SINTESIS FISIKOKIMIA DARI KARBON AKTIF BERBASIS BIOMASSA SABUT NIPAH (Nypa fruticans) UNTUK PERFORMANSI KINERJA SUPERKAPASITOR

Irma Apriyani, Rakhmawati Farma, Awitdrus Awitdrus, Aria Yunita

Abstract


Biomass-based activated carbon materials provide a new approach for the development of high-performance electrode materials for supercapacitor cells. In addition, the carbon materials are low cost and sustainable for large-scale production of electrode materials. In this study, carbon electrodes made from nipa palm (Nypa fruticans) coir were synthesized physicochemically. The pore size distribution of the carbon electrodes can be adjusted with the increased CO2 activation temperature (700°C, 800°C, and 900°C). The results showed that the SN-800 carbon electrode had the lowest density shrinkage and showed excellent electrochemical performance. The highest specific capacitance was obtained at 247 F/g at a current density of 1 A/g in a symmetrical two-electrode system. This work provides an efficient strategy for the preparation of high performance carbon electrodes based on nipa coir biomass.

Keywords


Nipa Coir; Activated Carbon; Physicochemistry; Electrochemical Capacitors

References


1. De, B., Banerjee, S., Pal, T., Verma, K. D., Tyagi, A., Manna, P. K., & Kar, K. K. (2020). Transition metal oxide-/carbon-/electronically conducting polymer-based ternary composites as electrode materials for supercapacitors. Handbook of Nanocomposite Supercapacitor Materials II: Performance, 387–434.

2. Wang, Y., Qu, Q., Gao, S., Tang, G., Liu, K., He, S., & Huang, C. (2019). Biomass derived carbon as binder-free electrode materials for supercapacitors. Carbon, 155, 706–726.

3. Gopalakrishnan, A., & Badhulika, S. (2020). Effect of self-doped heteroatoms on the performance of biomass-derived carbon for supercapacitor applications. Journal of power sources, 480, 228830.

4. Wei, X., Li, Y., & Gao, S. (2017). Correction: Biomass-derived interconnected carbon nanoring electrochemical capacitors with high performance in both strongly acidic and alkaline electrolytes. Journal of Materials Chemistry A, 5(38), 20505–20505.

5. Farma, R., Husni, H., Apriyani, I., Awitdrus, A., & Taer, E. (2021). Biomass waste-derived rubber seed shell functionalized porous carbon as an inexpensive and sustainable energy material for supercapacitors. Journal of Electronic Materials, 50, 6910–6919.

6. Wang, J., Zhang, X., Li, Z., Ma, Y., & Ma, L. (2020). Recent progress of biomass-derived carbon materials for supercapacitors. Journal of Power Sources, 451, 227794.

7. Kar, K. K. (2020). Handbook of nanocomposite supercapacitor materials II, 302.

8. Islam, M. A., Ong, H. L., Halim, K. A. A., Ganganboina, A. B., & Doong, R. A. (2021). Biomass–derived cellulose nanofibrils membrane from rice straw as sustainable separator for high performance supercapacitor. Industrial Crops and Products, 170, 113694.

9. Jiang, G., Senthil, R. A., Sun, Y., Kumar, T. R., & Pan, J. (2022). Recent progress on porous carbon and its derivatives from plants as advanced electrode materials for supercapacitors. Journal of Power Sources, 520, 230886.

10. Muzaffar, A., Ahamed, M. B., Deshmukh, K., & Thirumalai, J. (2019). A review on recent advances in hybrid supercapacitors: Design, fabrication and applications. Renewable and sustainable energy reviews, 101, 123–145.

11. Wang, J., Xu, Y., Yan, M., Ren, B., Dong, X., Miao, J., ... & Liu, Z. (2022). Preparation and application of biomass-based porous carbon with S, N, Zn, and Fe heteroatoms loading for use in supercapacitors. Biomass and Bioenergy, 156, 106301.

12. Sundriyal, S., Shrivastav, V., Pham, H. D., Mishra, S., Deep, A., & Dubal, D. P. (2021). Advances in bio-waste derived activated carbon for supercapacitors: Trends, challenges and prospective. Resources, Conservation and Recycling, 169, 105548.

13. Zhang, X., Sun, B., Fan, X., Liang, P., Zhao, G., Saikia, B. K., & Wei, X. (2022). Hierarchical porous carbon derived from coal and biomass for high performance supercapacitors. Fuel, 311, 122552.

14. Pang, X., Cao, M., Qin, J., Li, X., & Yang, X. (2022). Synthesis of bamboo-derived porous carbon: Exploring structure change, pore formation and supercapacitor application. Journal of Porous Materials, 29(2), 559–569.

15. Jalalah, M., Sivasubramaniam, S. S., Aljafari, B., Irfan, M., Almasabi, S. S., Alsuwian, T., ... & Harraz, F. A. (2022). Biowaste assisted preparation of self-nitrogen-doped nanoflakes carbon framework for highly efficient solid-state supercapacitor application. Journal of Energy Storage, 54, 105210.

16. Subramanian, D., Raju, G., Palanivel, B., Al-Zaqri, N., & Hossain, M. S. (2022). Exploration of ONS heteroatom self-doped mesoporous activated carbon derived from Datura stramonium seed pods as a potential electrode for supercapacitor application. Ionics, 28(5), 2363–2375.

17. Moudingo, J. H., Ajonina, G., Dibong, D., & Tomedi, M. (2020). Distribution, devastating effect, and drivers of the exotic mangrove Nypa fruticans Van Wurmb (Arecaceae) on the mangroves of West and Central Africa. Biotechnological Utilization of Mangrove Resources, 49–78.

18. Tamunaidu, P., & Saka, S. (2011). Chemical characterization of various parts of nipa palm (Nypa fruticans). Industrial Crops and Products, 34(3), 1423–1428.

19. Farma, R., Putri, A., Taer, E., Awitdrus, A., & Apriwandi, A. (2021). Synthesis of highly porous activated carbon nanofibers derived from bamboo waste materials for application in supercapacitor. Journal of Materials Science: Materials in Electronics, 32, 7681–7691.

20. Baig, M. M., & Gul, I. H. (2021). Conversion of wheat husk to high surface area activated carbon for energy storage in high-performance supercapacitors. Biomass and Bioenergy, 144, 105909.

21. Jiang, C., Yakaboylu, G. A., Yumak, T., Zondlo, J. W., Sabolsky, E. M., & Wang, J. (2020). Activated carbons prepared by indirect and direct CO2 activation of lignocellulosic biomass for supercapacitor electrodes. Renewable Energy, 155, 38–52.

22. Saka, C., Baytar, O., Yardim, Y., & Şahin, Ö. (2020). Improvement of electrochemical double-layer capacitance by fast and clean oxygen plasma treatment on activated carbon as the electrode material from walnut shells. Biomass and Bioenergy, 143, 105848.

23. Gunasekaran, S. S., Gopalakrishnan, A., Subashchandrabose, R., & Badhulika, S. (2021). Single step, direct pyrolysis assisted synthesis of nitrogen-doped porous carbon nanosheets derived from bamboo wood for high energy density asymmetric supercapacitor. Journal of Energy Storage, 42, 103048.

24. Gupta, G. K., Sagar, P., Pandey, S. K., Srivastava, M., Singh, A. K., Singh, J., ... & Srivastava, A. (2021). In situ fabrication of activated carbon from a bio-waste desmostachya bipinnata for the improved supercapacitor performance. Nanoscale research letters, 16(1), 85.

25. Xiao, K., Ding, L. X., Chen, H., Wang, S., Lu, X., & Wang, H. (2016). Nitrogen-doped porous carbon derived from residuary shaddock peel: a promising and sustainable anode for high energy density asymmetric supercapacitors. Journal of Materials Chemistry A, 4(2), 372–378.




DOI: http://dx.doi.org/10.31258/jkfi.20.2.127-134

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