촉매 화학 기상 증착법의 제조 조건에 따른 탄소 나노튜브의 특성

김현진; 이임렬; Hyun Jin Kim; Rhim Youl Lee

Korean Journal of Materials Research, Vol.12, No.6, 458-463, June, 2002

DOI10.3740/MRSK.2002.12.6.458 Export Citation

촉매 화학 기상 증착법의 제조 조건에 따른 탄소 나노튜브의 특성

Characteristics of Carbon Nanotube with Synthetic Conditions in Catalytic Chemical Vapor Deposition

김현진, 이임렬^†

단국대학교 신소재공학과

Hyun Jin Kim, and Rhim Youl Lee^†

Dept. of New Materials Engr., Dankook University, Cheonan, 330-714, Korea

E-mail:

Carbon nanotubes were synthesized at various conditions using Ni-catalytic thermal chemical vapor deposition method and their characteristic properties were investigated by SEM, TEM and Raman spectroscopy. Carbon nanotubes were formed on very fine Ni-catalytic particles. The carbon nanotubes synthesized by thermal decomposition of acetylene at 700 ? C had a coiled shape, while those synthesized at 850 ? C showed a curved and Y-shape having a bamboo-like morphology. It was found that the carbon nanotube was also made on the fine Ni-catalytic particles formed on the surface of 100~400nm sized large ones after pretreatment with NH 3 .ber composites show the high dielectric constant and large conduction loss which is increased with anisotropy of fiber arrangement. It is, therefore, proposed that the glass and carbon fiber composites can be used as the impedance transformer (surface layer) and microwave reflector, respectively. By inserting the foam core or honeycomb core (which can be treated as an air layer) between glass and carbon fiber composites, microwave absorption above 10 dB (90% absorbance) in 4-12 GHz can be obtained. The proposed fiber composites laminates with sandwitch structure have high potential as lightweight and high strength microwave absorbers.

Keywords:catalytic CVD;carbon nanotube;morphology

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[1] Hamada N, Sawada S, Oshiyama A, Phys. Rev. Lett., 68, 1579 (1992)

[2] Bonard JM, Salvetat JP, Stockli T, Forro L, Chatelain A, Appl. Phys. A, 69, 245 (1999)

[3] Nutzenadel C, Zuttel A, Chartouni D, Schlapbach L, Electrochem. Solid-State Lett., 2, 30 (1999)

[4] Zhang Q, Yoon SF, Ann J, Gan B, Rusil, Lu HB, J. Phys. Chem. Solid, 61, 1179 (2000)

[5] Jung M, Eun KY, Lee JK, Baik YJ, Lee KR, Park JW, Diam. Relat. Mat., 10, 1235 (2001)

[6] Yadasaka M, Kikuchi R, Matsui T, Ohki Y, Yoshimura S, Ota E, Appl. Phys. Lett, 67(17), 2477 (1995)

[7] Lee CJ, Park J, Kang SY, Lee JH, Chem. Phys. Lett., 323(5-6), 554 (2000)

[8] Hermadi K, Fonseca A, Nagy JB, Siska A, Kiricsi I, Appl. Catalysis. A, 199, 245 (1999)

[9] Choi YC, Shin YM, Bae DB, Lim SC, Lee YH, Lee BS, Diam. Relat. Mat., 10, 1457 (2001)

[10] Simonis P, Volodin A, Seynaeve E, Lambin P, Haesendonck CV, in Science and Application of Nanotubes, ed D. Tomaneck and R. J. Embody (Kluwer academic, New York, USA, 1999) p.83 (1999)

[11] He N, Kuang Y, Dai Q, Miao Y, Zhang A, Song K, Lu Z, Yuan C, Mater. Sci. Eng. C, 8-9, 151 (1999)

[12] Cheng HM, Li F, Su S, Pan HY, He LL, Sun X, Dresselhaus MS, Appl. Phys. Lett., 72(25), 3282 (1998)

[13] Qin LC, Zhou D, Krauss AR, Gruen DM, Appl. Phys. Lett., 72(26), 3477 (1998)

[14] Hernadi K, Fonseca A, Nagy JB, Siska A, Kiricsi I, Appl. Catalysis. A, 199, 245 (200)

[15] Endo M, Chemtech, 18(9), 568 (1988)

[16] Ajayan PM, in Carbon Nanotubes, ed Ebbessen TW (CRT, New York, USA, 1997) p.lll (1997)

[17] Gan B, Ann J, Zhang Q, Yoon SF, Rusil, Huang QF, Yu MB, Li WZ, Diam. Relat. Mat., 9, 897 (2000)

[18] Collins PG, Zettl A, Bando H, Thess A, Smalley RE, Science, 278(5335), 100 (1997)

[19] Chen J, Li Y, Ma Y, Qin Y, Chang L, Carbon, 39, 1467 (2001)

[20] Li WZ, Wen JG, Ren ZF, Appl. Phys. A, 74, 397 (2002)

[21] Ren ZF, Huang ZP, Xu JW, Wang JH, Bush P, Siegal MP, Provencio PN, Science, 282(5391), 1105 (1998)

[22] Hong SY, Cho YS, Choi GS, Kim DJ, Kim HJ, Korean J. Materials Reseirch, 11(8), 697 (2001)