: Jackfruit is a fruit tree species distributed mainly in Southeast Asia and Brazil. The pulp and skin of jackfruit are widely used in various fields such as food, medicine, and interior decoration. However, the jackfruit processing into edible and usable products generates a large quantity of agricultural waste. In this review, we focused on summarizing the environmental applications of jackfruit waste in wastewater treatment. Specifically, the potential and application of activated carbon synthesized from jackfruit waste were assessed concerning the adsorption of organic dyes and metals from wastewater. In practical water treatment applications, the adsorption kinetic and isothermal models have been evaluated for activated carbon's suitability and adsorption capacity. This study acts as the basis for further development of the by-product materials to environmental treatment application and to reduce the negative impact of agricultural by-products on the environment.

[1] Elevitch, C.R., and Manner, H.I., 2006 “Artocarpus heterophyllus (jackfruit), ver. 1.1v.” in Species Profiles for Pacific Island Agroforestry, Eds. Elevitch, C.R., Permanent Agriculture Resources (PAR), Hōlualoa, Hawai‘i, 1–17.

[2] Witt, A., and Luke, Q., 2017, Guide to the Naturalized and Invasive Plants of Eastern Africa, CABI, Wallingford, UK.

[3] Rajabathar, J.R., Manoharan, S., Vijaya, J.J., Al-Lohedan, H.A., and Arunachalam, P., 2020, Synthesis of porous carbon nanostructure formation from peel waste for low-cost flexible electrode fabrication towards energy storage applications, J. Energy Storage, 32, 101735.

[4] Prakash, O., Kumar, R., Mishra, A., and Gupta, R., 2009, Artocarpus heterophyllus (jackfruit): An overview, Pharmacogn. Rev., 3 (6), 353.

[5] Baliga, M.S., Shivashankara, A.R., Haniadka, R., Dsouza, J., and Bhat, H.P., 2011, Phytochemistry, nutritional and pharmacological properties of Artocarpus heterophyllus Lam (jackfruit): A review, Food Res. Int., 44 (7), 1800–1811.

[6] Shamsudin, R., Ling, C.S., Ling, C.N., Muda, N., and Hassan, O., 2009, Chemical compositions of the jackfruit juice (Artocarpus) cultivar J33 during storage, J. Appl. Sci., 9, 3202–3204.

[7] Shinde, V., Pawar, C., Warang, O., Dandekar, V., Kulkarni, M., Josiya, J., and Joshi, M., 2021, Studies on preparation of ice-cream from jackfruit (Artocarpus heterophyllus) seed powder, Int. J. Chem. Stud., 9 (1), 2710–2712.

[8] Rengasamy, M., Raj, R.V., and Vedagiriswaran, N., 2017, Study on oil extraction from jackfruit seed and its application in biodiesel production, Elix. Renewable Energy, 102, 44269–44272.

[9] Felli, R., Yang, T.A., Wan Abdullah, W.N., and Zzaman, W., 2018, Effects of incorporation of jackfruit rind powder on chemical and functional properties of bread, Trop. Life Sci. Res., 29 (1), 113–126.

[10] Meethal, S.M., Kaur, N., Singh, J., and Gat, Y., 2017, Effect of addition of jackfruit seed flour on nutrimental, phytochemical and sensory properties of snack bar, Curr. Res. Nutr. Food Sci., 5 (2), 154–158.

[11] Duque-Acevedo, M., Belmonte-Ureña, L.J., Cortés-García, F.J., and Camacho-Ferre, F., 2020, Agricultural waste: Review of the evolution, approaches and perspectives on alternative uses, Global Ecol. Conserv., 22, e00902.

[12] Speight, J.G., 2020, “Sources of Water Pollution” in Natural Water Remediation, Butterworth–Heinemann, Oxford, UK, 165–198.

[13] Elbasiouny, H., Elbanna, B.A., Al-Najoli, E., Alsherief, A., Negm, S., Abou El-Nour, E., Nofal, A., and Sharabash, S., 2020, “Agricultural Waste Management for Climate Change Mitigation: Some Implications to Egypt” in Waste Management in MENA Regions, Eds. Negm, A., and Shareef, N., Springer Water. Springer, Cham, 149–169.

[14] Nagendran, R., 2011, “Agricultural Waste and Pollution” in Waste, A Handbook for Management, Eds. Letcher, T.M., and Vallero, D.A., Academic Press, Boston, 341–355.

[15] Xue, L., Zhang, P., Shu, H., Wang, R., and Zhang, S., 2016, Agricultural waste, Water Environ. Res., 88 (10), 1334–1369.

[16] Sathiparan, N., and De Zoysa, H.T.S.M., 2018, The effects of using agricultural waste as partial substitute for sand in cement blocks, J. Build. Eng., 19, 216–227.

[17] Obi, F., Ugwuishiwu, B., and Nwakaire, J., 2016, Agricultural waste concept, generation, utilization and management, Niger. J. Technol., 35 (4), 957–964.

[18] Rao, R.A.K., and Khan, M.A., 2009, Biosorption of bivalent metal ions from aqueous solution by an agricultural waste: Kinetics, thermodynamics and environmental effects, Colloids Surf., A, 332 (2-3), 121–128.

[19] Gontard, N., Sonesson, U., Birkved, M., Majone, M., Bolzonella, D., Celli, A., Angellier-Coussy, H., Jang, G.W., Verniquet, A., Broeze, J., Schaer, B., Batista, A.P., and Sebok, A., 2018, A research challenge vision regarding management of agricultural waste in a circular bio-based economy, Crit. Rev. Environ. Sci. Technol., 48 (6), 614–654.

[20] Abioye, A.M., and Ani, F.N., 2015, Recent development in the production of activated carbon electrodes from agricultural waste biomass for supercapacitors: A review, Renewable Sustainable Energy Rev., 52, 1282–1293.

[21] Soetardji, J.P., Widjaja, C., Djojorahardjo, Y., Soetaredjo, F.E., and Ismadji, S., 2014, Bio-oil from jackfruit peel waste, Procedia Chem., 9, 158–164.

[22] Ginting, M.H.S., Irvan, Misran, E., and Maulina, S., 2020, Potential of durian, avocado and jackfruit seed as raw material of bioethanol: a review, IOP Conf. Ser.: Mater. Sci. Eng., 801, 012045.

[23] Nsubuga, D., Banadda, N., Kabenge, I., and Wydra, K.D., 2020, Potential of jackfruit waste for biogas, briquettes and as a carbondioxide sink-A review, J. Sustainable Dev., 13 (4), 60–75.

[24] Bhushan, B., Nayak, A., and Kotnala, S., 2021, Green synthesis of highly porous activated carbon from jackfruit peel: Effect of operating factors on its physico-chemical characteristics, Mater. Today: Proc., 44, 187–191.

[25] Yadav, D., Rangabhashiyam, S., Verma, P., Singh, P., Devi, P., Kumar, P., Hussain, C.M., Gaurav, G.K., and Kumar, K.S., 2021, Environmental and health impacts of contaminants of emerging concerns: Recent treatment challenges and approaches, Chemosphere, 272, 129492.

[26] Manahan, S.E., 1997, Environmental Science and Technology, CRC Press, Boca Raton, Florida.

[27] Singh, S., Wasewar, K.L., and Kansal, S.K., 2020, “Low-Cost Adsorbents for Removal of Inorganic Impurities from Wastewater” in Inorganic Pollutants in Water, Eds. Devi, P., Singh, P., and Kansal, S.K., Elsevier, Amsterdam, Netherlands, 173–203.

[28] Menya, E., Olupot, P.W., Storz, H., Lubwama, M., and Kiros, Y., 2018, Production and performance of activated carbon from rice husks for removal of natural organic matter from water: A review, Chem. Eng. Res. Des., 129, 271–296.

[29] Nam, H., Choi, W., Genuino, D.A., and Capareda, S.C., 2018, Development of rice straw activated carbon and its utilizations, J. Environ. Chem. Eng., 6 (4), 5221–5229.

[30] Rattanapan, S., Srikram, J., and Kongsune, P., 2017, Adsorption of methyl orange on coffee grounds activated carbon, Energy Procedia, 138, 949–954.

[31] Bello, O.S., Adegoke, K.A., Sarumi, O.O., and Lameed, O.S., 2019, Functionalized locust bean pod (Parkia biglobosa) activated carbon for Rhodamine B dye removal, Heliyon, 5 (8), e02323.

[32] Yaseen, M., Ullah, S., Ahmad, W., Subhan, S., and Subhan, F., 2021, Fabrication of Zn and Mn loaded activated carbon derived from corn cobs for the adsorptive desulfurization of model and real fuel oils, Fuel, 284, 119102.

[33] Luo, X., and Zhang, L., 2009, High effective adsorption of organic dyes on magnetic cellulose beads entrapping activated carbon, J. Hazard. Mater., 171 (1-3), 340–347.

[34] Kumar, A., and Gupta, H., 2020, Activated carbon from sawdust for naphthalene removal from contaminated water, Environ. Technol. Innovation, 20, 101080.

[35] Thi, T.T.L., and Van, K.L., 2016, Adsorption behavior of Pb(II) in aqueous solution using coffee husk-based activated carbon modified by nitric acid, Am. J. Eng. Res., 5 (4), 120–129.

[36] Tran, V.A., Kadam, A.N., and Lee, S.W., 2020, Adsorption-assisted photocatalytic degradation of methyl orange dye by zeolite-imidazole-framework-derived nanoparticles, J. Alloys Compd., 835, 155414.

[37] Tran, V.A., Vu, K.B., Thi Vo, T.T., Le, V.T., Do, H.H., Bach, L.G., and Lee, S.W., 2021, Experimental and computational investigation on interaction mechanism of Rhodamine B adsorption and photodegradation by zeolite imidazole frameworks-8, Appl. Surf. Sci., 538, 148065.

[38] Hieu, V.Q., Phung, T.K., Nguyen, T.Q., Khan, A., Doan, V.D., Tran, V.A., and Le, V.T., 2021, Photocatalytic degradation of methyl orange dye by Ti₃C₂–TiO₂ heterojunction under solar light, Chemosphere, 276, 130154.

[39] Ranasinghe, S.H., Navaratne, A.N., and Priyantha, N., 2018, Enhancement of adsorption characteristics of Cr(III) and Ni(II) by surface modification of jackfruit peel biosorbent, J. Environ. Chem. Eng., 6 (5), 5670–5682.

[40] Sidhu, A.S., 2012, Jackfruit Improvement in the Asia-Pacific Region: A Status Report, Regional Consultation on Collective Actions for Opening Access to Agricultural Information and Knowledge in the Asia-Pacific Region, 13-15 December 2012, Thimphu, Bhutan.

[41] Foo, K.Y., and Hameed, B.H., 2012, Potential of jackfruit peel as precursor for activated carbon prepared by microwave induced NaOH activation, Bioresour. Technol., 112, 143–150.

[42] Tengku Hasbullah, T.N.A., Selaman, O.S., and Rosli, N.A., 2014, Removal of methylene blue from aqueous solutions using chemical activated carbon prepared from jackfruit (Artocarpus heterophyllus) peel waste, J. Civ. Eng. Sci. Technol., 5 (1), 34–38.

[43] Prahas, D., Kartika, Y., Indraswati, N., and Ismadji, S., 2008, Activated carbon from jackfruit peel waste by H₃PO₄ chemical activation: Pore structure and surface chemistry characterization, Chem. Eng. J., 140 (1-3), 32–42.

[44] Lee, K., Shabnam, L., Faisal, S.N., Hoang, V.C., and Gomes, V.G., 2020, Aerogel from fruit biowaste produces ultracapacitors with high energy density and stability, J. Energy Storage, 27, 101152.

[45] Nayak, A., Bhushan, B., Gupta, V., and Kotnala, S., 2021, Fabrication of microwave assisted biogenic magnetite-biochar nanocomposite: A green adsorbent from jackfruit peel for removal and recovery of nutrients in water sample, J. Ind. Eng. Chem., 100, 134–148.

[46] Nagalakshmi, T.V., Emmanuel, K.A., and Bhavani, P., 2019, Adsorption of disperse blue 14 onto activated carbon prepared from jackfruit-PPI-I waste, Mater. Today: Proc., 18, 2036–2051.

[47] Prasad, N., Kumar, P., and Pal, D.B., 2020, Cadmium removal from aqueous solution by jackfruit seed bio-adsorbent, SN Appl. Sci., 2 (6), 1018.

[48] Chaudhary, R., Maji, S., Shrestha, R.G., Shrestha, R.L., Shrestha, T., Ariga, K., and Shrestha, L.K., 2020, Jackfruit seed-derived nanoporous carbons as the electrode material for supercapacitors, C, 6 (4), 73.

[49] Mutiara, T., Rofiki, I., and Al Ghifari, M.A.D., 2018, Bio adsorbent from modified jackfruit wood sawdust for removal of lead ions, Mater. Sci. Forum, 934, 159–164.

[50] Nagalakshmi, T.V., Emmanuel, K.A., Suresh Babu, C., Chakrapani, C., and Divakar, P.P., 2015, Preparation of mesoporous activated carbon from jackfruit PPI-1 waste and development of different surface functional groups, Int. Lett. Chem., Phys. Astron., 54, 189–200.

[51] Foo, K.Y., and Hameed, B.H., 2012, A cost effective method for regeneration of durian shell and jackfruit peel activated carbons by microwave irradiation, Chem. Eng. J., 193-194, 404–409.

[52] Karmaker, S., Uddin, M.N., Ichikawa, H., Fukumori, Y., and Saha, T.K., 2015, Adsorption of reactive orange 13 onto jackfruit seed flakes in aqueous solution, J. Environ. Chem. Eng., 3 (1), 583–592.

[53] Ojha, A.K., and Bulasara, V.K., 2015, Adsorption Characteristics of jackfruit leaf powder for the removal of Amido black 10B dye, Environ. Prog. Sustainable Energy, 34 (2), 461–470.

[54] Kooh, M.R.R., Dahri, M.K., and Lim, L.B.L., 2016, Jackfruit seed as a sustainable adsorbent for the removal of Rhodamine B dye, J. Environ. Biotechnol. Res., 4 (1), 7–16.

[55] Saranya, N., Ajmani, A., Sivasubramanian, V., and Selvaraju, N., 2018, Hexavalent chromium removal from simulated and real effluents using Artocarpus heterophyllus peel biosorbent - Batch and continuous studies, J. Mol. Liq., 265, 779–790.

[56] Kooh, M.R.R., Dahri, M.K., and Lim, L.B.L., 2018, Jackfruit seed as low-cost adsorbent for removal of malachite green: Artificial neural network and random forest approaches, Environ. Earth Sci., 77 (12), 434.

[57] Das, M., and Mishra, C., 2019, Jackfruit leaf as an adsorbent of malachite green: Recovery and reuse of the dye, SN Appl. Sci., 1 (5), 483.

[58] Afroze, S., and Sen, T.K., 2018, A review on heavy metal ions and dye adsorption from water by agricultural solid waste adsorbents, Water Air Soil Pollut., 229 (7), 225.

[59] Sabir, A., Altaf, F., Batool, R., Shafiq, M., Khan, R.U., and Jacob, K.I., 2021, “Agricultural Waste Absorbents for Heavy Metal Removal” in Green Adsorbents to Remove Metals, Dyes and Boron from Polluted Water, vol. 49, Eds. Inamuddin, Ahamed, M.I., Lichtfouse, E., and Asiri, A.M., Springer, Cham, 195–228.

[60] Lu, X.G., and Guo, Y.T., 2019, Removal of Pb(II) from aqueous solution by sulfur-functionalized walnut shell, Environ. Sci. Pollut. Res., 26 (13), 12776–12787.

[61] Cid, H., Ortiz, C., Pizarro, J., and Moreno-Piraján, J.C., 2020, Effect of copper(II) biosorption over light metal cation desorption in the surface of Macrocystis pyrifera biomass, J. Environ. Chem. Eng., 8 (3) 103729.

[62] do Nascimento Júnior, W.J., da Silva, M.G.C., and Vieira, M.G.A., 2019, Environmental science and pollution research competitive biosorption of Cu²⁺ and Ag⁺ ions on brown macro-algae waste: Kinetic and ion-exchange studies, Environ. Sci. Pollut. Res., 26 (23), 23416–23428.

[63] Bernard, E., Jimoh, A., and Odigure, J.O., 2013, Heavy metals removal from industrial wastewater by activated carbon prepared from coconut shell, Res. J. Chem. Sci., 3 (8), 3–9.

[64] Premachandra, J.K., Manoj, B.S., Aberathne, S.N.P.P.G.P.E., and Warnapura, L.H.P., 2017, Removal of lead from synthetic wastewater using chemically modified jackfruit leaves, 2017 Moratuwa Engineering Research Conference (MERCon), Moratuwa, Sri Lanka, 29–31 May 2017, 29–33.

[65] Banu, H.A.T., Karthikeyan, P., and Meenakshi, S., 2019, Comparative studies on revival of nitrate and phosphate ions using quaternized corn husk and jackfruit peel, Bioresour. Technol. Rep., 8, 100331.

[66] Ndung’u, S.N., Wanjau, R.N., Nthiga, E.W., Ndiritu, J., and Mbugua, G.W., 2020, Complexation equilibrium studies of Cu²⁺, Cd²⁺ and Pb²⁺ ions onto ethylenediamine quaternised Artocarpus heterophyllus L. seeds from aqueous solution, IOSR J. Appl. Chem., 13 (12), 1–12.

[67] Giri, D.D., Alhazmi, A., Mohammad, A., Haque, S., Srivastava, N., Thakur, V.K., Gupta, V.K., and Pal, D.B., 2021, Lead removal from synthetic wastewater by biosorbents prepared from seeds of Artocarpus heterophyllus and Syzygium cumini, Chemosphere, 287, 132016.