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Synthesis and Characterization of Nanocarbon-Supported Titanium Dioxide

Published online by Cambridge University Press:  31 January 2011

Marcus A Worsley
Affiliation:
[email protected], Lawrence Livermore National Laboratory, Physical and Life Sciences Directorate, Livermore, California, United States
Joshua D. Kuntz
Affiliation:
[email protected], Lawrence Livermore National Laboratory, Physical and Life Sciences Directorate, Livermore, California, United States
Octavio Cervantes
Affiliation:
[email protected], Lawrence Livermore National Laboratory, Physical and Life Sciences Directorate, Livermore, California, United States
T Yong-Jin Han
Affiliation:
[email protected], Lawrence Livermore National Laboratory, Physical and Life Sciences Directorate, Livermore, California, United States
Peter Pauzauskie
Affiliation:
[email protected], United States
Joe H Satcher
Affiliation:
[email protected], Lawrence Livermore National Laboratory, Physical and Life Sciences Directorate, Livermore, California, United States
Theodore F Baumann
Affiliation:
[email protected], Lawrence Livermore National Laboratory, Physical and Life Sciences Directorate, Livermore, California, United States
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Abstract

In this report, we describe recent efforts in fabricating new nanocarbon-supported titanium dioxide structures that exhibit high surface area and improved electrical conductivity. Nanocarbons consisting of single-walled carbon nanotubes and carbon aerogel nanoparticles were used to support titanium dioxide particles and produce monoliths with densities as low as 80 mg/cm 3. The electrical conductivity of the nanocarbon-supported titanium dioxide was dictated by the conductivity of the nanocarbon support while the pore structure was dominated by the titanium dioxide aerogel particles. The conductivity of the monoliths presented here was 72 S/m and the surface area was 203 m2/g.

Type
Research Article
Copyright
Copyright © Materials Research Society 2009

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References

[1] Yu, XB, Grant, DA, Walker, GS Journal of Physical Chemistry C 2008, 112, 11059.Google Scholar
[2] Fischer, A, Makowski, P, Mueller, JO, Antonietti, M, Thomas, A, Goettmann, F Chemsuschem 2008, 1, 444.Google Scholar
[3] Li, YZ, Lee, NH, Hwang, DS, Song, JS, Lee, EG, Kim, SJ Langmuir 2004, 20, 10838.Google Scholar
[4] Yamada, H, Yamato, T, Hidaka, R, Moriguchi, I, Kudo, T Solid State Ionics: the Science and Technology of Ions in Motion 2004, 533.Google Scholar
[5] Gratzel, M Current Opinion in Colloid & Interface Science 1999, 4, 314.Google Scholar
[6] Schneider, M, Baiker, A Catalysis Today 1997, 35, 339.Google Scholar
[7] Campbell, LK, Na, BK, Ko, EI Chemistry of Materials 1992, 4, 1329.Google Scholar
[8] Zhu, YF, Zhang, L, Wang, L, Fu, Y, Cao, LL Journal of Materials Chemistry 2001, 11, 1864.Google Scholar
[9] Retuert, J, Quijada, R, Fuenzalida, VM Journal of Materials Chemistry 2000, 10, 2818.Google Scholar
[10] Warrier, KGK, Kumar, SR, Sibu, CP, Werner, G Journal of Porous Materials 2001, 8, 311.Google Scholar
[11] Ding, Z, Hu, X, Yue, PL, Lu, GQ, Greenfield, PF Catalysis Today 2001, 68, 173.Google Scholar
[12] Torimoto, T, Ito, S, Kuwabata, S, Yoneyama, H Environmental Science & Technology 1996, 30, 1275.Google Scholar
[13] Liu, B, Zeng, HC Chemistry of Materials 2008, 20, 2711.Google Scholar
[14] Yu, HT, Quan, X, Chen, S, Zhao, HM Journal of Physical Chemistry C 2007, 111, 12987.Google Scholar
[15] Wang, WD, Silva, CG, Faria, JL Applied Catalysis B-Environmental 2007, 70, 470.Google Scholar
[16] Shin, HS, Jang, YS, Lee, Y, Jung, Y, Kim, SB, Choi, HC Advanced Materials 2007, 19, 2873.Google Scholar
[17] An, GM, Ma, WH, Sun, ZY, Liu, ZM, Han, BX, Miao, SD, Miao, ZJ, Ding, KL Carbon 2007, 45, 1795.Google Scholar
[18] Yan, XB, Tay, BK, Yang, Y Journal of Physical Chemistry B 2006, 110, 25844.Google Scholar
[19] Moriguchi, I, Hidaka, R, Yamada, H, Kudo, T, Murakami, H, Nakashima, N Advanced Materials 2006, 18, 69.Google Scholar
[20] Yu, Y, Yu, JC, Yu, JG, Kwok, YC, Che, YK, Zhao, JC, Ding, L, Ge, WK, Wong, PK Applied Catalysis a-General 2005, 289, 186.Google Scholar
[21] Li, YZ, Hwang, DS, Lee, NH, Kim, SJ Chemical Physics Letters 2005, 404, 25.Google Scholar
[22] Han, L, Wu, W, Kirk, FL, Luo, J, Maye, MM, Kariuki, NN, Lin, YH, Wang, CM, Zhong, CJ Langmuir 2004, 20, 6019.Google Scholar
[23] Tryba, B, Morawski, AW, Inagaki, M Applied Catalysis B: Environmental 2003, 46, 203.Google Scholar
[24] Sakthivel, S, Kisch, H Angewandte Chemie-International Edition 2003, 42, 4908.Google Scholar
[25] Worsley, MA, Kucheyev, SO, Satcher, JH, Hamza, AV, Baumann, TF Applied Physics Letters 2009, 94, 073115.Google Scholar
[26] Wiley, T, personal communication.Google Scholar
[27] Wang, J, Angnes, L, Tobias, H, Roesner, RA, Hong, KC, Glass, RS, Kong, FM, Pekala, RW Analytical Chemistry 1993, 65, 2300.Google Scholar
[28] Kucheyev, SO, Baumann, TF, Wang, YM, Buuren, T van, Satcher, JH Journal of Electron Spectroscopy and Related Phenomena 2005, 144, 609.Google Scholar
[29] Gregg, SJ, Sing, KSW, Adsorption, Surface Area and Porosity (Academic, London, ed. 2nd, 1982), pp.Google Scholar
[30] Lu, XP, Nilsson, O, Fricke, J, Pekala, RW Journal of Applied Physics 1993, 73, 581.Google Scholar
[31] Worsley, MA, Satcher, JH, Baumann, TF Langmuir 2008, 24, 9763.Google Scholar