 2012. Reinforced Wind Turbine Blades - An Environmental Life Cycle Evaluation. Environmental Science & Technology, Vol. 46, Issue. 17, p. 9785.

Bruce, Charles W. and Alyones, Sharhabeel 2012. Visible and infrared optical properties of stacked cone graphite microtubes. Applied Optics, Vol. 51, Issue. 16, p. 3250.

Howe, Jane Y. Burton, David J. Qi, Yue Meyer, Harry M. Nazri, Maryam Nazri, G. Abbas Palmer, Andrew C. and Lake, Patrick D. 2013. Improving microstructure of silicon/carbon nanofiber composites as a Li battery anode. Journal of Power Sources, Vol. 221, Issue. , p. 455.

Tjong, Sie Chin 2013. Recent progress in the development and properties of novel metal matrix nanocomposites reinforced with carbon nanotubes and graphene nanosheets. Materials Science and Engineering: R: Reports, Vol. 74, Issue. 10, p. 281.

Ramos, Alberto Cameán, Ignacio and García, Ana B. 2013. Graphitization thermal treatment of carbon nanofibers. Carbon, Vol. 59, Issue. , p. 2.

Ramos, Alberto Cameán, Ignacio Cuesta, Nuria and García, Ana B. 2014. Graphitized stacked-cup carbon nanofibers as anode materials for lithium-ion batteries. Electrochimica Acta, Vol. 146, Issue. , p. 769.

Download full list

Article contents

Heat treating carbon nanofibers for optimal composite performance

Abstract

Keywords

Access options

References

REFERENCES

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Heat treating carbon nanofibers for optimal composite performance

Abstract

Keywords

Access options

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests