Physical properties of reduced graphene oxide (rGO) prepared from two different raw materials, namely coconut shell (rGO-s) and graphite mineral (rGO-c, produced by Graphenea Inc.), have been investigated. While both samples have the same density of about 1.9 g/cm³, rGO-c has more porous of about 1.3 cc/g with diameter of 10.8 nm compared to rGO-s which has 0.2 cc/g porous with diameter of 2.4 nm. Specific surface area in rGO-c was also obtained much larger than that of rGO-s. rGO-c and rGO-s have specific surface area of ~298 m²/g and ~475 m²/g, respectively. Examinations on particle size and surface morphology show that rGO-c has homogenous particles which consist of transparent thin sheets, while rGO-s has rather heterogenous particles that look like dens stacked sheets. The presence of C and O was confirmed at the observed morphology. The difference in physical features were then found to influence the obtained electrical conductivity of the samples. rGO-c has higher conductivity than rGO-s. Estimation on gap energy (E_g) indicates that rGO-c and rGO-s have E_g in the range of semiconducting materials. The study provides a better understanding on physical properties of coconut shell-derived rGO to further revise synthesis method to improve quality of the obtained rGO.

J. Tuček, P. Błoński, J. Ugolotti, A. K. Swain, T. Enoki, R. Zbořil, “Emerging chemical strategies for imprinting magnetism in graphene and related 2D materials for spintronic and biomedical applications,” Chem. Soc. Rev. 47: 3899-3990, 2018.

S. K. Sarkar, K. K. Raul, S. S. Pradhan, S. Basu and A. Nayak, “Magnetic properties of graphite oxide and reduced graphene oxide,” Phys. E Low-Dimesional Syst. Nanostruct. 64: 78-82, 2014.

S. Qin, X. Guo, Y. Cao, Z. Ni and Q. Xu, “Strong ferromagnetism of reduced graphene oxide,” Carbon 78: 559-565, 2014.

I-D. Kim, S-J. Choi, H-J. Cho. “Graphene-based composite materials for chemical sensor application, electrospinning for high performance sensors,” in: A. Macagnano, E. Zampetti, E. Kny (Eds.). Cham: Springer International Publishing. 65-101, 2015.

C.R. Minitha, V.S. Anithaa, V. Subramaniam, R.T.R. Kumar, “Impact of oxygen functional groups on reduced graphene oxide-based sensors for ammonia and toluene detection at room temperature,” ACS Omega 3: 4105-4112, 2018.

J. Ma, T. Xue and Xue Qin, “Sugar-derived Carbon/Graphene Composite Materials as Electrodes for Supercapacitors,” Electrochimica Acta. 115: 566-572, 2014.

S. Rasul, A. Alazmi, K. Jaouen, M. N. Hedhili, P. M. F. J. Costa, “Rational design of reduced graphene oxide for superior performance of supercapacitor electrodes,” Carbon. 111: 774-781, 2017.

S. Jayaraman, A. Jain, M. Ulaganathan, E. Edison, M.P. Srinivasan, R. Balasubramanian, V. Aravindan, S. Madhavi, “Li-ion vs. Na-ion capacitors: A performance evaluation with coconut shell derived mesoporous carbon and natural plant based hard carbon,” Chemical Engineering Journal 316: 506-513, 2017.

J. M. Kim, W.G. Hong, S.M. Lee, S.J. Chang, Y. Jun, B.H. Kim, H.J. Kim, “Energy storage of thermally reduced graphene oxide,” International Journal of Hydrogen Energy 39: 3799-3804, 2014.

M. Czerniak-Reczulska, A. Niedzielska, A. Jędrzejczak, “Graphene as a material for solar cells applications,” Advances in Materials Sciences 15: 67, 2015.

D. Barpuzary and M. Qureshi, “Graphene filled polymers in photovoltaic, graphene-based polymer nanocomposites in electronics,” in: K.K. Sadasivuni, D. Ponnamma, J. Kim, S. Thomas (Eds.). Cham: Springer International Publishing: 157-191, 2015.

S.S. Shams, L.S. Zhang, R. Hu, R. Zhang, J. Zhu, “Synthesis of graphene from biomass: A green chemistry approach,” Mat. Lett. 161: 476-479, 2015.

A. Jain, R. Balasubramanian, M.P. Srinivasan, “Production of high surface area mesoporous activated carbons from waste biomass using hydrogen peroxide-mediated hydrothermal treatment for adsorption applications,” Chemical Engineering Journal 273: 622-629, 2015.

S. Jung, Y. Myung, B.N. Kim, I.G. Kim, I.-K. You, T. Kim, “Activated biomass-derived graphene-based carbons for supercapacitors with high energy and power density,” Sci. Reports 8: 1915, 2018.

Y. Liu, J. Chen, B. Cui, P. Yin, C. Zhang, “Design and preparation of biomass-derived carbon materials for supercapacitors: A review,” J. of Carbon Research 4: 53, 2018.

H.M. Mozammel, O. Masahiro and S. C. Bhattacharya, “Activated charcoal from coconut shell using ZnCl2 activation,” Biomass and Bioenergy 22: 397-400, 2002.

M. Yalcin and A.I. Arol, “Gold cyanide adsorption characteristics of activated carbon of non-coconut shell origin,” Hydrometallurgy 63: 201–206, 2002.

Z. Liu and F.-S. Zhang, “ Removal of copper(II) and phenol from aqueous solution using porous carbons derived from hydrothermal chars,” Desalination 267: 101–106, 2011.

D.D. Hendaryati and Y. Arianto, “Tree Crop Estate Statistics of Indonesia 2015-2017,” Directorate General of Estate Crops: 1-98, 2017.

J. Tauc, “ Optical properties and electronic structure of amorphous Ge and Si,” Materials Research Bulletin 3: 37–46, 1968.

Darminto, R. Asih, Kurniasari, M. A. Baqiya, S. Mustofa, Suasmoro, T. Kawamata, M. Kato, I. Watanabe and Y. Koike, “Enhanced magnetism by temperature induced defects in reduced graphene oxide prepared from coconut shells,” IEEE Trans. Mag. 54: 1-5, 2018.

R. Asih, E. B. Yutomo, D. Ristiani, M. A. Baqiya, T. Kawamata, M. Kato, I. Watanabe, Y. Koike, Darminto, “Comparative study on magnetism of reduced graphene oxide (rGO) prepared from coconut shells and the commercial product,” Mat. Sci. Forum 966: 290-295, 2019.