Preparation of composite material from layered double hydroxide (LDH) with hydrochar (HC) from duku peel produces CaAl-HC, MgAl-HC, and ZnAl-HC have shown the success of the preparation process as evidenced by characterizations such as XRD and FT-IR. The XRD characterization data evidenced the typical diffraction of the hydrochar around 2θ = 20° in the composite material. FTIR analysis is a characterization that supports the success of composite materials, which showed the presence of typical vibrations of HC at 3245, 2931, and 1635 cm^–1 contained in the composite spectrum. The application of MgAl-HC, CaAl-HC, and ZnAl-HC composites as adsorbents showed Q_max (adsorption ability) values of 94.340 mg/g, 128.205 mg/g, and 89.286 mg/g. Overall the adsorption process is endothermic with a positive enthalpy value, and a negative Gibbs free energy value indicates a spontaneous adsorption process. The isotherm model of MgAl-HC, CaAl-HC, and ZnAl-HC show that the Langmuir isotherm model is more dominant, as indicated by the R² value closer to 1 which indicates that the adsorption process takes place in a monolayer.

[1] Behbahani, E.S., Dashtian, K., and Ghaedi, M., 2020, Fe/Co-chalcogenide-stabilized Fe₃O₄ nanoparticles supported MgAl-layered double hydroxide as a new magnetically separable sorbent for the simultaneous spectrophotometric determination of anionic dyes, Microchem. J., 152, 104431.

[2] Starukh, H., and Levytska, S., 2019, The simultaneous anionic and cationic dyes removal with Zn e Al layered double hydroxides, Appl. Clay Sci., 180, 105183.

[3] Lim, S.J., and Kim, T.H., 2015, Combined treatment of swine wastewater by electron beam irradiation and ion-exchange biological reactor system, Sep. Purif. Technol., 146, 42–49.

[4] Zhuang, H., Han, H., Ma, W., Hou, B., Jia, S., and Zhao, Q., 2015, Advanced treatment of biologically pretreated coal gasification wastewater by a novel heterogeneous Fenton oxidation process, J. Environ. Sci., 33, 12–20.

[5] Mólgora, C.C., Domínguez, A.M., Avila, E.M., Drogui, P., and Buelna, G., 2013, Removal of arsenic from drinking water: A comparative study between electrocoagulation-microfiltration and chemical coagulation-microfiltration processes, Sep. Purif. Technol., 118, 645–651.

[6] Liu, H., Zhou, H., Li, H., Liu, X., Ren, C., Liu, Y., Li, W., and Zhang, M., 2019, Fabrication of Bi₂S₃@Bi₂WO₆/WO₃ ternary photocatalyst with enhanced photocatalytic performance: Synergistic effect of Z-scheme/traditional heterojunction and oxygen vacancy, J. Taiwan Inst. Chem. Eng., 95, 94–102.

[7] Liu, X., Zhou, Z., Yin, J., He, C., Zhao, W., and Zhao, C., 2020, Fast and environmental-friendly approach towards uniform hydrogel particles with ultrahigh and selective removal of anionic dyes, J. Environ. Chem. Eng., 8 (5), 104352.

[8] Milagres, J.L., Bellato, C.R., Ferreira, S.O., de M. Guimarães, L., de P. Tonon, G.J., and Bolandini, A., 2019, Simultaneous removal process of divalent metal and anionic and cationic dyes by layered reconstruction with hydrocalumite intercalated with dodecyl sulfate, Colloids Surf., A, 582, 123890.

[9] Meng, Z., Wu, M., Zhao, S., Jing, R., Li, S., Shao, Y., Liu, X., Lv, F., Liu, A., and Zhang, Q., 2019, Removing anionic dyes from wastewater based on in-situ formation of Fe₃O₄@Zn-Al layered double hydroxides by self-assembly, Appl. Clay Sci., 170, 41–45.

[10] Li, N., Chang, Z., Dang, H., Zhan, Y., Lou, J., Wang, S., Attique, S., Li, W., Zhou, H., and Sun, C., 2020, Deep eutectic solvents assisted synthesis of MgAl layered double hydroxide with enhanced adsorption toward anionic dyes, Colloids Surf., A, 591, 124507.

[11] Daud, M., Hai, A., Banat, F., Wazir, M.B., Habib, M., Bharath, G., and Al-Harthi, M.A., 2019, A review on the recent advances, challenges and future aspect of layered double hydroxides (LDH) – Containing hybrids as promising adsorbents for dyes removal, J. Mol. Liq., 288, 110989.

[12] Badri, A.F., Palapa, N.R., Mohadi, R., and Lesbani, A., 2020, Cationic dye removal by magnesium aluminum-biochar composite from aqueous solution, Int. J. Sci. Technol. Res., 9 (7), 186–190.

[13] He, H., Zhang, N., Chen, N., Lei, Z., Shimizu, K., and Zhang, Z., 2019, Efficient phosphate removal from wastewater by MgAl-LDHs modified hydrochar derived from tobacco stalk, Bioresour. Technol. Rep., 8, 100348.

[14] Balcomb, B., Singh, M., and Singh, S., 2015, Synthesis and characterization of layered double hydroxides and their potential as nonviral gene delivery vehicles, ChemistryOpen, 4 (2), 137–145.

[15] Palapa, N.R., Juleanti, N., Normah, N., Taher, T., and Lesbani, A., 2020, Unique Adsorption properties of malachite green on interlayer space of Cu-Al and Cu-Al-SiW₁₂O₄₀ layered double hydroxides, Bull. Chem. React. Eng. Catal., 15 (3), 653–661.

[16] Bamroongwongdee, C., Suwannee, S., and Kongsomsaksiri, M., 2019, Adsorption of Congo red from aqueous solution by surfactant-modified rice husk: Kinetic, isotherm and thermodynamic analysis, Songklanakarin J. Sci. Technol., 41 (5), 1076–1083.

[17] Alsamman, L., 2017, Development of Modified Layered Silicates with Superior Adsorption Properties for Uptake of Pollutants from Air and Water, Dissertation, RWTH Aachen University, Aachen, Germany.

[18] Siregar, P.M.S.B.N., Palapa, N.R., Wijaya, A., Fitri, E.S., and Lesbani, A., 2021, Structural stability of Ni/Al layered double hydroxide supported on graphite and biochar toward adorption of Congo red, Sci. Technol. Indones., 6 (2), 85–95.

[19] Wan Ngah, W.S., and Hanafiah, M.A.K.M., 2008, Adsorption of copper on rubber (Hevea brasiliensis) leaf powder: Kinetic, equilibrium and thermodynamic studies, Biochem. Eng. J., 39 (3), 521–530.

[20] Palapa, N.R., Taher, T., Wijaya, A., and Lesbani, A., 2021, Modification of Cu/Cr layered double hydroxide by Keggin type polyoxometalate as adsorbent of malachite green from aqueous solution, Sci. Technol. Indones., 6 (3), 209–217.

[21] Sahmoune, M.N., 2019, Evaluation of thermodynamic parameters for adsorption of heavy metals by green adsorbents, Environ. Chem. Lett., 17 (2), 697–704.

[22] Mahmoodi, N.M., Abdi, J., and Bastani, D., 2014, Direct dyes removal using modified magnetic ferrite nanoparticle, J. Environ. Health Sci. Eng., 12 (1), 96.

[23] Hashem, A., Ahmad, F., and Badawy, S.M., 2016, Adsorption of direct green 26 onto fix 3500 treated sawdust: Equilibrium, kinetic and isotherms, Desalin. Water Treat., 57 (28), 13334–13346.

[24] Yu, J., Zhang, X., Wang, D., and Li, P., 2018, Adsorption of methyl orange dye onto biochar adsorbent prepared from chicken manure, Water Sci. Technol., 77 (5), 1303–1312.

[25] Tran, T.V., Phan, T.Q.T., Nguyen, D.T.C., Nguyen, T.T., Nguyen, D.H., Vo, D.V.N., Bach, L.G., and Nguyen, T.D., 2020, Recyclable Fe₃O₄@C nanocomposite as potential adsorbent for a wide range of organic dyes and simulated hospital effluents, Environ. Technol. Innovation, 20, 101122.

[26] Nazir, M.A., Khan, N.A., Cheng, C., Shah, S.S.A., Najam, T., Arshad, M., Sharif, A., Akhtar, S., and Ur Rehman, A., 2020, Surface induced growth of ZIF-67 at Co-layered double hydroxide: Removal of methylene blue and methyl orange from water, Appl. Clay Sci., 190, 105564.

[27] Hua, P., Sellaoui, L., Franco, D., Netto, M.S., Luiz Dotto, G., Bajahzar, A., Belmabrouk, H., Bonilla-Petriciolet, A., and Li, Z., 2020, Adsorption of acid green and procion red on a magnetic geopolymer based adsorbent: Experiments, characterization and theoretical treatment, Chem. Eng. J., 383, 123113.

[28] Nazifa, T.H., Habba, N., Salmiati, S., Aris, A., and Hadibarata, T., 2018, Adsorption of procion red MX-5B and crystal violet dyes from aqueous solution onto corncob activated carbon, J. Chin. Chem. Soc., 65 (2), 259–270.