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Mechanisms of Trace Metal Elements Removal from Water using Low-Cost Biochar Adsorbents: A mini review | ||
Pollution | ||
دوره 10، شماره 1، فروردین 2024، صفحه 495-510 اصل مقاله (729.55 K) | ||
نوع مقاله: Review Paper | ||
شناسه دیجیتال (DOI): 10.22059/poll.2023.365187.2068 | ||
نویسندگان | ||
Arun Lal Srivastav* 1؛ Lata Rani2؛ Prakriti Sharda1؛ Ajay Sharma1 | ||
1Chitkara University School of Engineering and Technology, Chitkara University, Solan, Himachal Pradesh, India | ||
2Chitkara School of Pharmacy, Chitkara University, Solan, Himachal Pradesh 174103, India | ||
چکیده | ||
Trace metal elements are toxic to the environment and human health and can be removed from water through adsorption. Development of low-cost adsorbents would always been a matter of achievement of every adsorption study as usually many adsorbents were found to be expensive in nature. In this regard, biochar adsorbents gained significant attention due to high adsorption capacity, low-cost and environmental sustainability. Pyrolysis is used to produce biochar adsorbents at varying temperature ranged from 300°C-700°C. The adsorption capacities of palm fiber biochar adsorbents are remarkable which was found around ~198 mg/g for cadmium removal. However, bamboo-based biochar had 868 mg/g of adsorption capacity for arsenate removal. This review aims to provide the current discusses the sources and impacts of trace metal elements in water along with properties of biochar including its composition, surface area, pore structure, and surface functional groups. Further, various types of biomasses have also been mentioned for producing biochar such as agricultural wastes, food wastes, forestry residues, etc. The paper also discusses the different types of mechanisms involved in the adsorption of heavy metal biochar adsorbents like electrostatic attraction, ion exchange, surface complexation etc. | ||
کلیدواژهها | ||
Adsorption؛ Low-cost biochar؛ Trace metal element removal؛ Pyrolysis؛ Water purification | ||
مراجع | ||
Adeniyi, A. G., Iwuozor, K. O., Emenike, E. C., Ajala, O. J., Ogunniyi, S., & Muritala, K. B. (2023). Thermochemical co-conversion of biomass-plastic waste to biochar: A review. Green Chemical Engineering. Ahmad, Z., Gao, B., Mosa, A., Yu, H., Yin, X., Bashir, A., ... & Wang, S. (2018). Removal of Cu (II), Cd (II) and Pb (II) ions from aqueous solutions by biochars derived from potassium-rich biomass. Journal of cleaner production, 180, 437-449. Alam, M. S., Swaren, L., von Gunten, K., Cossio, M., Bishop, B., Robbins, L. J., ... & Alessi, D. S. (2018). Application of surface complexation modeling to trace metals uptake by biochar-amended agricultural soils. Applied Geochemistry, 88, 103-112. Alchouron, J., Navarathna, C., Chludil, H. D., Dewage, N. B., Perez, F., Pittman Jr, C. U., & Mlsna, T. E. (2020). Assessing South American Guadua chacoensis bamboo biochar and Fe3O4 nanoparticle dispersed analogues for aqueous arsenic (V) remediation. Science of The Total Environment, 706, 135943. Ali, H., Khan, E., & Ilahi, I. (2019). Environmental chemistry and ecotoxicology of hazardous heavy metals: environmental persistence, toxicity, and bioaccumulation. Journal of chemistry, 2019. Alizadeh, B., Delnavaz, M., & Shakeri, A. (2018). Removal of Cd (ӀӀ) and phenol using novel cross-linked magnetic EDTA/chitosan/TiO2 nanocomposite. Carbohydrate polymers, 181, 675-683. Bogusz, A., Oleszczuk, P., & Dobrowolski, R. (2015). Application of laboratory prepared and commercially available biochars to adsorption of cadmium, copper and zinc ions from water. Bioresource technology, 196, 540-549. Cai, C., Zhao, M., Yu, Z., Rong, H., & Zhang, C. (2019). Utilization of nanomaterials for in-situ remediation of heavy metal (loid) contaminated sediments: A review. Science of the Total Environment, 662, 205-217. Cao, X., & Harris, W. (2010). Properties of dairy-manure-derived biochar pertinent to its potential use in remediation. Bioresource technology, 101(14), 5222-5228. Cao, X., Ma, L., Gao, B., & Harris, W. (2009). Dairy-manure derived biochar effectively sorbs lead and atrazine. Environmental science & technology, 43(9), 3285-3291. Chen, B., Chen, Z., & Lv, S. (2011). A novel magnetic biochar efficiently sorbs organic pollutants and phosphate. Bioresource technology, 102(2), 716-723. Chen, W. H., Hoang, A. T., Nižetić, S., Pandey, A., Cheng, C. K., Luque, R., ... & Nguyen, X. P. (2022). Biomass-derived biochar: From production to application in removing heavy metal-contaminated water. Process Safety and Environmental Protection, 160, 704-733. Choy, K. K., & McKay, G. (2005). Sorption of cadmium, copper, and zinc ions onto bone char using Crank diffusion model. Chemosphere, 60(8), 1141-1150. Crabtree, R. H. (2009). The organometallic chemistry of the transition metals. John Wiley & Sons. Demir Delil, A., Gülçiçek, O., & Gören, N. (2019). Optimization of adsorption for the removal of cadmium from aqueous solution using Turkish coffee grounds. International Journal of Environmental Research, 13(5), 861-878. Demirbas, A. (2008). Heavy metal adsorption onto agro-based waste materials: a review. Journal of hazardous materials, 157(2-3), 220-229. Dhiman, V.K., Singh, J., Kanoungo, A., Goyal, A., & Singh, Y. (2022). Reuse of grey water generated from high rise educational building. Materials Today: Proceedings, 69, 372-377. Dinari, M., & Tabatabaeian, R. (2018). Ultra-fast and highly efficient removal of cadmium ions by magnetic layered double hydroxide/guargum bionanocomposites. Carbohydrate polymers, 192, 317-326. Dong, X., Ma, L. Q., Zhu, Y., Li, Y., & Gu, B. (2013). Mechanistic investigation of mercury sorption by Brazilian pepper biochars of different pyrolytic temperatures based on X-ray photoelectron spectroscopy and flow calorimetry. Environmental science & technology, 47(21), 12156-12164. Du, Q., Zhang, S., Song, J., Zhao, Y., & Yang, F. (2020). Activation of porous magnetized biochar by artificial humic acid for effective removal of lead ions. Journal of hazardous materials, 389, 122115. Feng, Y., Liu, P., Wang, Y., Liu, W., Liu, Y., & Finfrock, Y. Z. (2020). Mechanistic investigation of mercury removal by unmodified and Fe-modified biochars based on synchrotron-based methods. Science of the Total Environment, 719, 137435. Gabhane, J.W., Bhange, V.P., Patil, P.D., Bankar, S.T., & Kumar, S. (2020). Recent trends in biochar production methods and its application as a soil health conditioner: a review. SN Applied Sciences, 2, 1-21. Ghysels, S., Ronsse, F., Dickinson, D., & Prins, W. (2019). Production and characterization of slow pyrolysis biochar from lignin-rich digested stillage from lignocellulosic ethanol production. Biomass and bioenergy, 122, 349-360. Giraldo, S., Robles, I., Ramirez, A., Flórez, E., & Acelas, N. (2020). Mercury removal from wastewater using agroindustrial waste adsorbents. SN Applied Sciences, 2(6), 1-17. Godwin, P. M., Pan, Y., Xiao, H., & Afzal, M. T. (2019). Progress in preparation and application of modified biochar for improving heavy metal ion removal from wastewater. Journal of Bioresources and Bioproducts, 4(1), 31-42. Gupta S., Sireesha, S., Sreedhar, I., Patel, C.M., & Anitha, K.L. (2020). Latest trends in heavy metal removal from wastewater by biochar-based sorbents. Journal of Water Process Engineering, 38, 101561. Harvey, O. R., Herbert, B. E., Rhue, R. D., & Kuo, L. J. (2011). Metal interactions at the biochar-water interface: energetics and structure-sorption relationships elucidated by flow adsorption microcalorimetry. Environmental science & technology, 45(13), 5550-5556. Hassan, M., Naidu, R., Du, J., Liu, Y., & Qi, F. (2020). Critical review of magnetic biosorbents: Their preparation, application, and regeneration for wastewater treatment. Science of the Total Environment, 702, 134893. Hussain, N., Chantrapromma, S., Suwunwong, T., & Phoungthong, K. (2020). Cadmium (II) removal from aqueous solution using magnetic spent coffee ground biochar: Kinetics, isotherm and thermodynamic adsorption. Materials Research Express, 7(8), 085503. Imran, M., Khan, Z. U. H., Iqbal, J., Shah, N. S., Muzammil, S., Ali, S., ... & Rizwan, M. (2020). Potential of siltstone and its composites with biochar and magnetite nanoparticles for the removal of cadmium from contaminated aqueous solutions: batch and column scale studies. Environmental Pollution, 259, 113938. Jaishankar, M., Tseten, T., Anbalagan, N., Mathew, B. B., & Beeregowda, K. N. (2014). Toxicity, mechanism and health effects of some trace metal elements. Interdisciplinary toxicology, 7(2), 60. Jeon, C., Solis, K. L., An, H. R., Hong, Y., Igalavithana, A. D., & Ok, Y. S. (2020). Sustainable removal of Hg(II) by sulfur-modified pine-needle biochar. Journal of hazardous materials, 388, 122048. Jin, Q., Wang, Z., Feng, Y., Kim, Y. T., Stewart, A. C., O’Keefe, S. F., ... & Huang, H. (2020). Grape pomace and its secondary waste management: biochar production for a broad range of lead (Pb) removal from water. Environmental research, 186, 109442. Kahlon, S. K., Sharma, G., Julka, J. M., Kumar, A., Sharma, S., & Stadler, F. J. (2018). Impact of trace metal elements and nanoparticles on aquatic biota. Environmental chemistry letters, 16(3), 919-946. Keiluweit, M., & Kleber, M. (2009). Molecular-level interactions in soils and sediments: the role of aromatic π-systems. Environmental science & technology, 43(10), 3421-3429. Kołodyńska, D., & Bąk, J. (2018). Use of three types of magnetic biochar in the removal of copper (II) ions from wastewaters. Separation Science and Technology, 53(7), 1045-1057. Kumar, S., Loganathan, V. A., Gupta, R. B., & Barnett, M. O. (2011). An assessment of U (VI) removal from groundwater using biochar produced from hydrothermal carbonization. Journal of environmental management, 92(10), 2504-2512. Laird, D., Fleming, P., Wang, B., Horton, R., & Karlen, D. (2010). Biochar impact on nutrient leaching from a Midwestern agricultural soil. Geoderma, 158(3-4), 436-442. Lata, S., Singh, P. K., & Samadder, S. R. (2015). Regeneration of adsorbents and recovery of trace metal elements: a review. International journal of environmental science and technology, 12(4), 1461-1478. Li, J., Pan, Y., Xiang, C., Ge, Q., & Guo, J. (2006). Low temperature synthesis of ultrafine α-Al2O3 powder by a simple aqueous sol–gel process. Ceramics International, 32(5), 587-591. Li, R., Liang, W., Huang, H., Jiang, S., Guo, D., Li, M., ... & Wang, J. J. (2018). Removal of cadmium (II) cations from an aqueous solution with aminothiourea chitosan strengthened magnetic biochar. Journal of Applied Polymer Science, 135(19), 46239. Li, Z., Xing, B., Ding, Y., Li, Y., & Wang, S. (2020). A high-performance biochar produced from bamboo pyrolysis with in-situ nitrogen doping and activation for adsorption of phenol and methylene blue. Chinese Journal of Chemical Engineering, 28(11), 2872-2880. Liu, M., Almatrafi, E., Zhang, Y., Xu, P., Song, B., Zhou, C., ... & Zhu, Y. (2022). A critical review of biochar-based materials for the remediation of heavy metal contaminated environment: Applications and practical evaluations. Science of The Total Environment, 806, 150531. Liu, Z., Zhang, F. S., & Wu, J. (2010). Characterization and application of chars produced from pinewood pyrolysis and hydrothermal treatment. Fuel, 89(2), 510-514. Lu, H., Zhang, W., Yang, Y., Huang, X., Wang, S., & Qiu, R. (2012). Relative distribution of Pb2+ sorption mechanisms by sludge-derived biochar. Water research, 46(3), 854-862. Ma, Y., Liu, W. J., Zhang, N., Li, Y. S., Jiang, H., & Sheng, G. P. (2014). Polyethylenimine modified biochar adsorbent for hexavalent chromium removal from the aqueous solution. Bioresource technology, 169, 403-408. Mohan, D., Pittman Jr, C. U., Bricka, M., Smith, F., Yancey, B., Mohammad, J., ... & Gong, H. (2007). Sorption of arsenic, cadmium, and lead by chars produced from fast pyrolysis of wood and bark during bio-oil production. Journal of colloid and interface science, 310(1), 57-73. Moreira, M. T., Noya, I., & Feijoo, G. (2017). The prospective use of biochar as adsorption matrix–A review from a lifecycle perspective. Bioresource technology, 246, 135-141. Mukherjee, A., Zimmerman, A. R., & Harris, W. (2011). Surface chemistry variations among a series of laboratory-produced biochars. Geoderma, 163(3-4), 247-255. Mukherjee, S., Thakur, A. K., Goswami, R., Mazumder, P., Taki, K., Vithanage, M., & Kumar, M. (2021). Efficacy of agricultural waste derived biochar for arsenic removal: Tackling water quality in the Indo-Gangetic plain. Journal of Environmental Management, 281, 111814. https://doi.org/10.1016/j.jenvman.2020.111814 Nadeem, M., Mahmood, A., Shahid, S.A., Shah, S.S., Khalid, A.M. and McKay, G., 2006. Sorption of lead from aqueous solution by chemically modified carbon adsorbents. Journal of Hazardous materials, 138(3), 604-613. Navarathna, C. M., Karunanayake, A. G., Gunatilake, S. R., Pittman Jr, C. U., Perez, F., Mohan, D., & Mlsna, T. (2019). Removal of Arsenic (III) from water using magnetite precipitated onto Douglas fir biochar. Journal of environmental management, 250, 109429. Nisticò, R., Cesano, F., Franzoso, F., Magnacca, G., Scarano, D., Funes, I. G., ... & Parolo, M. E. (2018). From biowaste to magnet-responsive materials for water remediation from polycyclic aromatic hydrocarbons. Chemosphere, 202, 686-693. Panwar, N. L., Pawar, A., & Salvi, B. L. (2019). Comprehensive review on production and utilization of biochar. SN Applied Sciences, 1(2), 1-19. Park, J. H., Ok, Y. S., Kim, S. H., Cho, J. S., Heo, J. S., Delaune, R. D., & Seo, D. C. (2016). Competitive adsorption of trace metal elements onto sesame straw biochar in aqueous solutions. Chemosphere, 142, 77-83. Priharto, N., Ronsse, F., Yildiz, G., Heeres, H.J., Deuss, P.J., & Prins, W. (2020). Fast pyrolysis with fractional condensation of lignin-rich digested stillage from second-generation bioethanol production. Journal of Analytical and Applied Pyrolysis, 145, 104756. Qambrani, N. A., Rahman, M. M., Won, S., Shim, S., & Ra, C. (2017). Biochar properties and eco-friendly applications for climate change mitigation, waste management, and wastewater treatment: A review. Renewable and Sustainable Energy Reviews, 79, 255-273. Qian, L., Zhang, W., Yan, J., Han, L., Gao, W., Liu, R., & Chen, M. (2016). Effective removal of heavy metal by biochar colloids under different pyrolysis temperatures. Bioresource technology, 206, 217-224. Qiao, K., Tian, W., Bai, J., Zhao, J., Du, Z., Song, T., ... & Xie, W. (2020). Synthesis of floatable magnetic iron/biochar beads for the removal of chromium from aqueous solutions. Environmental Technology & Innovation, 19, 100907. Qiu Y, Cheng H, Xu C, Sheng GD. 2008. Surface characteristics of crop-residue-derived black carbon and lead (II) adsorption. Water Research, 42(3), 567–574 Rajapaksha, A. U., Chen, S. S., Tsang, D. C., Zhang, M., Vithanage, M., Mandal, S., ... & Ok, Y. S. (2016). Engineered/designer biochar for contaminant removal/immobilization from soil and water: potential and implication of biochar modification. Chemosphere, 148, 276-291. Reddy, D. H. K., & Lee, S. M. (2014). Magnetic biochar composite: facile synthesis, characterization, and application for heavy metal removal. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 454, 96-103. Reguyal, F., Sarmah, A. K., & Gao, W. (2017). Synthesis of magnetic biochar from pine sawdust via oxidative hydrolysis of FeCl2 for the removal sulfamethoxazole from aqueous solution. Journal of Hazardous Materials, 321, 868-878. Shetty, A. and Goyal, A. (2022). Application of nanofiltration systems in wastewater reclamation & its long-term performance. In AIP Conference Proceedings (Vol. 2357(1), 030015). AIP Publishing LLC. Shi, J., Fan, X., Tsang, D. C., Wang, F., Shen, Z., Hou, D., & Alessi, D. S. (2019). Removal of lead by rice husk biochars produced at different temperatures and implications for their environmental utilizations. Chemosphere, 235, 825-831. Tan, X. F., Liu, S. B., Liu, Y. G., Gu, Y. L., Zeng, G. M., Hu, X. J., ... & Jiang, L. H. (2017). Biochar as potential sustainable precursors for activated carbon production: multiple applications in environmental protection and energy storage. Bioresource technology, 227, 359-372. Tan, X. F., Liu, Y. G., Gu, Y. L., Xu, Y., Zeng, G. M., Hu, X. J., ... & Li, J. (2016). Biochar-based nano-composites for the decontamination of wastewater: a review. Bioresource technology, 212, 318-333. Tan, X., Liu, Y., Zeng, G., Wang, X., Hu, X., Gu, Y., & Yang, Z. (2015). Application of biochar for the removal of pollutants from aqueous solutions. Chemosphere, 125, 70-85. Tang, X. Y., Huang, W. D., Guo, J. J., Yang, Y., Tao, R., & Feng, X. (2017). Use of Fe-impregnated biochar to efficiently sorb chlorpyrifos, reduce uptake by Allium fistulosum L., and enhance microbial community diversity. Journal of agricultural and food chemistry, 65(26), 5238-5243. Thines, K. R., Abdullah, E. C., Mubarak, N. M., & Ruthiraan, M. (2017). Synthesis of magnetic biochar from agricultural waste biomass to enhancing route for waste water and polymer application: a review. Renewable and Sustainable Energy Reviews, 67, 257-276. Trakal, L., Bingöl, D., Pohořelý, M., Hruška, M., & Komárek, M. (2014). Geochemical and spectroscopic investigations of Cd and Pb sorption mechanisms on contrasting biochars: engineering implications. Bioresource technology, 171, 442-451. Wiedner, K., Naisse, C., Rumpel, C., Pozzi, A., Wieczorek, P., & Glaser, B. (2013). Chemical modification of biomass residues during hydrothermal carbonization–What makes the difference, temperature or feedstock?. Organic Geochemistry, 54, 91-100. Williams, F. S., & Misra, C. (2011). Pressure calcination revisited. In Light Metals 2011 (pp. 131-136). Springer, Cham. Wu, C., Huang, L., Xue, S. G., Huang, Y. Y., Hartley, W., Cui, M. Q., & Wong, M. H. (2017). Arsenic sorption by red mud-modified biochar produced from rice straw. Environmental Science and Pollution Research, 24(22), 18168-18178. Xiao, F., Bedane, A. H., Mallula, S., Sasi, P. C., Alinezhad, A., Soli, D., ... & Mann, M. D. (2020). Production of granular activated carbon by thermal air oxidation of biomass charcoal/biochar for water treatment in rural communities: a mechanistic investigation. Chemical Engineering Journal Advances, 4, 100035. Yaashikaa, P.R., Kumar, P.S., Varjani, S., & Saravanan, A. (2020). A critical review on the biochar production techniques, characterization, stability and applications for circular bioeconomy. Biotechnology Reports, 28, e00570. Yang, X., Wan, Y., Zheng, Y., He, F., Yu, Z., Huang, J., ... & Gao, B. (2019). Surface functional groups of carbon-based adsorbents and their roles in the removal of heavy metals from aqueous solutions: a critical review. Chemical Engineering Journal, 366, 608-621. Yi, Y., Tu, G., Zhao, D., Tsang, P. E., & Fang, Z. (2020). Key role of FeO in the reduction of Cr (VI) by magnetic biochar synthesised using steel pickling waste liquor and sugarcane bagasse. Journal of Cleaner Production, 245, 118886. Yin, X., Long, J., Xi, Y., & Luo, X. (2017). Recovery of silver from wastewater using a new magnetic photocatalytic ion-imprinted polymer. ACS Sustainable Chemistry & Engineering, 5(3), 2090-2097. Zhang, L., Guo, J., Huang, X., Wang, W., Sun, P., Li, Y., & Han, J. (2019). Functionalized biochar-supported magnetic MnFe 2O4 nanocomposite for the removal of Pb (II) and Cd (II). RSC advances, 9(1), 365-376. Zhao, L., Zheng, W., Mašek, O., Chen, X., Gu, B., Sharma, B. K., & Cao, X. (2017). Roles of phosphoric acid in biochar formation: synchronously improving carbon retention and sorption capacity. Journal of environmental quality, 46(2), 393-401. Zhu, Y., Dai, W., Deng, K., Pan, T. & Guan, Z., 2020. Efficient removal of Cr (VI) from aqueous solution by Fe-Mn oxide-modified biochar. Water, Air, & Soil Pollution, 231(2), 1-17. | ||
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