Synthesis and Characterization of Activated Carbon from Waste Compedak Fruit (Artocarpus Champeden) Activated H3PO4 as Adsorbent of Methylene Blue

Authors

  • Catherina Bijang Pattimura University
  • Matheis F. J. D. P. Tanasale Pattimura University
  • Dewi Sri Pattimura University
  • Tahril Tahril Tadulako University
  • Thamrin Azis universitas Halu Oleo

DOI:

https://doi.org/10.22487/j24775185.2022.v11.i1.pp56-63

Keywords:

Activated carbon, cempedak peel, phosphoric acid, methylene blue

Abstract

Synthesis of activated carbon from cempedak peel waste is carried out to utilize biomass waste. This study aimed to synthesize and characterize activated carbon from cempedak peel waste. The synthesis was carried out by chemical activation using phosphoric acid with a dry impregnation ratio of 1:4 (g sample:g H3PO4). Samples impregnated for 24 hours were then heated at 250℃—and then calcined at 350℃ and 450℃. The XRD and FTIR characterization results indicated that the activated carbon obtained had an amorphous structure and the activated carbon obtained had hydroxyl, carbonyl, and carboxylic groups. Activated carbon with the highest yield was obtained at a temperature of 350, namely 43%. The results of determining the water content of activated carbon obtained are 8.36% at 350 0C and 7.1% at 450 ℃. The value of water content and ash content of activated carbon from the skin of this cempedak fruit has met the Indonesian National Standard (SNI 06-3730-1995). The best-activated carbon yield was at a calcination temperature of 450, with the percentage of adsorption efficiency on methylene blue of 98.88%.

Author Biographies

Catherina Bijang, Pattimura University

Department of Chemistry, Faculty of Mathematics and Natural Sciences

Matheis F. J. D. P. Tanasale, Pattimura University

Department of Chemistry, Faculty of Mathematics and Natural Sciences

Dewi Sri, Pattimura University

Department of Chemistry, Faculty of Mathematics and Natural Sciences

Tahril Tahril, Tadulako University

Department of Chemistry, Faculty of Teacher Training and Education

Thamrin Azis, universitas Halu Oleo

Department of Chemistry, Faculty of Mathematics and Natural Sciences

References

Aisiyah, R. H. (2016), Pemanfaatan karbon aktif dari limbah tongkol jagung sebagai filter air. Unpublished undergraduate thesis. Bogor: Fakultas Matematika dan Ilmu Pengetahuan Alam, Instiut Pertanian Bogor.

Angela, M. N. S., Andreas, A., & Putranto, A. (2015). Sintesis karbon aktif dari kulit salak dengan aktivasi H3PO4 sebagai adsorben larutan zat warna metilen biru. Prosiding Seminar Nasional Teknik Kimia “Kejuangan” Pengembangan Teknologi Kimia untuk Pengolahan Sumber Daya Alam (pp 1-7). Yogyakarta: Program Studi Teknik Kimia Fakultas Teknologi Industri Universitas Pembangunan Nasional.

Aryani, F., Mardiana, F., & Wartomo. (2019. Aplikasi metode aktivitas fisika dan aktivitas kimia pada pembuatan arang aktif dari tempurung kelapa (cocos nucifera l). Indonesian Journal of Laboratory, 1(2), 16-20.

Azevedo, D. C. S., Araújo, J. C. S., Bastos-Neto, M., Torres, A. E. B., Jaguaribe, E. F., & Cavalcante, C. L. (2007). Microporous activated carbon prepared from coconut shells using chemical activation with zinc chloride. Microporous and Mesoporous Materials, 100(1), 361–364.

Darajat, S., Aziz, H., & Alif, A. (2008). Seng oksida (ZnO) sebagai fotokatalis pada proses degradasi senyawa biru metilen. Jurnal Riset Kimia, 1(2),

Darmawan, S., Syafii, W., Wistara, N. J., Maddu, A., & Pari, G. (2015). Kajian struktur arang-pirolisis, arang-hidro dan karbon aktif dari kayu acacia mangium willd menggunakan difraksi sinar-X. Jurnal Penelitian Hasil Hutan, 33(2), 81–92.

Dini, E. W. P., & Wardhani, S. (2014). Degradasi metilen biru menggunakan fotokatalis ZnO-Zeolit. Chemistry Progress, 7(1), 29-33.

Eletta, O. A. A., Tijani, I. O., & Ighalo, J. O. (2020). Adsorption of Pb(II) and phenol from wastewater using silver nitrate modified activated carbon from groundnut (arachis hypogaea l.) shells. The West Indian Journal of Engineering, 43(1), 26-35.

Jamilatun, S., Salamah, S., & Isparulita, I. D. (2015). Karakteristik arang aktif dari tempurung kelapa dengan pengaktivasi H2SO4 variasi suhu dan waktu. Chemica: Jurnal Teknik Kimia, 2(1), 13-19.

Juwita, A. I., Mustafa, A., & Tamrin, R. (2017). Studi pemanfaatan kulit kopi arabika (coffee arabica l.) sebagai mikro organisme lokal (mol). Agrointek, 11(1), 1-8.

Kumar, V., & Tyagi, P. K. (2018). Potential application of multi-walled carbon nanotubes/activated carbon/bamboo charcoal for efficient alcohol sensing. Journal of Alloys and Compounds, 767(October), 215-222.

Kurniasari, L., Riwayati, I., & Suwardiyono. (2012). Pektin sebagai alternatif bahan baku biosorben logam berat. Momentum, 8(1), 1-5.

Lestari, K. D., Ratnani, R. D., Suwardiyono., & Kholis, N. (2017). Pengaruh waku dan suhu pembuatan karbon aktif dari tempurung kelapa sebagai upaya pemanfaatan limbah dengan suhu tinggi secara pirolisis. Jurnal Inovasi Teknik Kimia, 2(1), 32-38.

Lewoyehu, M. (2021). Comprehensive review on synthesis and application of activated carbon from agricultural residues for the remediation of venomous pollutants in wastewater. Journal of Analytical and Applied Pyrolysis, 159(October), 1-17.

Lim, A., Chew, J. J., Ngu, L. H., Ismadji, S., Khaerudini, D. S., & Sunarso, J. (2020), synthesis, characterization, adsorption isotherm, and kinetic study of oil palm trunk-derived activated carbon for tannin removal from aqueous solution. American Chemical Society Omega, 5(44), 28673−28683.

Muhtar. (2013). Pilarisasi bentonit menggunakan MoO3 dan aplikasinya pada degradasi martius yellow. Unpublished undergraduate thesis. Jakarta: Universitas Indonesia.

Musa, S. H. (2013). Kinetika adsorpsi zat warna biru metilena oleh karbon aktif dari kulit kemiri (aleurites moluccana (l) willd). Unpublished undergraduate thesis. Ambon: Fakultas Matematika Dan Ilmu Pengetahuan Alam, Universitas Pattimura.

Nagalakshmi, T. V., Emmanuel, K. A., & Bhavani, P. (2019). Adsorption of disperse blue 14 onto activated carbon prepared from jackfruit-PPI-I waste. Materialstoday: Proceedings, 18(6), 2036-2051.

Nurhasni., Mar’af, R., & Hendrawati, H. (2018), Pemanfaatan kulit kacang tanah (arachis hipogaea l.) sebagai adsorben zat warna metilen biru. Jurnal Kimia Valensi, 4(2), 156–167.

Olivares-Marín, M., Fernández-González, C., Macías-García, A., & Gómez-Serrano, V. (2006). Preparation of activated carbon from cherry stones by chemical activation with ZnCl2. Applied Surface Science, 252(17), 5967–5971.

Pari, G. (2011). Pengaruh selulosa terhadap struktur karbon bagian 1: Pengaruh suhu karbonisasi. Jurnal Penelitian Hasil Hutan, 29(1), 33–45.

Perdani, F. P., Riyanto, C. A., & Martono, Y. (2021). Karakterisasi karbon aktif kulit singkong (manihot esculenta crantz) berdasarkan variasi konsentrasi H3PO4 dan lama waktu aktivasi. Indonesian Journal of Chemical Analysis, 4(2), 72-81.

Prabu, P., & Raghu, K. (2017). Synthesis and characterization of cotton stalk activated carbon by chemical activation using H3PO4. International Journal of Advanced Science and Research, 2(5), 93-97.

Prahas, D., Kartika, Y., Indraswati, N., & Ismadji, S. (2008). The use of activated carbon prepared from jackfruit (artocarpus heterophyllus) peel waste for methylene blue removal. Journal of Enviromental Protection Science, 2, 1-10.

Putri, M. P., Lukis, P. A., & Mawarni, L. P. (2020). Isolation and characterization of pectin from waste of “raja nangka” banana peels (musa acuminata (AAA cv)). EduChemia (Jurnal Kimia dan Pendidikan, 5(1), 60-71.

Rahmawati, A. A., Ardana, M., & Sastyarin Y. (2021). Kajian literatur: aktivitas antioksidan ekstrak tanaman cempedak (artocarpus champeden spreng). Proceeding of Mulawarman Pharmaceuticals Conferences (pp 385-388). Samarinda: Faculty of Pharmacy, Mulawarman University.

Ramayana, D., Royani, I., & Arsyad, F. S. (2017). Pembuatan carbon black berbasis nanoserbuk tempurung biji karet menggunakan high energy milling. Jurnal MIPA (Indonesian Journal of Mathematics and Natural Sciences, 40(1), 28-32.

Sahara, E., Dahliani, N. K., & Manuaba, I. B. P., (2017). Pembuatan dan karakterisasi arang aktif dari batang tanaman gumitir (tagetes erecta) dengan aktivator NaOH. Jurnal Kimia, 11(2), 174-180.

Sangi, M. S., Momuat, L. I., & Kumaunang, M. (2012). Uji toksisitas dan skrining fitokimia tepung gabah pelepah aren (arenga pinnata). Jurnal Ilmiah Sains, 12(2), 127-134.

Saputro, M. (2010). Pembuatan karbon aktif dari kulit kacang tanah (arachis hypogeae) dengan aktifator asam sulfat. Unpublished undergraduate thesis. Semarang: Universitas Dipenogoro.

Sawalha, H., Maghalseh, M., Qutaina, J., K Junaidi, K., & Rene, E. R. (2020). Removal of hydrogen sulfide from biogas using activated carbon synthesized from different locally available biomass wastes - a case study from Palestine. Bioengineered, 11(1), 607-618

Sudrajat, R. (2011) Arang aktif: Teknologi pengolahan dan depannya. Jakarta: Badan Litbang kehutanan.

Sunarsih, S., & Dahani, W. (2018). Studi adsorpsi karbon aktif limbah kulit buah nangka rhodamin B. Jurnal Teknologi, 11(1), 46-53.

Teddy, M., Bijang, C. M., Nurdin, M., & Kapelle, B. (2018). The influence of calcination temperatures in TiO2 impregnated ouw’s natural clay on its degradation activity of methylene blue dye. Science Nature, 1(1), 008-014.

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Published

2022-02-28

How to Cite

Bijang, C. ., Tanasale, M. F. J. D. P. ., Sri, D. ., Tahril, T., & Azis, T. (2022). Synthesis and Characterization of Activated Carbon from Waste Compedak Fruit (Artocarpus Champeden) Activated H3PO4 as Adsorbent of Methylene Blue. Jurnal Akademika Kimia, 11(1), 56–63. https://doi.org/10.22487/j24775185.2022.v11.i1.pp56-63

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Vol. 11 No. 1 (2022)

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