양극산화를 이용한 알루미나 나노세공 멤브레인의 제조

임완순; 조경철; 조유석; 최규석; 김도진; W.S. Im; K.C. Cho; Y.S. Cho; G.S. Choi; D.J. Kim

Korean Journal of Materials Research, Vol.13, No.9, 593-597, September, 2003

DOI10.3740/MRSK.2003.13.9.593 Export Citation

양극산화를 이용한 알루미나 나노세공 멤브레인의 제조

Fabrication of Alumina Membrane Using Anodic Oxidation Process

임완순, 조경철, 조유석, 최규석, 김도진 ^†

충남대학교 공과대학 재료공학과 나노 재료 응용 실험실

W.S. Im, K.C. Cho, Y.S. Cho, G.S. Choi, and D.J. Kim^†

Department of Materials Engineering, Chungnam National University, Daejeon 305-764, Korea

E-mail:

Anodic aluminum oxide (AAO) membrane was made of aluminum sheet (99.6%, 0.2 mm thickness). The regular array of hexagonal nano pores or channels were prepared by two step anodization process. A detail description of the AAO fabrication is presented. After the 1st anodization in oxalic acid (0.3 M) at 45 V, The formed AAO was removed by etching in a solution of 6 wt% ＋1.8 wt% . The regular arrangement of the pores was obtained by the 2nd anodization, which was carried out in the same condition as the 1st anodization. Subsequently, the alumina barrier layer at the bottom of the channel layer was removed in phosphoric acid (1M) after removing of aluminum. Pore diameter, density, and thickness could be controlled by the anodization process parameters such as applied voltage, anodizing time, pore widening time, etc. The pore diameter is proportional to the applied voltage and pore widening time. The pore density and thickness can be controlled by anodization temperature and voltage.

Keywords:odic aluminum oxide;anodization;membrane;template

[References]

Furneaux RC, Rigby WR, Davidson AP, Nature, 337, 149 (1989)
Masuda H, Fukuda K, Science, 268, 199 (1995)
Masuda H, Satoh M, Jpn. J. Appl. Phys., 35, L126 (1996)
Sui YC, Gonzalez-Leon JA, Bermudez A, Saniger JM, Carbon, 39, 1709 (2001)
Iwasaki T, Motoi T, Den T, Appl. Phys. Lett., 75, 2044 (1999)
Yin AJ, Li J, Jian W, Benett AJ, Xu JM, Appl. Phys. Lett., 79, 1039 (2001)
Yang Y, Chen H, Mei Y, Chen J, Wu X, Bao X, Solid State Communications, 123, 279 (2002)
Parkhutic VP, Shershulsky VI, Appl. Phys., 25, 1258
Lohrengel MM, Mater. Sci. Eng., R11, 243 (1993)
Li OF, Zhang L, Metzger RM, Chem. Mater., 10, 2470 (1998)
Diggle JW, Downie TC, Goulding CW, Chem. Rev., 69, 365 (1969)
Shinizu K, Kobayashi K, Skeldon P, Thompson GE, Wood GC, Corrosion Sci., 39, 701 (1997)
Shingubara S, Okino O, Sayama Y, Sakaue H, Takahagi T, Solid State Electronics, 43, 1143 (1999)
Jessensky O, Muller F, Gosele U

[Related Articles]

[1] Furneaux RC, Rigby WR, Davidson AP, Nature, 337, 149 (1989)

[2] Masuda H, Fukuda K, Science, 268, 199 (1995)

[3] Masuda H, Satoh M, Jpn. J. Appl. Phys., 35, L126 (1996)

[4] Sui YC, Gonzalez-Leon JA, Bermudez A, Saniger JM, Carbon, 39, 1709 (2001)

[5] Iwasaki T, Motoi T, Den T, Appl. Phys. Lett., 75, 2044 (1999)

[6] Yin AJ, Li J, Jian W, Benett AJ, Xu JM, Appl. Phys. Lett., 79, 1039 (2001)

[7] Yang Y, Chen H, Mei Y, Chen J, Wu X, Bao X, Solid State Communications, 123, 279 (2002)

[8] Parkhutic VP, Shershulsky VI, Appl. Phys., 25, 1258

[9] Lohrengel MM, Mater. Sci. Eng., R11, 243 (1993)

[10] Li OF, Zhang L, Metzger RM, Chem. Mater., 10, 2470 (1998)

[11] Diggle JW, Downie TC, Goulding CW, Chem. Rev., 69, 365 (1969)

[12] Shinizu K, Kobayashi K, Skeldon P, Thompson GE, Wood GC, Corrosion Sci., 39, 701 (1997)

[13] Shingubara S, Okino O, Sayama Y, Sakaue H, Takahagi T, Solid State Electronics, 43, 1143 (1999)

[14] Jessensky O, Muller F, Gosele U