화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Journal of Materials Research, Vol.19, No.12, 644-648, December, 2009
DOI10.3740/MRSK.2009.19.12.644  Export Citation
Carbon Black-Polyethylene복합재료의 Percolation Threshold 전후 저항율에 미치는 온도의 영향
Effect of the Temperature on Resistivity of Carbon Black-Polyethylene Composites Below and Above Percolation Threshold
신순기
  • 강원대학교 신소재화학공학부
Soon-Gi Shin
  • Division of Advanced Materials and Chemical Engineering, Kangwon National University, 1 Joongang-ro, Samcheok-si, Gangwon-do, Korea 245-711
E-mail:
Temperature dependency of resistivity of the carbon black-polyethylene composites below and above percolation threshold is studied based on the electrical conduction mechanism. Temperature coefficient of resistance of the composites below percolation threshold changed from minus to plus, increasing volume fraction of carbon black; this trend decreased with increasing volume fraction of carbon black. The temperature dependence of resistivity of the composites below percolation threshold can be explained with a tunneling conduction model by incorporating the effect of thermal expansion of the composites into a tunneling gap. Temperature coefficient of resistance of the composites above percolation threshold was positive and its absolute value increased with increasing volume fraction of carbon black. By assuming that the electrical conduction through percolating paths is a thermally activated process and by incorporating the effect of thermal expansion into the volume fraction of carbon black, the temperature dependency of the resistivity above percolation threshold has been well explained without violating the universal law of conductivity. The apparent activation energy is estimated to be 0.14 eV.
Keywords:composites;percolation;polyethylene;carbon black;tunneling conduction
  1. Ishida C, Handbook of Electronic Materials, p.769, ed. Asakura KZ, Asakura shoden, Tokyo (2006). (2006)
  2. Kim J, Shin SJ, Woo SK, Kang KM, Hong HS, Korean J. Mater. Res., 18(7), 384 (2008)
  3. Song Y, Seo JH, Lee YS, Rha SK, Korean J. Mater. Res., 19(6), 344 (2009)
  4. Efros AL, Shklovskii BI, Phys. Status Solidi B, 76, 475 (1976)
  5. Staufer D, Aharrony A, Tayler & Francis, London, (1972). (1972)
  6. Nakamura S, Saito K, Sawa G, Kitagawa K, Snarskii A, Electronics A, 117, 371 (1995)
  7. Nakamura S, Saito K, Sawa G, Kitagawa K, Snarskii A, Jpn. J. Appl. Phys., 136, 5163 (1997)
  8. Nakamura S, Saito K, Sawa G, Kitagawa K, Electronic A, 118, 280 (1996)
  9. Nakamura S, Saito K, Sawa G, Electronics A, 119, 1335 (1997)
  10. Shin SG, Met. and Mat. Int., 7(6), 605 (2002)
  11. Shin SG, Lee SR, Met. and Mat. Int., 12(2), 137 (2006)
  12. Sheng P, Phys. Rev. B, 21, 2180 (1980)
  13. Nakamura S, Tomimura T, Sawa G, 1999 Ann Report Conf. on Elect. Inst. and Drelec. Plenom., II, 293(1999). (1999)