Design, Fabrication, and Testing of Supercapacitor Based on Nanocarbon Composite Material

Heri Rustamaji; Tirto Prakoso; Hary Devianto; Pramujo Widiatmoko; Isdiriayani Nurdin

Heri Rustamaji Department of Chemical Engineering, Lampung University, Bandar Lampung 35145 Indonesia
Tirto Prakoso Department of Chemical Engineering, Institut Teknologi Bandung, Bandung 40132 Indonesia
Hary Devianto Department of Chemical Engineering, Institut Teknologi Bandung, Bandung 40132 Indonesia
Pramujo Widiatmoko Department of Chemical Engineering, Institut Teknologi Bandung, Bandung 40132 Indonesia
Isdiriayani Nurdin Department of Chemical Engineering, Institut Teknologi Bandung, Bandung 40132 Indonesia

Keywords: supercapacitor, nanocarbon, electrode, electrochemical, performance test

Abstract

This research investigates the design, fabrication, and testing of single-cell and module supercapacitors. The supercapacitor consists of carbon nanocomposites, which contain activated carbon (AC), multiwall carbon nanotubes (MWCNT), and graphene (GR). The coin and pouch cell type supercapacitors were manufactured with AC: MWCNT: GR composite electrodes in a ratio of 70:20:10 weight percent. Meanwhile, the electrochemical characterization showed that the highest capacitance values for single coin and pouch cells were 32.13 F g^-1 and 5.3 F g^-1, respectively, in 6 M KOH electrolyte at a scan rate of 2 mV s^-1. Furthermore, the power and energy densities for the coin-cell supercapacitor were 69 W kg^-1 and 6.6 Wh kg^-1, respectively, while for the pouch cell, it was 7.4 W kg^-1 and 1.0 Wh kg^-1, respectively. The coin-cell supercapacitor durability test was carried out for 1000 cycles, yielding the retention capacitance and coulombic efficiency values of 94-97% and 100%, respectively. These results showed that the performance of the supercapacitor is close to commercial products.

References

Allebrod, F., Chatzichristodoulou, C., Mollerup, P. L., and Mogensen, M. B., 2012. "Electrical conductivity measurements of aqueous and immobilized potassium hydroxide," Int. J. Hydrog. Energy, 37, 16505-16414.

Antonietti, M., Chen, X. D., Yan, R. Y., and Oschatz, M., 2018. "Storing electricity as chemical energy: beyond traditional electrochemistry and double-layer compression," Energy Environ. Sci., 11, 3069–30

Augustyn, V., Simon, P., and Dunn, B., 2014. "Pseudocapacitive oxide materials for high-rate electrochemical energy storage," Energy Environ. Sci., 7, 1597–1614.

Azaïs, P., Duclaux, L., Florian, P., Massiot, D., and Lillo-Rodenas, M. A., 2017. "Causes of supercapacitors aging in an organic electrolyte," J. Power Sources, 171, 1046–1053.

Balducci A., Belanger, D., Brousse, T., Long, J. W., and W. Sugimoto., 2017. "A guideline for reporting performance metrics with electrochemical capacitors: from electrode materials to full devices," J. Electrochem. Soc., 164 (7), A1487-A1488.

Beguin, F. and Frackowiak, E., 2013. Supercapacitors: materials, systems, and applications, Wiley-VCH Verlag GmbH & Co. KgaA, Weinheim, Germany

Bonaccorso, F., Colombo, L., Yu, G., Stoller, M., Tozzini, V., Ferrari, A. C., Ruoff, R.S., and Pellegrini., 2015. "Graphene, related two-dimensional crystals, and hybrid systems for energy conversion and storage," Science, 347 (6217), 10.

Cheng, F., Yang, X., Zhang, S., and Lu., 2020. "Boosting the supercapacitor performances of activated carbon with carbon nanomaterials," J. Power Sources, 450, 227678.

Cheng, Q., Tang, J., Ma, J., Zhang, H., Shinyaa, N., dan Qin, L. Q., 2011. "Graphene dan carbon nanotube composite electrodes for supercapacitors with ultra-high energy density," Phys. Chem. Chem. Phys., 13, 17615–17624.

Chernysh, O., Khomenko, V., Makyeyeva, I., and Barsukov, V., 2019. "Effect of binder's solvent on the electrochemical performance of electrodes for lithium-ion batteries and supercapacitors," Mater. Today: Proc., 6, 42–47.

Giurlani, W., Sergi, L., Crestini, E., Calisi, N., Poli, F., Soavi, F., and Innocenti, M., 2022. "Electrochemical stability of steel, Ti, and Cu current collectors in water-in-salt electrolyte for green batteries and supercapacitors," J. of Solid State Electrochem., 26, 85–95.

Marshall, J. E., Zhenova, A., Roberts, S., Petchey, Zhu, P., Dancer, C. E. J., McElroy, C. R, Emma Kendrick, E., and Goodship, V., 2021. "On the solubility and stability of polyvinylidene fluoride," Polymers, 13, 1354.

Kumar, V. B., Borenstein, A., Markovsky, B., Aurbach, D., Gedanken, A., Talianker, M., and Porat, Z, 2016. "Activated carbon modified with carbon nanodots as novel electrode material for supercapacitors," J. Phys. Chem. C, 120, 13406−13413.

Liang, K., Wang, W., Yu, Y., Liu, L., Haijun, L., Zhang, Y., and Chen, A., 2019. "Synthesis of nitrogen-doped mesoporous carbon for high-performance supercapacitors," New J. Chem., 43, 2776-2782.

Liu, J., Deng, Y., Li, X., dan Wang, L., 2016. "Promising nitrogen-rich porous carbons derived from one-step calcium chloride activation of biomass-based waste for high-performance supercapacitors," ACS Sustain. Chem. Eng., 4, 177-187.

Liu, C. and Liu, L., 2017. "Optimal design of Li-ion batteries through multi-physics modeling and multi-objective optimization," J. Electrochem. Soc, 164 (11), E3254-E3264.

Liu, Z., Zhu, Z., Dai, J., and Yan, Y., 2018. "Waste biomass based-activated carbons derived from soybean pods as electrode materials for high-performance supercapacitors," Chemistry Select., 3, 5726 – 5732.

Lukatskaya, M. R., Dunn, B., and Gogotsi, Y., 2016. "Multidimensional materials and device architectures for future hybrid energy storage," Nat. Commun., 7, 12647–12659.

Pal, B., Yang, S., Ramesh, S., Thangadurai, V., and Jose, R., 2019. "Electrolyte selection for supercapacitive devices: a critical review," Nanoscale Adv., 1, 3807–3835.

Scibioh, M. A. and Viswanathan, B., 2020a. Materials for Supercapacitor Applications. Elsevier, New York, USA.

Scibioh, M. A. and Viswanathan, B., 2020b. Materials for Supercapacitor Applications. Elsevier, New York, USA

Shao, H., Wu, Y. C., Lin, Z., Taberna, P. L., and Simon, P., 2020. "Nanoporous carbon for electrochemical capacitive energy storage," Chem. Soc. Rev., 49, 3005–3039.

Singh A. P., Karandikar, P. B., and Tiwari, N. K., 2015. "Effect of electrode shape on the parameters of the supercapacitor," IEEE, 2015, 669–673.

Sinha, P., Banerjee, S., and Kar, K. K., 2020. Characteristics of Activated Carbon. Vol 300, Kar K. K., ed., Springer, Cambridge, United Kingdom.

Simon, P. and Gogotsi, Y., 2020. "Perspectives for electrochemical capacitors and related devices," Nat. Matter., 19, 1151-1161.

Stephane, K. D., Gupta, M., Kumar, A., Sharma, V., Pandit, S., Bocchetta, P., and Kumar, Y., 2021. "The effect of activated carbon materials modifications on the capacitive performance: surface, microstructure, and wettability," J. Compos. Sci., 5, 66.

Tanwilaisiri, A., Xu, Y., Zhang, R., Harrison, D., Fyson, J., and Areir, M., 2018. "Design and fabrication of modular supercapacitors using 3D printing", J. Energy Storage, 16, 1-7.

Trask, S. E., Kubal, J. J., Bettge, M., Bryant, J., Polzin, B. J., Zhu, Y., Danrew N., Jansen, A. N., and Abraham, D. P., 2014. "From coin cells to 400 mAh pouch cells: Enhancing performance of high-capacity lithium-ion cells via modifications in electrode constitution dan fabrication", J. of Power Sources, 259, 233-244.

Wang, Y., Song, Y., and Xia, Y., 2016. " Electrochemical capacitors: mechanism, materials, systems, characterization and applications," Chem. Soc. Rev., 45, 5925–5950

Wang, F., Wu X, Yuan, X., Liu, Z., Zhang, Y., Fu, L., Zhu, Y., Zhou, Q., Wu, Y., and Huang, W., 2017. "Latest advances in supercapacitors: from new electrode materials to novel device designs," Chem. Soc. Rev., 46, 6816–6854.

Wulandari, N.N., Rustamaji, H., Fibarzy, W.U., Prakoso, T., Rizkiana, J., Devianto, H., Widiatmoko, P., and Nurdin, I., 2020. "Production of activated carbon from palm empty fruit bunch as supercapacitor electrode material." IOP Conf. Series: Mater. Sci. Eng., 1143(1), 012004.

Xu Z., Li, Y., Li, D., Wang, D., Zhao, J., Wang, Z., Banis, M. N., Hu, Y., and Zhang, H., 2018. "N-enriched multilayered porous carbon derived from natural casings for high-performance supercapacitors," Appl. Surf. Sci., 444, 661–667.

Yang, W., Li, Y., and Feng, Y., 2018. "High electrochemical performance from oxygen functional groups containing porous activated carbon electrode of supercapacitors," Materials, 11, 2455.

Yang, H., Kannappan, S., Pandian, A. S., Jang, J. H., Lee, Y. S., and Lu, W., 2017. "Rapidly annealed nanoporous graphene materials for electrochemical energy storage," J. Mater. Chem. A, 5, 23720–23726.

Zhang, F., Zhang, T., Yang, X., Zhang, L., Leng, K., Huang, Y., and Chen, Y., 2013. "High-performance supercapacitor-battery hybrid energy storage device based on graphene-enhanced electrode materials with ultrahigh energy density," Energy Environ. Sci., 6, 1623-1632.

Zheng, Z. and Gao, Q., 2011. "Hierarchical porous carbons prepared by an easy one-step carbonization and activation of phenol-formaldehyde resins with high performance for supercapacitors," J. Power Sources 196, 1615–1619.

Zhong, C., Deng, Y, Hu, W., Jinli Qiao, J., Zhang, L., and Zhang, J., 2015. "A review of electrolyte materials and compositions for electrochemical supercapacitors," Chem. Soc. Rev., 44, 7484-7.