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Review Article

A Review of the Application of CNTs in PEM Fuel Cells

Santanu MukherjeeDepartment of Mechanical Engineering, University of Louisville, Louisville, Kentucky, USA
,
Alex BatesDepartment of Mechanical Engineering, University of Louisville, Louisville, Kentucky, USA
,
Sang C. LeeDaegu Gyeongbuk Institute of Science and Technology, Daegu, Korea
,
Dong-Ha LeeDaegu Gyeongbuk Institute of Science and Technology, Daegu, Korea
&
S. ParkDepartment of Mechanical Engineering, University of Louisville, Louisville, Kentucky, USACorrespondence[email protected]
Pages 787-809 | Published online: 18 Mar 2015

References

  • Ackers, N., and S. Minteer. 2003. Towards the development of a Membrane Electrode Assembly (MEA) style biofuel cell. American Chemical Society 48:895–96.
  • Andersen, S. Ma, M. Borghei, P. Lund, Y.-R. Elina, A. Pasanen, E. Kauppinen, V. Ruiz, P. Kauranen, and E. M. Skou. 2013. Durability of carbon nanofiber (CNF) & carbon nanotube (CNT) as catalyst support for Proton Exchange Membrane Fuel Cells. Solid State Ionics 231:94–101.
  • Antolini, E. 2009. Carbon supports for low-temperature fuel cell catalysts. Applied Catalysis: B 88:1–24.
  • Antolini, E., R. R. Passos, and E. A. Ticianelli. 2002. Effects of the carbon powder characteristics in the cathode gas diffusion layer on the performance of polymer electrolyte fuel cells. Journal of Power Sources 109:477–82.
  • Atkinson, A., S. Barnett, R. J. Gorte, J. T. S. Irvine, A. J. McEvoy, M. Mogensen, S. C. Singhal, and J. Vohs. 2004. Advanced anodes for high-temperature fuel cells. Nature Materials 3:17–27.
  • Banis, M. N., S. Sun, X. Meng, Y. Zhang, Z. Wang, R. Li, M. Cai, T.-K. Sham, and X. Sun. 2013. TiSi2Ox Coated N-Doped Carbon Nanotubes as Pt Catalyst Support for the Oxygen Reduction Reaction in PEMFCs. The Journal of Physical Chemistry C 117:15457–67.
  • Barbir, F., and T. Gomez. 1997. Efficiency and economics of proton exchange membrane (PEM) fuel cells. International Journal of Hydrogen Energy 22:1027–37.
  • Baughman, R. H., A. A. Zakhidov, and W. A. de Heer. 2002. Carbon nanotubes–the route toward applications. Science 297(5582):787–92.
  • Benziger, J., J. Nehlsen, D. Blackwell, T. Brennan, and J. Itescu. 2005. Water flow in the gas diffusion layer of PEM fuel cells. Journal of Membrane Science 261(1–2):98–106.
  • Berg, P., K. Promislow, J. St. Pierre, J. Stumper, and B. Wetton. 2004. Water Management in PEM Fuel Cells. Journal of the Electrochemical Society 151 (3):A341–A353.
  • Bezerra, C. W. B., L. Zhang, K. Lee, H. Liu, A. L. B. Marques, E. P. Marques, H. Wang, and J.Zhang. 2008. Electrochimica Acta 53:4937.
  • Boyer, C., S. Gamburzev, O. Velev, S. Srinivasan, and A. J. Appleby. 1998. Measurements of proton conductivity in the active layer of PEM fuel cell gas diffusion electrodes. Electrochimica Acta 43 (24):3703–709.
  • Cagin, J. C. T., and W. A. Goddard III. 2000 Thermal conductivity of carbon nanotubes. Nanotechnology 11:65–9.
  • Caillard, A., C. Charles, R. Boswell, P. Brault, and C. Coutanceau. 2007. Plasma based platinum nanoaggregates deposited on carbon nanofibers improve fuel cell efficiency. Applied Physics Letters 90:223119-1-223119-3.
  • Candelaria, S. L., Y. Shao, W. Zhou, X. Li, J. Xiao, J.-G. Zhang, Y. Wang, J. Liu, J. Li, and G. Cao. 2011. Nanostructured carbon for energy storage and conversion. Nano Energy 1:195–20.
  • Candelaria, S., Y. Shao, W. Zhou, X. Li, J. Xiao, J. G. Zhang, Y. Wang, J. Liu, J. Li, and G. Cao. 2012. Nanostructured carbon for energy storage and conversion. Nano Energy 1:195–20.
  • Cassell, A. M., J. A. Raymakers, J. Kong, and H. Dai. 1999. Large scale CVD synthesis of single-walled carbon nanotubes. Journal of Physical Chemistry B 103:6484–92.
  • Cha, S. Y., and W. M. Lee. 1999. Performance of proton exchange membrane fuel cell electrodes prepared by direct deposition of ultrathin platinum on the membrane surface. Journal of the Electrochemical Society 146(11):4055–60.
  • Che, G., B. B. Lakshmi, C. R. Martin, R. S. Ruoff, and E. R. Fisher. 1998. Chemical vapor deposition based synthesis of carbon nanotubes and nanofibers using a template method. Chemistry of Materials 10:260–67.
  • Chen, Y., J. Wang, H. Liu, M. N. Banis, R. Li, X. Sun, T.-K. Sham, S. Ye, and S. Knights. 2011. Nitrogen doping effects on carbon nanotubes and the origin of the enhanced electrocatalytic activity of supported Pt for proton-exchange membrane fuel cells. The Journal of Physical Chemistry C 115:3769–76.
  • Cindrella, L., A. M. Kannan, J. F. Lin, K. Saminathan, Y. Ho, C. W. Lin, and J. Wertz. 2009. Gas diffusion layer for proton exchange membrane fuel cells—A review. Journal of Power Sources 194:146–60.
  • Coleman, J. N., U. Khan, W. J. Blau, and Y. K. Gun’ko. 2006. Small but strong: A review of the mechanical properties of carbon nanotube–polymer composites. Carbon 44 (9):1624–52.
  • Daenen, M., R. D. de Fouw, B. Hamers, P. G. A. Janssen, K. Schouteden, and M. A. J. Veld. 2003. The Wondrous World of Carbon Nanotubes, ‘A Revew of Current Carbon Nanotube Technologies’. Eindhoven, Netherlands: Eindhoven University of Technology.
  • Dai, H. 2002. Carbon Nanotubes: Synthesis, Integration and Properties. Accounts of Chemical Research 35(12):1035–44.
  • Daping, H., S. Mu, and M. Pan. 2011. Perfluorosulfonic acid-functionalized Pt/carbon nanotube catalysts with enhanced stability and performance for use in proton exchange membrane fuel cells. Carbon 49 (1):82–88.
  • Darkrim, F. L., P. Malbrunot, and G. P. Tartaglia. 2002. Review of hydrogen storage by adsorption in carbon nanotubes. International Journal of Hydrogen Energy 27(2):193–202.
  • Debe, M. K., A. K. Schmoeckel, G. D. Vernstrom, and R. Atanasoski. 2006. High voltage stability of nanostructured thin film catalysts for PEM fuel cells. Journal of Power Sources 161(2):1002–11.
  • deBruijn, F. A., V. A. T. Dam, and G. J. M. Janssen. 2008. Review: Durability and degradation issues of PEM fuel cell components. Fuel Cells 8 (1):3–22.
  • Dhakate, S. R., S. Sharma, N. Chauhan, R.K Seth, and R. B. Mathur. 2010. CNT’s nanostructuring effecton the properties of graphitecomposite bipolar plate. International Journal of Hydrogen Energy 35:4195–200.
  • Dicks, A. L. 2006. The role of carbon in fuel cells. Journal of Power Sources 156 (2):142–50.
  • Dresselhaus, M. S., G. Dresselhaus, J. C. Charlier, and E. Hernandez. 2004. Electronic, thermal and mechanical properties of carbon nanotubes. The Royal Society 2065–98.
  • Du, J-H., J. Bai, and H.-M. Cheng. 2007. The present status and key problems of carbon nanotube based polymer composites. eXPRESS Polymer Letters 1(5):253–73.
  • Du, C., M. Chen, X. Cao, G. Yin, and P. Shi. 2009. A novel CNT@SnO2 core–sheath nanocomposite as a stabilizing support for catalysts of proton exchange membrane fuel cells. Electrochemistry Communications 11:496–98.
  • Du, C., B. Wang, and X. Cheng. 2009. Hierarchy carbon paper for the gas diffusion layer of proton exchange membrane fuel cells. Journal of Power Sources 187(2):505–508.
  • Duca, D., F. Ferrante, and G. La Manna. 2007. Theoretical study of palladium cluster structures on carbonaceous supports. The Journal of Physical Chemistry C 111 (14): 5402.
  • Dujardin, E, T. Ebbesen, H. Hiura, and K. Tanigaki. 1994. Capillarity and wetting of carbon nanotubes. Science 265:1850–52.
  • Dujardin, E., T. Ebbesen, A. Krishnan, and M. Treacy. 1998. Wetting of single shell carbon nanotubes. Advanced Materials 10(17):1472–1475.
  • Eitan, A., K. Jiang, D. Dukes, R. Andrews, and L. S. Schadler. 2003. Surface modification of multiwalled carbon nanotubes: Toward the tailoring of the interface in polymer composites. Chemistry of Materials 15:3198–201.
  • Endo, M., T. Hayashi, Y. A. Kim, and H. Muramatsu. 2008. Development and application of carbon nanotubes. Japanese Journal of Applied Physics 45:1–9.
  • Energy, US Department of. 2011. Fuel cell technologies program. Energy Efficiency and Renewable Energy 44:1–118.
  • Esmaeilifar, A., S. Rowshanzamir, M. H. Eikani, and E. Ghazanfari. 2010. Synthesis methods of low-Pt-loading electrocatalysts for proton exchange membrane fuel cell systems. Energy 35:3941–57.
  • Feng, Y., Ningning F., and G. Du. 2012. Wearable carbon nanotube fibers for energy storage. International Journal of Electrochemical Science 7:12432–39.
  • Fiala, R., I. Khalakhan, I. Matolínová, M. Václavů, M. Vorokhta, Z. Sofer, S. Huber, V. Potin, and V. Matolín. 2011. Pt-CeO2 coating of carbon nanotubes grown on anode gas diffusion layer of the polymer electrolyte membrane fuel cell. Journal for Nanoscience and Nanotechnology 11(6):5062–67.
  • Firouzi, A., S. Sobri, F. M. Yasin, and F.-R. Ahmadun. 2010a. CH4 and CO2 detection using carbon nanotube-based sensors. Advanced Materials Research 214:482–489.
  • Firouzi, A., S. Sobri, F. M. Yasin, and F.-r. b. Ahmadun. 2010b. The effect of CH4 and CO2 exposure on carbon nanotubes electrical resistance. Advanced Materials Research, 214:655–661.
  • Frost, G. J. K., J. C. Acres, G. A. Hards, R. J. Potter, T. R. ralph, and D. Thompsett. 1997. Electrocatalysts for fuel cells. Catalysis Today 38:393–400.
  • Fujigayaa, T., M. Okamotoa, and N. Nakashima. 2009. Design of an assembly of pyridine-containing polybenzimidazole, carbon nanotubes and Pt nanoparticles for a fuel cell electrocatalyst with a high electrochemically active surface area. Carbon 47:3227–32.
  • Gao, Y., G. Q. Sun, S. L. Wang, and S. Zhu. 2010. Carbon nanotubes based gas diffusion layers in direct methanol fuel cells. Energy 35(3):1455–59.
  • Garg, A., and S. Sinnott. 1998. Effect of chemical functionalization on the mechanical properties of carbon nanotubes. Chemical Physics Letters 295 (4):273–78.
  • Ge, J., A. Higier, and H. Liu. 2006. Effect of gas diffusion layer compression on PEM fuel cell performance. Journal of Power Sources 159(2):922–27.
  • Girishkumar, G., M. Rettker, R. Underhile, D. Binz, K. Vinodgopal, P. McGinn, and P. Kamat. 2005. Single-wall carbon nanotube-based proton exchange membrane assembly for hydrogen fuel cells. Langmuir 21(18):8487–94.
  • Gong, K., F. Du, Z. Xia, M. Durstock, and L. Dai. 2009. Nitrogen-doped carbon nanotube arrays with high electrocatalytic activity for oxygen reduction. Science 323:760–64.
  • Grundler, M., T. Derieth, P. Beckhaus, and A. Heinzel. 2010. CarbonNanoTubes (CNT) in bipolar plates for PEM fuel cell applications. 18th World Hydrogen Energy Conference, Essen, Germany, May 16–21.
  • Guha, A., W. Lu, T. A. Zawodzinski Jr., and D. A. Schiraldi. 2007. Surface-modified carbons as platinum catalyst support for PEM fuel cells. Carbon 45:1506–17.
  • Guo, J., G. Sun a, Q. Wang, G. Wang, Z. Zhou, S. Tang, L. Jiang, B. Zhou, and Q. Xin. 2006. Carbon nanofibers supported Pt–Ru electrocatalysts for direct methanol fuel cells. Carbon 44:152–57.
  • Gutierrez, M. C., M. J. Hortiguela, J. M. Amarilla, R. Jimenez, M. L. Ferrer, and F. del Monte. 2007. Macroporous 3D architectures of self-assembled MWCNT surface decorated with Pt nanoparticles as anodes for a direct methanol fuel cell. The Journal of Physical Chemistry C 111:5557–60.
  • Han, M., S. H. Chan, and S. P. Jiang. 2006. Development of carbon-filled gas diffusion layer for polymer electrolyte fuel cells. Journal of Power Sources 159:1005–14.
  • Hickner, M. A., H. Ghassemi, Y. S. Kim, B. R. Einsla, and J. E. McGrath. 2004. Alternative Polymer Systems for Proton Exchange Membranes (PEMs). Chemical Review 104:4587–12.
  • Higgins, D. C., D. Meza, and Z. Chen. 2010. Nitrogen-doped carbon nanotubes as platinum catalyst supports for oxygen reduction reaction in proton exchange membrane fuel cells. Journal of Physical Chemistry 114(50):21982–88.
  • Hilding, J. M. 2004. Characterization and Applications of Multiwalled Carbon Nanotubes. Lexington: Chemical Engineering, University of Kentucky.
  • Hinds, B. 2012. Current opinion in solid state and materials science. Dramatic Transport Properties of Carbon Nanotube Membranes for a Robust Protein Channel Mimetic Platform 16:1–9.
  • Hoa, L. Q., M. C. Vestergaard, H. Yoshikawa, M. Saitoa, and E. Tamiya. 2012. Enhancing catalytic performance of Pt-based electrodes with a noncovalent interaction-induced functionalized carbon nanotube-grafted matrix. Journal of Materials Chemistry 22:14705–14.
  • Hsieh, C.-T., J.-Y. Lin, and J.-L. Wei. 2009. Deposition and electrochemical activity of Pt-based bimetallic nanocatalysts on carbon nanotube electrodes. International Journal of Hydrogen Energy 34(2):685–93.
  • Huang, S., B. Maynor, X. Cai, and J. Liu. 2003. Ultralong, well-aligned single-walled carbon nanotube architectures on surfaces. Advanced Materials 15(19) :1651–5.
  • Huanga, H., W. Zhanga, M. Lia, Y. Gana, J. Chenb, and Y. Kuangb. 2005. Carbon nanotubes as a secondary support of a catalyst layer in a gas diffusion electrode for metal air batteries. Journal of Colloid and Interface Science 284(2):593–99.
  • Ijima, S. 1991. Helical microtubules of graphitic carbon. Nature 354:56–58.
  • Ijima, S., P. M. Ajayan, and T. Ichihashi. 1992. Growth model for carbon nanotubes. Physical Review Letters 69:3100–103.
  • Ijima, S., and T. Ichihashi. 1993. Single-shell carbon nanotubes of 1-nm diameter. Nature 363:603–605.
  • Jha, N., P. Ramesh, E. Bekyarova, X. Tian, F. Wang, M. E. Itkis, and R. C. Haddon. 2013. Functionalized Single-walled carbon nanotube-based fuel cell benchmarked against US DOE 2017 technical targets. Scientific Reports 3 :1–7.
  • Kadirgan, F., A. M. Kannan, T. Atilan, S. Beyhan, S. S. Ozenler, S. Suzerc, and A. Yörür. 2009. Carbon supported nano-sized Pt–Pd and Pt–Co electrocatalysts for proton exchange membrane fuel cells. International Journal of Hydrogen Energy 34(23):9450–460.
  • Kannan, A. M., P. Kanagala, and V. Veedu. 2009. Development of carbon nanotubes based gas diffusion layers by in situ chemical vapor deposition process for proton exchange membrane fuel cells. Journal of Power Sources 192:297–303.
  • Kim, S. H., T. K. Lee, J. H. Jung, J. N. Park, J. B. Kim, and S. H. Hur. 2012. Catalytic performance of acid-treated multi-walled carbon nanotube-supported platinum catalyst for PEM fuel cells. Materials Research Bulletin 47:2760–64.
  • Kitahara, T., T. Konomi, and H. Nakajima. 2010. Microporous layer coated gas diffusion layers for enhanced performance of polymer electrolyte fuel cells. Journal of Power Sources 195:2202–11.
  • Kokai, F., K. Takahashi, M. Yudasaka, R. Yamada, T. Ichihashi, and S. Iijima. 1999. The Journal of Physical Chemistry B 103: 4346–51.
  • Koziol, K., B. O. Boskovic, and N. Yahya. 2010. Synthesis of Carbon Nanostructures by CVD Method. Advanced Materials and Structures 5:23–49.
  • Kumar, M., and Y. Ando. 2010. Chemical vapor deposition of carbon nanotubes: A review on growth mechanism and mass production. Journal of Nanoscience and Nanotechnology 10:3739–58.
  • Kyotani, T., L. F. Tsai, and A. Tomita. 1996. Preparation of ultrafine carbon tubes in nanochannelsof an anodic aluminum oxide film. Chemistry of Materials 8:2109–13.
  • Larminie, J., and A. Dicks. 2006. Fuel Cell Systems Explained (2nd ed.). Wiley Chichester, UK: Wiley.
  • Lasagni, A., R. Cross, S. Graham, and S. Das. 2009. The fabrication of high aspect ratio carbon nanotube arrays by direct laser interference patterning. Nanotechnology 20: 1–7.
  • Lee, J. H., Y. K. Jang, C. H. Eong, N. H. Kim, P. Li, and H. K. Lee. 2009. Effect of carbon fillers on properties of polymer composite bipolar plates of fuel cells. Journal of Power Sources 193:523–29.
  • Lee, K.-S., B.-C. Lee, S. Lee, I. In, T.-w. Hong, D. Kim, W. Kim, and D. Kim. 2012. The catalytic properties of the sputtered iron on carbon nanotubes for polymer electrolyte membrane fuel cells. International Journal of Hydrogen Energy 37:6268–71.
  • Lee, Y. B., C. H. Lee, and D.-S. Lim. 2009. The electrical and corrosion properties of carbon nanotube coated 304 stainless steel/polymer composite as PEM fuel cell bipolar plates. International Journal of Hydrogen Energy 34:9781–87.
  • Lee, K., J. Zhang, H. Wang, and D. P. Wilkinson. 2006. Progress in the synthesis of carbon nanotube- and nanofiber-supported Pt electrocatalysts for PEM fuel cell catalysis. Journal of Applied Electrochemistry 36 (5):507–22.
  • Leea, W.-k., C.-H. Hoa, J. W. Van Zeea, and M. Murthy. 1999. The effects of compression and gas diffusion layers on the performance of a PEM fuel cell. Journal of Power Sources 84(1):45–51.
  • Li, X., and I. Sabir. 2005. Review of bipolar plates in PEM fuel cells: Flow-field designs. International Journal of Hydrogen Energy 30(4):359–71.
  • Li, L., and Y. Xing. 2006. Electrochemical durability of carbon nanotubes in noncatalyzed and catalyzed oxidations. Journal of the Electrochemical Society 153(10):A1823–28.
  • Liao, S. H., C.-Y. Chen, C.-H. Hung, C.-C. Weng, M.-C. Tsai, Y.-F. Lin, C.-C. M. Ma, and A. Su. 2008. One-step functionalization of carbon nanotubes by free-radical modification for the preparation of nanocompsoite bipolar plates in polymer electrolyte membrane fuel cells. Journal of Materials Chemistry 18:3993–4002.
  • Liao, S.-H., C.-H. Heng, C.-C. M. Ma, Y.-Y. Chuan, Y.-F. Lin, and C.-C. Weng. 2008. Preparation and properties of carbon nanotube-reinforced vinyl ester/nanocomposite bipolar plates for polymer electrolyte membrane fuel cells. Journal of Power Sources 176:175–82.
  • Liew, K. M., C. H. Wong, X. Q. He, M. J. Tan, and S. A. Meguid. 2004. Nanomechanics of single and multiwalled carbon nanotubes. Physical Review B 69.
  • Lim, S. H., Z. Li, C. K. Poh, L. Lai, and J. Lin. 2012. Highly active non-precious metal catalyst based on poly(vinylpyrrolidone)-wrapped carbon nanotubes complexed with ironecobalt metal ions for oxygen reduction reaction. Journal of Power Sources 214:15–20.
  • Lim, C., and C. Y. Wang. 2004. Effects of hydrophobic polymer content in GDL on power performance of a PEM fuel cell. Electrochimica Acta 49:4149–56.
  • Litster, S., and G. McLean. 2004. PEM fuel cell electrodes. Journal of Power Sources 130:61–76.
  • Liu, Y.-q., X.-h. Chen, Zhi, Y., Y.-x. Pu, and B. Yi. 2010. Synthesis of aligned carbon nanotube with straight-chained alkanes by nebulization method. The Transactions of Nonferrous Metals Society of China 20:1012–16.
  • Long, D., W. Li, W. Qiao, J. Miyawaki, S.-H. Yoon, I. Mochida, and L. Ling. 2011. Partially unzipped carbon nanotubes as a superior catalyst support for PEM fuel cells. Chemical Communications 47:9429–31.
  • Lu, J. P. 1997. Elastic properties of carbon nanotubes and nanoropes. Physical Review Letters 79:1297–1300.
  • Lukes, J. R., and H. Zhong. 2007. Thermal conductivity of individual single-wall carbon nanotubes. Journal of Heat Transfer 129:705–16.
  • Lv, H., N. Cheng, S. Mu, and M. Pan. 2011. Heat-treated multi-walled carbon nanotubes as durable supports for PEM fuel cell catalysts. Electrochimica Acta 58:736–742.
  • Maeng, I., C. Kang, S. J. Oh, J.-H. Son, and K. H. An. 2007. Terahertz electrical and optical characteristics of double-walled carbon nanotubes and their comparison with single-walled carbon nanotubes. Applied Physics Letters 90.
  • Maldonado, S., and K. J. Stevenson. 2005. Influence of nitrogen doping on oxygen reduction electrocatalysis at carbon nanofiber electrodes. The Journal of Physical Chemistry 109:4707–16.
  • Martel, R., T. Schmidt, H. R. Shea, T. Hertel, and P. H. Avouris. 1998. Single- and multi- wall carbon nanotube field effect transistors. Applied Physics Letters 73:2447–49.
  • Mason, C. W., and A. M. Kannan. 2011. Study of carbon nanotube-supported platinum nanocatalyst fabricated with sodium formate reducing agent in ethylene glycol suspension. ISRN Nanotechnology.
  • McBride, W. S. 2001. Synthesis of Carbon Nanotubes by Chemical vapor Deposition (CVD). Williamsburg: Physics, College of William and Mary.
  • Meyers, J. P., and H. L. Maynard. 2002. Design considerations for miniaturized PEM fuel cells. Journal of Power Sources 109(1):76–88.
  • Michel, M., A. Taylor, R. Sekol, P. Podsiadlo, P. Ho, N. Kotov, and L. Thompson. 2007. High-performance nanostructured membrane electrode assemblies for fuel cells made by layer-by-layer assembly of carbon nanocolloids. Advanced Materials 19(22):3859–64.
  • Michiko, K., M. Rokkaku, and T. Suzuki. 1997. Epitaxial carbon nanotube film self-organized by sublimation decomposition of silicon carbide. Applied Physics Letters 71.
  • Mintmire, J. W., B. I. Dunlap, and C. T. White. 1992. Physical Review Letters 68(5): 631–4
  • Mishra, V., F. Yang, and R. Pitchumani. 2004. Measurement and prediction of electrical contact resistance between gas diffusion layers and bipolar plate for applications to PEM fuel cells. Journal of Fuel Cell Science and Technology 1(1).
  • Mitchell, B. S. 2004. An introduction to materials engineering and science: For chemical and materials engineers. In Appendix 8:Electrical Conductivity of Selected Materials: John Wiley & Sons Inc.
  • Moshkalyov, S. A., A. L. D. Moreau, H. R. Gutierrez, M. A. Cotta, and J. W. Swart. 2004. Carbon nanotubes growth by chemical vapor deposition using thin film nickel catalyst. Materials Science and Engineering B 112:147–53.
  • Muniz, A. R., M. Meyyappan, and D. Maroudas. 2009. On the hydrogen storage capacity of carbon nanotube bundles. Applied Physics Letters 95:163111-1-163111-3.
  • Nozakia, T., K. Ohnishia, K. Okazakia, and U. Kortshagen. 2007. Fabrication of vertically aligned single-walled carbon nanotubes in atmospheric pressure non-thermal plasma CVD. Carbon 45(2):364–74.
  • Nutzenadel, C., A. Zuttel, C. Emmeneger, P. Sudan, and L. Schlapbach. 2002. Electrochemical storage of hydrogen in carbon single wall nanotubes. Fundamental Materials Research Part II: 205–13.
  • Odom, T. W., J.-L. Huang, P. Kim, and C. M. Lieber. 2000. Structure and electronic properties of carbon nanotubes. The Journal of Physical Chemistry B 104(13):2794–809.
  • Oosthuizen, R. S., and V. O. Nyamori. 2011. Carbon nanotubes as supports for palladium and bimetallic catalysts for use in hydrogenation reactions. Platinum Metals Review 55:154–69.
  • Orellana, W. 2012. Metal-phthalocyanine functionalized carbon nanotubes as catalystfor the oxygen reduction reaction: A theoretical study. Chemical Physics Letters 541:81–84.
  • Orfanidi, A., M. K. Daletou, and S. G. Neophytides. 2011. Preparation and characterization of Pt on modified multi-wall carbon nanotubes to be used as electrocatalysts for high temperature fuel cell applications. Applied Catalysis B: Environmental 106:379–89.
  • Pan, D., J. Chen, W. Tao, L. Nie, and S. Yao. 2006. Polyoxometalate-modified carbon nanotubes: New catalyst support for methanol electro-oxidation. Langmuir 22:5872–76.
  • Park, S., J.-W. Lee, and B. N. Popov. 2012. A review of gas diffusion layer in PEM fuel cells: Materials and designs. International Journal of Hydrogen Energy 37(7):5850–65.
  • Park, S., Y. Shao, R. Kou, V. V. Viswanathan, S. A. Towne, P. C. Rieke, J. Liu, Y. Lin, and Y. Wang. 2011. Polarization losses under accelerated stress test using multiwalled carbon nanotube supported Pt catalyst in PEM fuel cells. Journal of the Electrochemical Society 158(3):B297–B302.
  • Park, G.-G., Y.-J. Sohn, S.-D. Yim, T.-H. Yang, Y.-G. Yoon, W.-Y. Lee, K. Eguchi, and C.-S. Kim. 2006. Adoption of nano-materials for the micro-layer in gas diffusion layers of PEMFCs. Journal of Power Sources 163:113–18.
  • Park, S.-H., D.-J. Yun, P. Theilmann, and P. R. Bandaru. 2013. Superior electrical and mechanical characteristics observed through the incorporation of coiled carbon nanotubes, in comparison to non-coiled forms, in polymers. Polymer 54(4):1318–22.
  • Planeix, J. M., N. Coustel, B. Coq, V. Brotons, P. S. Kumbhar, R. Dutartre, P. Geneste, P. Bernier, and P. M. Ajayan. 1994. Application of carbon nanotubes as supports in heterogeneous catalysis. Journal of the American Chemical Society 116:7935–36.
  • Poochai, C., and T. Pongprayoon. 2010. Gas diffusion layer from multiwalled carbon nanotubes/polyacrylonitrile composite fiber for proton exchange membrane fuel cell. Advances in Fluid Mechanics and Heat & Mass Transfer. 114:105–9.
  • Puretzky, A. A., D. B. Geohegan, X. Fan, and S. J. Pennycook. 2000. Applied Physics A 70.
  • Purwanto, W. W., Slamet, V. J. Wargadalam, and B. Pranoto. 2012. Effects of the addition of flourinated polymers and carbon nanotubes in microporous layer on the improvement of performance of a proton exchange membrane fuel cell. International Journal of Electrochemical science 7:525–33.
  • Qin, L. C. 1997. CVD Synthesis of carbon nanotubes. Journal of Materials Sceince Letters 16:457–59.
  • Raffaelle, R. P., B. J. Landi, J. D. Harris, S. G. Bailey, and A. F. Hepp. 2005. Carbon nanotubes for power applications. Materials Science and Engineering B 116 (233–243).
  • Rafique, M. M. A., and J. Iqbal. 2011. Production of carbon nanotubes by different routes—A review. Journal of Encapsulation and Adsorption Sciences 1:29–34.
  • Rajalakshmi, N., H. Ryu, M. M. Shaijumon, and S. Ramaprabhu. 2005. Performance of polymer electrolyte membrane fuel cells with carbon nanotubes as oxygen reduction catalyst support material. Journal of Power Sources 140:250–57.
  • Ramesh, P., M. E. Itkis, J. M. Tang, and R. C. Haddon. 2008. SWNT-MWNT hybrid architecture for proton exchange membrane fuel cell cathodes. Journal of Physical Chemistry C 112:9089–94.
  • Ranney, C. 2007. Effect of Temperature and Solvent Activity on the Viscoelastic Response of Nafion for PEM Fuel Cells. Chemical Engineering, Princeton, NJ:Princeton University.
  • Ruoff, R. S., and D. C. Lorents. 1995. Mechanical and themral properties of carbon nanotubes. Carbon 33:925–30.
  • Saha, M. S., R. Li, X. Sun, and S. Ye. 2009. 3-D composite electrodes for high performance PEM fuel cells composed of Pt supported on nitrogen-doped carbon nanotubes grown on carbon paper. Electrochemistry Communications 11:438–41.
  • Savas, B., Y.-K. Kwon, and D. Tománek. 2000. Unusually high thermal conductivity of carbon nanotubes. Physical Review Letters 84:4613–16.
  • Sebastian, D., J. C. Calderon, J. A. Gonzalez-Exposito, E. Pastor, M. V. Martınez-Huerta, I. Suelves, R. Moliner, and M. J. Lazaro. 2010. Influence of carbon nanofiber properties as electrocatalyst support on the electrochemical performance for PEM fuel cells. International Journal of Hydrogen Energy 35:9934–42.
  • Seetharamappa, J., S. Yellappa, and F. D’Souza. 2006. Carbon nanotubes: Next generation of electronic materials. The Electrochemical Society Interface 23–26.
  • Serp, P., M. Corrias, and P. Kalck. 2003. Carbon nanotubes and nanofibers in catalysis. Applied Catalysis A: General 253(2):337–58.
  • Shao, Y., G. Yin, J. Wang, Y. Gao, and P. Shi. 2006. Multi-walled carbon nanotubes based Pt electrodesprepared with in situ ion exchange methods for oxygen reduction. Journal of Power Sources 1661:47–53.
  • Shawn, L., C. R. Buie, T. Fabian, J. K. Eaton, and J. G. Santiago. 2007. Active water management for PEM fuel cells. Journal of the Electrochemical Society 154 (10):B1049–B1058.
  • Shen, S. Y., P. Kang, S. Song, and S. P. Jiang. 2009. Functionalization of carbon nanotubes by an effective intermittent microwave heating-assisted HF/H2O2 treatment for electrocatalyst support of fuel cells. Electrochimica Acta 54:6954–6958.
  • Shi, W. 2012. Superconductivity in bundles of double-wall carbon nanotubes. Scientific Reports 2: 1–7
  • Shin, W. H., H. M. Jeong, B. G. Kim, J. K. Kang, and J. W. Choi. 2012. Nitrogen-doped multiwall carbon nanotubes for lithium storage with extremely high capacity. Nanoletters 12:2283–88.
  • Show, Y., and K. Takahashi. 2009. Stainless steel bipolar plate coated with carbon nanotube (CNT)/polytetrafluoroethylene (PTFE) composite film for proton exchange membrane fuel cell. Journal of Power Sources 190:322–25.
  • Shuangyin, W., D. Yu and L. Dai. 2011. Polyelectrolyte functionalized carbon nanotubes as efficient Metal-free electrocatalysts for oxygen reduction. Journal of the American Chemical Society 133:5182–85.
  • Singh, C., M. S. P. Shaffer, and A. H. Windle. 2003. Production of controlled architectures of aligned carbon nanotubes by an injection chemical vapour deposition method. Carbon 41:359–68.
  • Skoulidas, A. I., D. M. Ackerman, J. K. Johnson, and D. S. Sholl. 2002. Rapid transport of gases in carbon nanotubes. Physical Review Letters 89:18590-1-18590-4.
  • Soehn, M., M. Lebert, T. Wirth, S. Hofmann, and N. Nicoloso. 2008. Design of gas diffusion electrodes using nanocarbon. Journal of Power Sources 176:494–98.
  • Somani, S. P., P. R. Somani, A. Sato, and M. Umeno. 2009. Platinum and Ruthenium nanoparticles decorated multi walled carbon nanotubes as electrodes for polymer electrolyte membrane fuel cells. Diamond and Related Materials 18:497–500.
  • Souier, T., S. Santos, A. A. Ghaferi, M. Stefancich, and M. Chiesa. 2012. Enhanced electrical properties of vertically aligned carbon nanotube-epoxy nanocomposites with high packing density. Nanoscale Research Letters 7:690–37.
  • Souzy, R., and B. Ameduri. 2005. Functional fluoropolymers for fuel cell membranes. Progress in Polymer Science 30(6):644–87.
  • Su, X. 2012. Novel Design of Functionalized Carbon Nanotube Electrodes and Membranes for Fuel Cells and Energy Storage. Lexington: College of Business and Economics, University of Kentucky.
  • Sun, S., G. Zhang, D. Geng, Y. Chen, M. N. Banis, R. Li, M. Cai, and X. Sun. 2010. Direct growth of single-crystal Pt nanowires on Sn@CNT nanocable: 3D electrodes for highly active electrocatalysts. Chemistry: A European Journal 16:829–835.
  • Sun, X., R. Li, B. Stansfield, J. P. Dodelet, and S. Desilets. 2004. 3D carbon nanotube network based on a hierarchical structure grown on carbon paper backing. Chemical Physics Letters 394:266–70.
  • Sun, X., R. Li, D. Villers, J. P. Dodelet, S. Desilets. 2003. Composite electrodes made of Pt nanoparticles deposited on carbon nanotubes grown on fuel cell backings. Chemical Physics Letters 379:99–104.
  • Sun, S., G. Zhang, Y. Zhong, H. Liu, R. Li, X. Zhou, and X. Sun. 2009. Ultrathin single crystal Pt nanowires grown on N-doped carbon nanotubes. Chemical Communications 45:7048–50.
  • Szabó, A., C. Perri, A. Csató, G. Giordano, D. Vuono, and J. B. Nagy. 2010. Synthesis methods of carbon nanotubes and related materials. Materials 3:3092–40.
  • Tang, J. M., M. E. Itkis, C. Wang, X. Wang, Y. Yan, and R. C. Haddon. 2006. Carbon nanotube free-standing membrane as gas diffusion layer in hydrogen fuel cells. Micro and Nano Letters 1 (1):62–65.
  • Tang, Z., C. K. Poh, Z. Tian, J. Lin, H. Y. Ng, and D. H. C. Chua. 2011. In situ grown carbon nanotubes on carbon paper as integrated gas diffusion and catalyst layer for proton exchange membrane fuel cells. Electrochimica Acta 56:4327–34.
  • Terrones, M. 2003. Science and technology of the twenty-first century: Synthesis, Properties and Applications of Carbon Nanotubes. The Annual Review of Materials Research 33:419–501.
  • The Fuel Cell Today Industry Review 2011 2011. Ballard Power Systems Available at: http://www.ingentaconnect.com.echo.louisville.edu/content/matthey/pmr/2011/00000055/00000004/art00009?token=00651c85c5298c6fdb3d7b76504c4866467045496e2f2d407b4d5e6a332b2550696e43734e765c304c5f226a333f256614295.
  • Thmosen, C., S. Reich, H. Jantoljak, I. Loa, K. Syassen, M. Burghard, G. S. Duesberg, and S. Roth. 1999. Raman spectroscopy on single- and multi-walled nanotubes under high pressure. Applied Physics A 69:309–12.
  • Treacy, M. M. J., T. W. Ebbesen, and J. M. Gibson. 1996. Exceptionally high Young’s modulus observed for individual carbon nanotubes. Nature 381:678–80.
  • Tu, Z.-C., and Z.-c. Ou-Yang. 2002. Single-walled and multiwalled carbon nanotubesviewed as elastic tubes with the effective Young’s moduli dependent on layer number. Physical Review B 65: 233407-1–233407-4.
  • Varga, G. 2011. Self-Assembled, Nanostructured Carbon for Energy Storage and Water Treatment. 21:135–45.
  • Viswanathan, B., and M. Helen. 2007. Is Nafion®, the only Choice? Bulletin of the Catalysis Society of India 6:50–66.
  • Wang, Z., R.-M. Latonen, C. Kvarnstrom, A. Ivaska, and L. Niu. 2010. Preparation of multi-walled carbon Nanotube/Amino terminated ionic liquid arrays and their electrocatalysis towards oxygen reduction. Materials 3:672–81.
  • Wang, H., X. Sun, Y. Yea, and S. Qiu. 2006. Radiation induced synthesis of Pt nanoparticles supported on carbon nanotubes. Journal of Power Sources 161:839–42.
  • Wilde, P. M., M. Mändle, M. Murata, and N. Berg. 2004. Structural and physical properties of GDL and GDL/BPP combinations and their influence on PEMFC performance. Fuel Cells 4:180–184.
  • Wong, W. Y., W. R. W. Dauda, A. B. Mohamada, A. A. H. Kadhuma, E. H. Majlana, and K. S. Loha. 2012. Nitrogen-containing carbon nanotubes as cathodic catalysts for proton exchange membrane fuel cells. Diamond and Related Materials 22:12–22.
  • Wu, G, M. A. Nelson, N. H. Mack, S. Ma, P. Sekhar, F. H. Garzon, and P. Zelenay. 2010. Titanium dioxide-supported non-precious metal oxygen reduction electrocatalyst. Chemical Communications 46(40):7489–91.
  • Xiao, L., H. Zhang, E. Scanlon, L. S. Ramanathan, E.-W. Choe, D. Rogers, T. Apple, and B. C. Benicewicz. 2005. High-temperature polybenzimidazole fuel cell membranes via a sol-gel process. Chemistry of Materials 17:5328–33.
  • Xing, Y. 2004. Synthesis and electrochemical characterization of uniformly-dispersed high loading Pt nanoparticles on sonochemically-treated carbon nanotubes. The Journal of Physical Chemistry B 108(50):19255–59.
  • Xiong, W., F. Du, Y. Liu, Jr. A. Perez, M. Supp, T. S. Ramakrishnan, L. Dai, and L. Jiang. 2010. 3-D carbon nanotube structures used as high performance catalyst for oxygen reduction reaction. Journal of American Chemical Society 132:15839–41.
  • Yu, R., L. Chen, Q. Liu, J. Lin, K.-L. Tan, S. C. Ng, H. S. O. Chan, G.-Q. Xu, and T. S. A. Hor. 1998. Platinum deposition on carbon nanotubes via chemical modification. Chem. Matter 10:718–22.
  • Yu, X., and S. Ye. 2007. Recent advances in activity and durability enhancement of Pt/C catalytic cathode in PEMFC Part II: Degradation mechanism and durability enhancement of carbon supported platinum catalyst. Journal of Power Sources 172:145–54.
  • Yudasaka, M., R. Kikuchi, T. Matsui, Y. Ohki, S. Yoshimura, and E. Ota. 1995. Specific conditions for Ni catalyzed carbon nanotube growth by chemical vapor deposition Applied Physics Letters 67(17):2477–79.
  • Yumura, M. 2003. Carbon Nanotube industrial applications. AIST Today International Edition 10:8–9.
  • Zagal, J. H., S. Griveau, J. F. Silva, T. Nyokong, and F. Bedioui. 2010. Coordination Chemistry Review 254.
  • Zawodzinski, T. A., Jr., T. E. Springer, J. Davey, R. Jestel, C. Lopez, J. Valerio, and S. Gottesfeld. 1993. A comparative study of water uptake by and transport through ionomeric fuel cell membranes. Journal of Electrochemical Society 140(7):1981–85.
  • Zeng, X., X. Yuan, X.-Y. Xia, H.-J. Zhang, and Z.-F. Ma. 2009. Non-precious metal catalyst based on Co/polypyrrole/C for oxygen reduction reaction. 215th ECS Meeting, Abstract #296.
  • Zhang, W., P. Sherrell, A. I. Minett, J. M. Razal, and J. Chen. 2010. Carbon nanotube architectures as catalyst supports for proton exchange membrane fuel cells. Energy and Environmental Science 3:1286–93.
  • Zhou, O., H. Shimoda, B. Gao, S. Oh, L. Fleming, and G. Z. Yue. 2002. Materials science of carbon nanotubes: Fabrication, integration, and properties of macroscopic structures of carbon nanotubes. Accounts of Chemical Research 35(12):1045–53.
  • Zhou, O. Z., W. Zhu, D. J. Werder, and S. Jin. 2000. Nucleation and growth of carbon nanotubes by microwave plasma chemical vapor deposition Applied Physics Letters 77(17):2767–69.
  • Zhu, X., M. G. Gupta, and G. Q. Lu. 2006. Advanced Fabrication of Single Wall Carbon Nanotubes by Laser Ablation with Reduced Number of Parameters. Paper read at 1st IEEE Conference on Nano/MicroEngineered and Molecular Systems, at Zhuhai.

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