159
[6]
Liu, Q.-S., Zheng, T., Li, N., Wang, P. and Abulikemu
G. ( 2009). Modification of bamboo-based
activated carbon using microwave radiation and its effects on the adsorption of methylene
blue.
Applied Surface Science
. 256, 3309-3315.
[7]
Hirata, M., Kawasaki, N., Nakamura, T., Matsumoto, K., Kabayama, M., Tamura, T. and Tanada, S.
(2002). Adsorption of Dyes onto Carbonaceous Materials Produced from Coffee Grounds by
Microwave Treatment.
Journal of Colloid and Interface Science
. 254(1), 17-22.
[8]
Nuithitikul, K., Srikhun, S. and Hirunpraditkoon, S. (2009). Influences of pyrolysis condition and
acid treatment on properties of durian peel-based activated carbon.
Bioresource Technology.
101(1) , 426-429.
[9]
Gao, P., Liu, Z. H,. Xue, G., Han, B. and Zhou, M.H. (2011). Preparation and characterization of
activated carbon produced from rice straw by (NH
4
)
2
HPO
4
activation.
Bioresource Technology.
102, 3645–3648.
[10]
Foo, K.Y. and Hameed, B.H. (2012). Factors affecting the carbon yield and adsorption capability
of the mangosteen peel activated carbon prepared by microwave assisted K
2
CO
3
activation.
Chemical Engineering Journal
. 180, 66-74.
[11]
Gokce, Y. and Aktas, Z. (
2014
). Nitric acid modification of activated carbon produced from
waste tea and adsorption of methylene blue and phenol.
Applied Surface Science
. 313, 352-
359.
[12]
Alabadi, A., Razzaque, S., Yang, Y., Chen, S. and Tan, B.. Highly porous activated carbon
materials from carbonized biomass with high CO
2
capturing capacity.
Chemical Engineering
Journal
. 281, 606-612.
