Title :
Electrical conduction of cellulose under DC field
Author :
Takahashi, Masae ; Takenaka, Haruko ; Wada, Yasaku
Author_Institution :
Phys. Lab., Japan Women´´s Univ., Tokyo, Japan
Abstract :
The temperature gradient of crystal lattice spacings and X-ray reflection intensities has been found to change discontinuously at 150°C for cellulose I (Cell I) and at 100°C for cellulose II (Cell II). These breaks reflect a transition related to the onset of the backbone motion in the crystalline phase. The authors have attempted to confirm this conclusion by measuring the DC conductivity from room temperature to about 230°C for Cell I and Cell II both parallel and perpendicular to the fiber direction. The conduction mechanism is discussed in relation to the absorption current of Cell I under a DC field in the temperature range from 140°C to 230°C, where the DC conductivity becomes relatively high. The results indicate that the increase of carrier mobility above the transition temperature of crystallites arises from the backbone motion in the disordered crystalline phase (mesophase) and that proton transfer is an elementary mechanism for both absorption and steady currents
Keywords :
carrier mobility; electrical conductivity of amorphous semiconductors and insulators; high field effects; polymer structure; polymers; 20 to 230 C; DC field; X-ray reflection intensities; absorption current; backbone motion; carrier mobility; cellulose; conduction mechanism; crystal lattice spacings; crystalline phase; disordered crystalline phase; electrical conduction; fibre direction; mesophase; proton transfer; temperature gradient; transition temperature of crystallites; Amorphous materials; Conductivity; Crystallization; Electrical resistance measurement; Equations; Polymers; Spine; Temperature; Thermal decomposition; Voltage;
Conference_Titel :
Conduction and Breakdown in Solid Dielectrics, 1989., Proceedings of the 3rd International Conference on
Conference_Location :
Trondheim
DOI :
10.1109/ICSD.1989.69185
