Biomass & Bioenergy, Vol.59, 370-379, 2013
Supercapacitors using binderless composite monolith electrodes from carbon nanotubes and pre-carbonized biomass residues
Binderless composite monolith (BCM) electrodes prepared from carbon nanotubes (CNTs) and self-adhesive carbon grains (SACGs) were used in a symmetrical supercapacitor. The SACGs were prepared from fibers of oil palm empty fruit bunches (EFBs) from oil palm tree (Elaeis guineensis), Heliotropium dasycarpum (H. dasycarpum) and Guaiacum officinale (G. officinale). For each biomass, the BCMs were prepared by the carbonization and activation of green monoliths (GMs) containing SACGs treated with KOH and a mixture of SACGs and CNTs treated with KOH. Thermal decomposition behavior of all SACGs was found to be slightly different because of the difference in their compositions. In addition, BCMs from H. dasycarpum and G. officinale were found to have SiO2. The BET surface areas were 1656, 1031 and 532 m(2) g(-1) for the BCMs from EFB, H. dasycarpum and G. officinale, respectively, and these values decreased by 40, 50 and 31% upon CNTs addition. Consequently, the specific capacitance decreased from similar to 124 to similar to 104 and similar to 49 F g(-1) to similar to 111, similar to 87 and similar to 31 F g(-1), respectively. However, addition of CNTs reduced the equivalent series resistance (ESR) by a factor of 83.9 (EFB), 90.6 (H. dasycarpum) and 38.8 (G. officinale) %. It was also found that CNTs addition contributed to improving the decay of C-sp with increasing scan rate if the electrode surface area was sufficiently high. (C) 2013 Elsevier Ltd. All rights reserved.
Keywords:Elaeis guineensis;Heliotropium dasycarpum;Guaiacum officinale;Energy storage;Binderless composite electrodes;Porosity