화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Journal of Industrial and Engineering Chemistry, Vol.19, No.5, 1631-1637, September, 2013
DOI10.1016/j.jiec.2013.01.034  Export Citation
Ultrathin carbon film from carbonization of spin-cast polyacrylonitrile film
Bong Seock Kim, Ji Hyun Park, Nayeong Hong, Joonwon Bae1, Cheol-Soo Yang2, and Kyusoon Shin
  • School of Chemical and Biological Engineering, Seoul National University, Seoul 151-742, Republic of Korea
  • 1Department of Applied Chemistry, Dongduk Women’s University, Seoul 136-714, Republic of Korea
  • 2Advanced Materials Division, Korea Research Institute of Chemical Technology, Daejeon 305-343, Republic of Korea
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Here we present ultrathin carbon films derived from polyacrylonitrile precursor film. Subsequent carbonization was investigated to examine the optical and electrical properties of resulting carbon films. The precursor PAN solution was carefully prepared and heated in order to have thin and uniform PAN film, and X-ray reflectivity of the precursor film and the carbon film shows uniformity. X-ray diffraction pattern of the carbon film indicated that the obtained carbon films possess low crystallinity. It was also found that the thickness for ultrathin carbon film from PAN layer showed counterbalanced optical and electrical performance in the range of experiment.
Keywords:Carbon film;Polyacrylonitrile;Electrical resistance;Optical transmittance;Carbonization
  1. Bisht H, Eun HT, Mehrtens A, Aegerter MA, Thin Solid Films, 351(1-2), 109 (1999)
  2. Kim MS, Lee HD, Kim CK, J. Ind. Eng. Chem., 12(3), 430 (2006)
  3. Lii DF, Huang JL, Jen IJ, Lin SS, Sajgalik P, Surface and Coatings Technology., 192, 106 (2005)
  4. Song IS, Heo SW, Lee JH, Haw JR, Moon DK, J. Ind. Eng. Chem., 18(1), 312 (2012)
  5. Yu HH, Hwang SJ, Hwang KC, Optics Communication., 248, 51 (2005)
  6. Cui J, Wang A, Edleman NL, Ni J, Lee P, Armstrong NR, Marks TJ, Adv. Mater., 13(19), 1476 (2001)
  7. Minami T, Semiconductor Science and Technology., 20, S35 (2005)
  8. O’regan B, Gratzel M, Nature., 353, 737 (1991)
  9. Minami T, Nanto H, Takata S, Japanese Journal of Applied Physics., 23, L280 (1984)
  10. Minami T, Nanto H, Shooji S, Takata S, Thin Solid Films., 111, 167 (1984)
  11. Lee JY, Connor ST, Cui Y, Peumans P, Nano Letters., 8, 689 (2008)
  12. Kang MG, Guo LJ, Adv. Mater., 19(10), 1391 (2007)
  13. O’Connor B, Haughn C, An KH, Pipe KP, Shtein M, Applied Physics Letters., 93, 223304 (2008)
  14. Zhang FL, Johansson M, Andersson MR, Hummelen JC, Inganas O, Adv. Mater., 14(9), 662 (2002)
  15. Kim WH, Makinen AJ, Nikolov N, Shashidhar R, Kim H, Kafafi ZH, Applied Physics Letters., 80, 3844 (2002)
  16. Pasquier AD, Unalan HE, Kanwal A, Miller S, Chhowalla M, Applied Physics Letters., 87, 203511 (2005)
  17. Zhang M, Fang S, Zakhidov AA, Lee SB, Aliev AE, Williams CD, Atkinson KR, Baughman RH, Science., 309, 1215 (2005)
  18. Wang X, Zhi L, Mullen K, Nano Letters., 8, 323 (2008)
  19. Hecht DS, Hu LB, Irvin G, Adv. Mater., 23(13), 1482 (2011)
  20. Wang X, Zhi L, Tsao N, Tomovic Z, Li J, Mullen K, Angewandte Chemie International Edition., 47, 2990 (2008)
  21. Renschler CL, Sylwester AP, Applied Physics Letters., 50, 1420 (1987)
  22. Renschler CL, Sylwester AP, Salgado LV, Journal of Materials Research., 4, 452 (1989)
  23. McEvoy N, Peltekis N, Kumar S, Rezvani E, Nolan H, Keeley GP, Blau WJ, Duesberg GS, Carbon., 50, 1216 (2012)
  24. Vu DQ, Koros WJ, Miller SJ, Ind. Eng. Chem. Res., 41(3), 367 (2002)
  25. Centeno TA, Fuertes AB, Carbon., 38, 1067 (2000)
  26. Song C, Wang T, Qiu Y, Qiu J, Cheng H, Journal of Porous Materials., 16, 197 (2009)
  27. Rahaman MSA, Ismail AF, Mustafa A, Polymer Degradation and Stability., 92, 1421 (2007)
  28. Gupta AK, Paliwal DK, Bajaj P, Polymer Reviews., 31, 1 (1991)
  29. Leiston-Belanger JM, Penelle J, Russell TP, Macromolecules, 39(5), 1766 (2006)
  30. Bailey JE, Clarke AJ, Nature., 234, 529 (1971)
  31. Takahagi T, Shimada I, Fukuhara M, Morita K, Ishitani A, Journal of Polymer Science Part A: Polymer Chemistry., 24, 3101 (1986)
  32. Stevenson WTK, Garton A, Ripmeester JA, Wiles DM, Polymer Degradation and Stability., 15, 125 (1986)
  33. Qin X, Lu Y, Xiao H, Song Y, Materials Letters., 76, 162 (2012)
  34. Gupta A, Harrison IR, Carbon., 34, 1427 (1996)
  35. Gupta A, Harrison IR, Carbon., 35, 809 (1997)
  36. Sivy GT, Gordon III B, Coleman MM, Carbon., 21, 573 (1983)
  37. Coleman MM, Sivy GT, Painter PC, Snyder RW, Gordon III B, Carbon., 21, 255 (1983)
  38. Mellbring O, Oiseth SK, Krozer A, Lausmaa J, Hjertberg T, Macromolecules, 34(21), 7496 (2001)
  39. Kressler J, Wang C, Kammer HW, Langmuir, 13(16), 4407 (1997)
  40. Hernandez JJ, Rueda DR, Garcia-Gutierrez MC, Nogales A, Ezquerra TA, Soccio M, Lotti N, Munari A, Langmuir, 26(13), 10731 (2010)
  41. Liu XD, Ruland W, Macromolecules., 26, 3030 (1993)
  42. Hori Y, Shimada S, Kashiwabara H, Polymer., 18, 151 (1977)
  43. Hori Y, Fukunage Z, Shimada S, Kashiwabara H, Polymer., 20, 181 (1979)
  44. Fitzer E, Muller DJ, Carbon., 13, 63 (1975)
  45. Henrici-Olive G, Olive S, Advances in Polymer Science., 51, 1 (1983)
  46. Huang Y, Wu J, Hwang KC, Physical Review B: Condensed Matter and Materials Physics., 74, 245413 (2006)
  47. De S, King PJ, Lotya M, O’Neill A, Doherty EM, Hernandez Y, Duesberg GS, Coleman JN, Small., 6, 458 (2010)
  48. Geng HZ, Kim KK, So KP, Lee YS, Chang Y, Lee YH, J. Am. Chem. Soc., 129(25), 7758 (2007)
  49. Kang BD, Hur SG, Kim DJ, Yoon SG, Electrochem. Solid State Lett., 8(4), G92 (2005)