다층카본나노튜브가 보강된 고분자 나노복합체의 기계적, 열적, 전기적 특성

Mechanical, thermal and electrical properties of polymer nanocomposites reinforced with multi-walled carbon nanotubes

  • 국정호 (전북대학교 BK-21 고분자 BIN 융합기술 연구팀) ;
  • 허몽영 (전북대학교 BK-21 고분자 BIN 융합기술 연구팀) ;
  • 양훈 (원광대학교 전자재료공학과) ;
  • 신동훈 (원광대학교 전자재료공학과) ;
  • 박대희 (원광대학교 전자재료공학과) ;
  • 나창운 (전북대학교 BK-21 고분자 BIN 융합기술 연구팀)
  • Kook, J.H. (BK-21 Polymer BIN Fusion Research Team, Chonbuk National Univ.) ;
  • Huh, M.Y. (BK-21 Polymer BIN Fusion Research Team, Chonbuk National Univ.) ;
  • Yang, H. (Department of Electronic Materials Engineering, Wonkwang Univ.) ;
  • Shin, D.H. (Department of Electronic Materials Engineering, Wonkwang Univ.) ;
  • Park, D.H. (Department of Electronic Materials Engineering, Wonkwang Univ.) ;
  • Nah, C. (BK-21 Polymer BIN Fusion Research Team, Chonbuk National Univ.)
  • 발행 : 2007.06.21

초록

Semiconducting layers are thin rubber film between electrical cable wire and insulating polymer layers having a volume resistivity of ${\sim}10^2{\Omega}cm$. A new semiconducting material was suggested in this study based on the carbon nanotube(CNT)-reinforced polymer nanocomposites. CNT-reinforced polymer nanocomposites were prepared by solution mixing with various polymer type and dual filler system. The mechanical, thermal and electrical properties were investigated as a function of polymer type and dual filler system based on CNT and carbon black. The volume resistivity of composites was strongly related with the crystallinity of polymer matrix. With decreased crystallinity, the volume resistivity decreased linearly until a critical point, and it remained constant with further decreasing the crystallinity. Dual filler system also affected the volume resistivity. The CNT-reinforced nanocomposite showed the lowest volume resistivity. When a small amount of carbon black(CB) was replaced the CNT, the crystallinity increased considerably leading to a higher volume resistivity.

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