A technique to determine the surface fractal dimension of mesoporous TiO­₂ using a dynamic flow adsorption instrument is described. Fractal dimension is an additional technique to characterize surface morphology. Surface fractal dimension, a quantitative measurement of surface ruggedness, can be determined by adsorbing a homologous series of adsorbates onto an adsorbent sample of mesoporous TiO­₂. Titania wet gel prepared by hydrolysis of Ti-alkoxide was immersed in the flow of supercritical CO₂ at 60 °C and the solvent was extracted.  Mesoporous TiO­₂ consists of anatase nano-particles, about 5nm in diameter, have been obtained. After calcination at 600 °C, the average pore size of the extracted gel, about 20nm in diameter, and the pore volume, about 0.35cm³g^-1, and the specific surface area, about 58 m²g^-1. Using the N₂ adsorption isotherm, the surface fractal dimension, D_S, has been estimated according to the Frenkel-Halsey-Hill (FHH) theory. The N₂ adsorption isotherm for the as-extracted aerogel indicates the mesoporous structure. Two linear regions are found for the FHH plot of the as-extracted aerogel. The estimated surface fractal dimensions are about 2.49 and 2.68. Both of the D_S  values indicate rather complex surface morphology. The TEM observation shows that there are amorphous and crystalline particles. Two values of D_S may be attributed to these two kinds of particles. The two regions are in near length scales, and the smaller D_S, D_S =2.49, for the smaller region. This result indicates that there are two kinds of particles, probably amorphous and anatase particles as shown by the TEM observation.

[1] Oki, Yasuyuki, Koike, Hironobu and Takeuchi, Yoshiaki, US patent, Serial No.: 978004, Application Number, 11-228474J. 2002.

[2] Mandelbrot, B.B., The Fractal Geometry of Nature, W.H. Freeman and Company, New York, 1983

[3] Barnsly, M., Fractals Everywhere, Academic Press, Inc., New York, 1988.

[4] Vicsek, T., Fractal Growth Phenomena, World Scientific, London, 1989.

[5] Avnir, D., Proceeding Materials Research Society Symposium, Vol. 73, Better Ceramics Through Chemistry II, Materials Research Society, Pittsburgh, PA, 1986, p. 321.

[6] Haerudin, H., Bertel, S., and Kramer, R., 1998, J. Chemical Society, Faraday Trans, 94 (10), 1481.

[7] Fox, M.A. and Dulay, M.T., Chem. Rev., 93, 1993, 341.

[8] Moritz, T., Reiss, J., Diesner, K., Su D., and Chemseddine, A., J. Phys. Chem. B, 101, 1997, 8052.

[9] Hirashima, H., Imai, H., and Balek, V., J. Non-Crystalline Solids, 285, 2001, 96.

[10] Yusuf, M.M., Imai, H., Hirashima, H., 2001, J. Non-Crystalline Solids, 285, 90.

[11] Suh, D.J., Park, T.J., Kim, J.H., and Kim, K.L., Chem. Mater. 9, 9, 1997, 1903.

[12] Barret, E.P., Joyner, L.G. and Halenda, P.H., 1951, J. Am. Chem. Soc., 73, 373.

[13] Imai, H., Morimoto, H., Tomonaga, A., and Hirashima, H., 1997, J. Sol-gel Sci.and Tech., 10, 45

[14] Yao, B., Zhang, Y., Shi, H., and Zhang, L., 2000, Chem. Mat., 12, 3740.

[15] Kasuga, T., Hiramatsu, M., Hoson, A., Sekino, T., and Niihara, K., 1999, Adv. Mater., 11, 1307.

[16] Kumar, K-N.P., Keizer, K., Burggraaf, A.J., Okubo, T., and Nagamoto, H., 1993, J. Mater. Chem., 3, 1151.

[17] Fan, K. and Hatzkiriokos, S.G., Wood Science and Technology, 33, 1999, 139-145.

[18] Staszczuk, P., Sternik, D., and Chadzynski, G.W., 2003, Journal of Thermal analysis and Calorimetry, 71, 173-182.

[19] Balovsyak, S.V., Fodchuk, I.M., and Lytvyn, P.M., 2003, Semiconductor Physics, Quantum Electronics & Optoelectronics, 6, 41-46

[20] Staszczuk, P., Matyjewicz, M., Kowalska, E. Radomska, J., Byszewski, P., and Kozlowwski, M., 2003, Rev. Adv. Mater. Sci. 5, 471-476.

[21] HongWei, F., MingHong, C., and ZhiHe, C., 2008, Sci. China. Ser. G-Phys. Astron., 51, 8, 1022-1028