Mesoporous activated carbon-zeolite composite prepared from waste macadamia nut shell and synthetic faujasite

doi:10.1016/j.cjche.2018.06.024

Abstract

Abstract: Novel activated carbon-zeolite composite adsorbent was prepared from macadamia shell bio-waste and synthetic zeolite X using hydrothermal treatment. Characterisation studies revealed mainly mesoporous structure with 418 m²·g^-1 BET surface area with faujasite clusters on the carbon carrier. Sorption capacity for methylene blue model pollutant increased from 85 to 97 mg·g^-1 with the temperature increase from 25 to 45℃, and improved with increasing pH. Nonlinear regression analyses found accurate fit to the pseudo-first-order kinetics model and intra-particle diffusion rate controlling mechanism. Excellent fits to the Jovanovic isotherm model indicated monolayer coverage on chiefly homotattic surfaces with variable potential. The thermodynamic analysis confirmed spontaneous and endothermic physisorption process. The spent adsorbent was regenerated with 20% capacity loss over five reuse cycles. Although the adsorbent was developed for ammonia, heavy metal and organic matter removal from water sources, the results also indicate good performance in cationic dye removal from wastewaters.

Key words: Activated carbon, Adsorption, Synthetic faujasite, Functional composite, Methylene blue

摘要： Novel activated carbon-zeolite composite adsorbent was prepared from macadamia shell bio-waste and synthetic zeolite X using hydrothermal treatment. Characterisation studies revealed mainly mesoporous structure with 418 m²·g^-1 BET surface area with faujasite clusters on the carbon carrier. Sorption capacity for methylene blue model pollutant increased from 85 to 97 mg·g^-1 with the temperature increase from 25 to 45℃, and improved with increasing pH. Nonlinear regression analyses found accurate fit to the pseudo-first-order kinetics model and intra-particle diffusion rate controlling mechanism. Excellent fits to the Jovanovic isotherm model indicated monolayer coverage on chiefly homotattic surfaces with variable potential. The thermodynamic analysis confirmed spontaneous and endothermic physisorption process. The spent adsorbent was regenerated with 20% capacity loss over five reuse cycles. Although the adsorbent was developed for ammonia, heavy metal and organic matter removal from water sources, the results also indicate good performance in cationic dye removal from wastewaters.

关键词: Activated carbon, Adsorption, Synthetic faujasite, Functional composite, Methylene blue

Surachai Wongcharee, Vasantha Aravinthan, Laszlo Erdei. Mesoporous activated carbon-zeolite composite prepared from waste macadamia nut shell and synthetic faujasite[J]. Chin.J.Chem.Eng., 2019, 27(1): 226-236.

References

[1] AMS (Australian Macadamia Society), Australian macadamia crop shows recovery[2017-02-17], http://australian-macadamias.org/industry/site/industry/industrypage/industry-news-archive/media-releases-industry/2016-australian-macadamiacrop-remains-on-track-for-46750-tonnes-in-shell?Itemid=133&lang=en.

[2] L.H. Wartelle, W.E. Marshall, Nutshells as granular activated carbons:Physical, chemical and adsorptive properties, J. Chem. Technol. Biotechnol. 76(2001) 451-455.

[3] G.E.J. Poinern, G. Senanayake, N. Shah, X.N. Thi-Le, G.M. Parkinson, D. Fawcett, Adsorption of the aurocyanide, complex on granular activated carbons derived from macadamia nut shells-A preliminary study, Miner. Eng. 24(2011) 1694-1702.

[4] L.A. Rodrigues, L.A. de Sousa Ribeiro, G.P. Thim, R.R. Ferreira, M.O. Alvarez-Mendez, A. dos R. Coutinho, Activated carbon derived from macadamia nut shells:An effective adsorbent for phenol removal, J. Porous. Mater. 20(2013) 619-627.

[5] O. Pezoti Junior, A.L. Cazetta, R.C. Gomes, E.O. Barizao, I.P.A.F. Souza, A.C. Martins, T. Asefa, V.C. Almeida, Synthesis of ZnCl₂-activated carbon from macadamia nut endocarp (Macadamia integrifolia) by microwave-assisted pyrolysis:Optimization using RSM and methylene blue adsorption, J. Anal. Appl. Pyrolysis 105(2014) 166-176.

[6] D.W. Breck, Zeolite Molecular Sieves:Structure, Chemistry, and Use, 1st ed. WileyInterscience, New York, 1974.

[7] J. Hlavay, G.Y. Vigh, V. Olaszi, J. Inczedy, Investigations on natural Hungarian zeolite for ammonia removal, Water Res. 16(1982) 417-420.

[8] G. Blanchard, M. Maunaye, G. Martin, Removal of heavy metals from waters by means of natural zeolites, Water Res. 18(1984) 1501-1507.

[9] V. Meshko, L. Markovska, M. Mincheva, A.E. Rodrigues, Adsorption of basic dyes on granular activated carbon and natural zeolite, Water Res. 35(2001) 3357-3366.

[10] S. Shevade, R.G. Ford, Use of synthetic zeolites for arsenate removal from pollutant water, Water Res. 38(2004) 3197-3204.

[11] N.F. Chelishchev, Use of natural zeolites for liquid radioactive wastes treatment (Russian experience), in:H.G. Karge, J. Weitkamp (Eds.), Stud. Surf. Sci. Catal, Elsevier, 1995.

[12] A. Rossner, S.A. Snyder, D.R.U. Knappe, Removal of emerging contaminants of concern by alternative adsorbents, Water Res. 43(2009) 3787-3796.

[13] C.K. Lim, H.H. Bay, C.H. Neoh, A. Aris, Z. Abdul Majid, Z. Ibrahim, Application of zeoliteactivated carbon macrocomposite for the adsorption of Acid Orange 7:Isotherm, kinetic and thermodynamic studies, Environ. Sci. Pollut. Res. 20(2013) 7243-7255.

[14] A.A. Halim, H.A. Aziz, M.A.M. Johari, K.S. Ariffin, Landfill leachate treatment using combination of hydrophobic-hydrophilic and low cost adsorption materials as a single media, 1st Civ. Eng. Colloq., USM, Nibong Tebal, Penang, Malaysia, 2006.

[15] M. Miyake, Y. Kimura, T. Ohashi, M. Matsuda, Preparation of activated carbon-zeolite composite materials from coal fly ash, Microporous Mesoporous Mater. 112(2008) 170-177.

[16] N.F. Gao, S. Kume, K. Watari, Zeolite-carbon composites prepared from industrial wastes:(I) Effects of processing parameters, Mater. Sci. Eng. A 399(2005) 216-221.

[17] N. Koshy, D.N. Singh, Fly ash zeolites for water treatment applications, J. Environ. Chem. Eng. 4(2016) 1460-1472.

[18] K.Y. Foo, B.H. Hameed, The environmental applications of activated carbon/zeolite composite materials, Adv. Colloid Interf. Sci. 162(2011) 22-28.

[19] S. Wang, Y. Boyjoo, A. Choueib, E. Ng, H. Wu, Z. Zhu, Role of unburnt carbon in adsorption of dyes on fly ash, J. Chem. Technol. Biotechnol. 80(2005) 1204-1209.

[20] C.W. Purnomo, Utilization of bagasse fly ash for carbon-zeolite composite preparation, J. Porous. Mater. 20(2013) 1305-1313.

[21] M.E. Davis, Ordered porous materials for emerging applications, Nature 417(2002) 813-821.

[22] S.C. Pillai, S. Hehir, Sol-Gel Materials for Energy, Environment and Electronic Applications, Springer, 2017.

[23] C.W. Purnomo, C. Salim, H. Hinode, Synthesis of pure Na-X and Na-A zeolite from bagasse fly ash, Microporous Mesoporous Mater. 162(2012) 6-13.

[24] L. Ai, C. Zhang, F. Liao, Y. Wang, M. Li, L. Meng, J. Jiang, Removal of methylene blue from aqueous solution with magnetite loaded multi-wall carbon nanotube:Kinetic, isotherm and mechanism analysis, J. Hazard. Mater. 198(2011) 282-290.

[25] J. Ozaki, K. Takahashi, M. Sato, A. Oya, Preparation of ZSM-5 nanoparticles supported on carbon substrate, Carbon (N. Y.) 44(2006) 1243-1249.

[26] P. Palanivell, O.H. Ahmed, K. Susilawati, M.N. Ab Majid, Mitigating ammonia volatilization from urea in waterlogged condition using clinoptilolite zeolite, Int. J. Agric. Biol. 17(2015) 149-155.

[27] S. Wang, Y. Peng, Natural zeolites as effective adsorbents in water and wastewater treatment, Chem. Eng. J. 156(2010) 11-24.

[28] D.-S. Kim, Measurement of point of zero charge of bentonite by solubilization technique and its dependence of surface potential on pH, Environ. Eng. Res. 8(2003) 222-227.

[29] C.N.R. Amaral, F.N. Feiteira, R.C. Cruz, V.O. Cravo, R.J. Cassella, W.F. Pacheco, Removal of basic violet 3 dye from aqueous media using a steel industry residue as solid phase, J. Environ. Chem. Eng. 4(2016) 4184-4193.

[30] M. Keiluweit, M. Kleber, Molecular-level interactions in soils and sediments:the role of aromatic π-systems, Environ. Sci. Technol. 43(2009) 3421-3429.

[31] M. Badertscher, E. Pretsch, Bad results from good data, TrAC Trends Anal. Chem. 25(2006) 1131-1138.

[32] Y.-S. Ho, Selection of optimum sorption isotherm, Carbon (N. Y.) 42(2004) 2115-2116.

[33] A.W.M. Ip, J.P. Barford, G. McKay, Reactive Black dye adsorption/desorption onto different adsorbents:Effect of salt, surface chemistry, pore size and surface area, J. Colloid Interface Sci. 337(2009) 32-38.

[34] Y.-S. Ho, G. McKay, Sorption of dye from aqueous solution by peat, Chem. Eng. J. 70(1998) 115-124.

[35] C.P. Bergmann, F. Machado, Carbon Nanomaterials as Adsorbents for Environmental and Biological Applications, Springer International Publishing, 2015.

[36] R.-S. Juang, M.-L. Chen, Application of the elovich equation to the kinetics of metal sorption with solvent-impregnated resins, Ind. Eng. Chem. Res. 36(1997) 813-820.

[37] C. Sutherland,C.Venkobachar,A diffusion-chemisorptionkineticmodelfor simulating biosorption using forest macro-fungus, fomesfasciatus, Int. Res. J. Plant Sci. 1(2010) 107-117.

[38] N.F. Cardoso, E.C. Lima, I.S. Pinto, C.V. Amavisca, B. Royer, R.B. Pinto, W.S. Alencar, S.F.P. Pereira, Application of cupuassu shell as biosorbent for the removal of textile dyes from aqueous solution, J. Environ. Manag. 92(2011) 1237-1247.

[39] Y. Liu, L. Shen, A general rate law equation for biosorption, Biochem. Eng. J. 38(2008) 390-394.

[40] L. Largitte, R. Pasquier, A review of the kinetics adsorption models and their application to the adsorption of lead by an activated carbon, Chem. Eng. Res. Des. 109(2016) 495-504.

[41] H. Sontheimer, J.C. Crittenden, R.S. Summers, Activated Carbon for Water Treatment, 2nd ed. DVGW-Forschungsstelle, Karlsruhe, Germany, 1988.

[42] H. Freundlich, W.J. Helle, Ubber die adsorption in lusungen, J. Am. Chem. Soc. 61(1939) 2-28.

[43] M.I. Temkin, V. Pyzhev, Kinetics of ammonia synthesis on promoted iron catalysts, Acta Physicochim. URSS 12(1940) 217-222.

[44] W.D. Harkins, G. Jura, The decrease (π) of free surface energy (γ) as a basis for the development of equations for adsorption isotherms; and the existence of two condensed phases in films on solids, J. Chem. Phys. 12(1944) 112-113.

[45] D.S. Jovanovic, Physical adsorption of gases, Kolloid Z. Z. Polym. 235(1969) 1203-1213.

[46] R. Han, J. Zhang, P. Han, Y. Wang, Z. Zhao, M. Tang, Study of equilibrium, kinetic and thermodynamic parameters about methylene blue adsorption onto natural zeolite, Chem. Eng. J. 145(2009) 496-504.

[47] Y. Yu, B.N. Murthy, J.G. Shapter, K.T. Constantopoulos, N.H. Voelcker, A.V. Ellis, Benzene carboxylic acid derivatized graphene oxide nanosheets on natural zeolites as effective adsorbents for cationic dye removal, J. Hazard. Mater. 260(2013) 330-338.

[48] J. Xie, C. Li, L. Chi, D. Wu, Chitosan modified zeolite as a versatile adsorbent for the removal of different pollutants from water, Fuel 103(2013) 480-485.

[49] K.Y. Hor, J.M.C. Chee, M.N. Chong, B. Jin, C. Saint, P.E. Poh, R. Aryal, Evaluation of physicochemical methods in enhancing the adsorption performance of natural zeolite as low-cost adsorbent of methylene blue dye from wastewater, J. Clean. Prod. 118(2016) 197-209.

[50] Y. Zhang, J. Shang, Y. Song, C. Rong, Y. Wang, W. Huang, K. Yu, Selective Fenton-like oxidation of methylene blue on modified Fe-zeolites prepared via molecular imprinting technique, Water Sci. Technol. 75(2017) 659-669.

[51] S. Banerjee, G.C. Sharma, M.C. Chattopadhyaya, Y.C. Sharma, Kinetic and equilibrium modeling for the adsorptive removal of methylene blue from aqueous solutions on of activated fly ash (AFSH), J. Environ. Chem. Eng. 2(2014) 1870-1880.

[52] B.A. Shah, A.V. Shah, H.D. Patel, Alkaline hydrothermal conversion of agricultural waste bagasse fly ash into zeolite:Utilisation in dye removal from aqueous solution, Int. J. Environ. Waste Manag. 7(2010) 192-208.

[53] M. Shirani, A. Semnani, H. Haddadi, S. Habibollahi, Optimization of simultaneous removal of methylene blue, crystal violet, and fuchsine from aqueous solutions by magnetic NaY zeolite composite, Water Air Soil Pollut. 225(2014) 2054.

[54] C.A. Nunes, M.C. Guerreiro, Estimation of surface area and pore volume of activated carbons by methylene blue and iodine numbers, Quim Nova 34(2011) 472-476.

[55] S. Wongcharee, V. Aravinthan, L. Erdei, W. Sanongraj, Use of macadamia nut shell residues as magnetic nanosorbents, Int. Biodeterior. Biodegrad. 124(2017) 276-287.