Fluoride Removal from Water Using Adsorption Method with Different Compounds: A Comprehensive Review

Authors

  • Dharmendra Kumar Research Scholar, University Department of Chemistry, B. N. Mandal University Madhepura, INDIA. https://orcid.org/0009-0001-8808-1145
  • Dr. Kameshwar Kumar Associate Professor and Ex-HOD, University Department of Chemistry, B. N. Mandal University Madhepura, INDIA.

DOI:

https://doi.org/10.55544/jrasb.2.5.22

Keywords:

Adsorbent, Environment, Fluoride, Water

Abstract

This comprehensive review paper explores the diverse range of compounds employed in the adsorption process for the removal of fluoride from water. The escalating levels of fluoride contamination in drinking water sources pose a significant health threat to communities worldwide. Adsorption is a widely acknowledged and effective method for mitigating this concern, involving various compounds such as activated carbon, metal oxides, and biomaterials. It focuses on the mechanisms, adsorption isotherms, kinetics, and factors affecting the efficiency of fluoride removal using these compounds. We discuss the advantages and limitations of each compound, considering their applicability in different environmental conditions and scale of operation. Furthermore, we scrutinize the regeneration and cost-effectiveness of these materials. This review consolidates the existing knowledge on fluoride removal via adsorption techniques, offering valuable insights for researchers, policymakers, and practitioners involved in water purification. The main objective of this paper is to present a comprehensive, and up-to-date assessment of the subject matter.

Downloads

Download data is not yet available.

Metrics

Metrics Loading ...

Author Biography

Dr. Kameshwar Kumar, Associate Professor and Ex-HOD, University Department of Chemistry, B. N. Mandal University Madhepura, INDIA.

Associate Professor and Ex-HOD at University Department of Chemistry, B. N. Mandal University Madhepura, India

References

Dwivedi AD, Dubey SP, Gopal K, Tandon VK. A comparative investigation for strengthening the adsorptive phenomenon by activated natural minerals and plant waste-carbon for defluoridation in water milieu. Desalination. 2010 Nov 30;263(1-3):189-99.

Jha SK, Singh RK, Damodaran T, Mishra VK, Sharma DK, Rai D. Fluoride in groundwater: toxicological exposure and remedies. Journal of Toxicology and Environmental Health, Part B. 2013 Jan 1;16(1):52-66.

Lugwisha EH, Lunyungu G. Water defluoridation capacity of Tanzanian kaolin-feldspar blend adsorbents. Am. J. Appl. Chem. 2016;4:77-83.

Ali S, Shekhar S, Bhattacharya P, Verma G, Chandrasekhar T, Chandrashekhar AK. Elevated fluoride in groundwater of Siwani Block, Western Haryana, India: a potential concern for sustainable water supplies for drinking and irrigation. Groundwater for Sustainable Development. 2018 Sep 1;7:410-20.

Review, Mini, and Abdullatef Nureddin. 2018. “Adverse Effects of Fluoride.” 8(5): 8–10.

Chandrajith R, Padmasiri JP, Dissanayake CB, Prematilaka KM. Spatial distribution of fluoride in groundwater of Sri Lanka.

Dharmagunawardhane HA, Malaviarachchi SP, Burgess W. Fluoride content of minerals in gneissic rocks at an area of endemic dental fluorosis in Sri Lanka: estimates from combined petrographic and electron microprobe analysis. Ceylon Journal of Science. 2016 Jun 22;45(1).

Mohammad A, Majumder CB. Removal of fluoride from synthetic waste water by using “bio-adsorbents”. Int. J. Res. Eng. Technol. 2014 Apr 3;3(4):776-85.

WHO G. Guidelines for drinking-water quality. World health organization. 2011 Apr 16;216:303-4.

Emmanuel KA, Veerabhadrarao A, Nagalakshmi TV, Reddy MG, Diwakar PP, Sureshbabu C. Factors influencing the removal of fluoride from aqueous solution by Pithacelobium dulce carbon. Der Pharma Chem. 2015;7:225-36.

Kaseva ME. Contribution of trona (magadi) into excessive fluorosis—a case study in Maji ya Chai ward, northern Tanzania. Science of the Total Environment. 2006 Jul 31;366(1):92-100.

Thole B. Ground water contamination with fluoride and potential fluoride removal technologies for East and Southern Africa. Perspectives in water pollution. 2013 Apr 17:65-95.

Jha SK, Singh RK, Damodaran T, Mishra VK, Sharma DK, Rai D. Fluoride in groundwater: toxicological exposure and remedies. Journal of Toxicology and Environmental Health, Part B. 2013 Jan 1;16(1):52-66.

Sehn P. Fluoride removal with extra low energy reverse osmosis membranes: three years of large scale field experience in Finland. Desalination. 2008 Mar 1;223(1-3):73-84.

Chandrajith R, Padmasiri JP, Dissanayake CB, Prematilaka KM. Spatial distribution of fluoride in groundwater of Sri Lanka.

Jha SK, Singh RK, Damodaran T, Mishra VK, Sharma DK, Rai D. Fluoride in groundwater: toxicological exposure and remedies. Journal of Toxicology and Environmental Health, Part B. 2013 Jan 1;16(1):52-66.

Jacks G. Fluoride in groundwater: mobilization, trends, and remediation. InGroundwater Assessment, Modeling, and Management 2016 Sep 15 (pp. 339-349). CRC Press.

Raju NJ, Dey S, Das K. Fluoride contamination in groundwaters of Sonbhadra district, Uttar Pradesh, India. Current science. 2009 Apr 10:979-85.

Sreedevi PD, Ahmed S, Madé B, Ledoux E, Gandolfi JM. Association of hydrogeological factors in temporal variations of fluoride concentration in a crystalline aquifer in India. Environmental Geology. 2006 May;50:1-1.

Dar MA, Sankar K, Dar IA. Fluorine contamination in groundwater: a major challenge. Environmental monitoring and assessment. 2011 Feb;173:955-68.

Shaji E, Viju J, Thambi DS. High fluoride in groundwater of Palghat District, Kerala. Current Science. 2007 Jan 25:240-5.

Sollo F, Larson TE, Mueller HF. Fluoride Removal from Potable Water Supplies. University of Illinois. Water Resources Center. 1978.

Alain Tressaud (Ed.), Advances in Fluorine Science, Fluorine and the Environment, Agrochemicals, Archaeology, Green Chemistry & Water, vol. 2, Elsevier, 2006

Ghorai S, Pant KK. Equilibrium, kinetics and breakthrough studies for adsorption of fluoride on activated alumina. Separation and purification technology. 2005 Apr 1;42(3):265-71.

Sujana MG, Thakur RS, Rao SB. Removal of fluoride from aqueous solution by using alum sludge. Journal of Colloid and Interface Science. 1998 Oct 1;206(1):94-101.

Huang CJ, Liu JC. Precipitate flotation of fluoride-containing wastewater from a semiconductor manufacturer. Water Research. 1999 Nov 1;33(16):3403-12.

Popat KM, Anand PS, Dasare BD. Selective removal of fluoride ions from water by the aluminium form of the aminomethylphosphonic acid-type ion exchanger. Reactive polymers. 1994 Jul 1;23(1):23-32.

Luo F, Inoue K. The removal of fluoride ion by using metal (III)‐loaded amberlite resins. Solvent extraction and ion exchange. 2004 Dec 31;22(2):305-22.

Solangi IB, Memon S, Bhanger MI. Removal of fluoride from aqueous environment by modified Amberlite resin. Journal of hazardous materials. 2009 Nov 15;171(1-3):815-9.

Meenakshi S, Viswanathan N. Identification of selective ion-exchange resin for fluoride sorption. Journal of colloid and interface science. 2007 Apr 15;308(2):438-50.

Simons R. Trace element removal from ash dam waters by nanofiltration and diffusion dialysis. Desalination. 1993 Jan 1;89(3):325-41.

Sehn P. Fluoride removal with extra low energy reverse osmosis membranes: three years of large scale field experience in Finland. Desalination. 2008 Mar 1;223(1-3):73-84.

Adhikary SK, Tipnis UK, Harkare WP, Govindan KP. Defluoridation during desalination of brackish water by electrodialysis. Desalination. 1989 Jan 1;71(3):301-12.

Mohapatra M, Anand S, Mishra BK, Giles DE, Singh P. Review of fluoride removal from drinking water. Journal of environmental management. 2009 Oct 1;91(1):67-77.

Miretzky P, Cirelli AF. Fluoride removal from water by chitosan derivatives and composites: a review. Journal of Fluorine Chemistry. 2011 Apr 1;132(4):231-40.

Turner BD, Binning P, Stipp SL. Fluoride removal by calcite: evidence for fluorite precipitation and surface adsorption. Environmental science & technology. 2005 Dec 15;39(24):9561-8.

Eskandarpour A, Onyango MS, Ochieng A, Asai S. Removal of fluoride ions from aqueous solution at low pH using schwertmannite. Journal of Hazardous Materials. 2008 Apr 1;152(2):571-9.

Liu Q, Guo H, Shan Y. Adsorption of fluoride on synthetic siderite from aqueous solution. Journal of Fluorine Chemistry. 2010 May 1;131(5):635-41.

Farrah H, Slavek J, Pickering WF. Fluoride interactions with hydrous aluminum oxides and alumina. Soil Research. 1987;25(1):55-69.

Ku, Y., & Chiou, H. (2002). The Adsorption of Fluoride Ion from Aqueous Solution by Activated Alumina. Water, Air, & Soil Pollution, 133(1/4), 349–361. https://doi.org/10.1023/a:1012929900113

Bhargava DS, Killedar DJ. Fluoride adsorption on fishbone charcoal through a moving media adsorber. Water Research. 1992 Jun 1;26(6):781-8.

Kaseva ME. Optimization of regenerated bone char for fluoride removal in drinking water: a case study in Tanzania. Journal of water and health. 2006 Mar;4(1):139-47.

Janardhana C, Rao GN, Sathish RS, Kumar PS, Kumar VA, Madhav MV. Study on defluoridation of drinking water using zirconium ion impregnated activated charcoals.

Chaturvedi AK, Yadava KP, Pathak KC, Singh VN. Defluoridation of water by adsorption on fly ash. Water, Air, and Soil Pollution. 1990 Jan;49:51-61.

Nigussie W, Zewge F, Chandravanshi BS. Removal of excess fluoride from water using waste residue from alum manufacturing process. Journal of Hazardous Materials. 2007 Aug 25;147(3):954-63.

Lv L, He J, Wei M, Duan X. Kinetic studies on fluoride removal by calcined layered double hydroxides. Industrial & engineering chemistry research. 2006 Dec 6;45(25):8623-8.

Hammari LE, Laghzizil A, Barboux P, Lahlil K, Saoiabi A. Retention of fluoride ions from aqueous solution using porous hydroxyapatite: Structure and conduction properties. Journal of hazardous materials. 2004 Oct 18;114(1-3):41-4.

S.A. Wasay, M.J. Haron, S. Tokunaga, Adsorption of fluoride, phosphate, and arsenate ions on lanthanum-impregnated silica gel, Water Environ. Res. 68 (1996) 295–300.

Srimurali M, Pragathi A, Karthikeyan J. A study on removal of fluorides from drinking water by adsorption onto low-cost materials. Environmental pollution. 1998 Jan 1;99(2):285-9.

Nemade PD, Vasudeva Rao A, Alappat BJ. Removal of fluorides from water using low cost adsorbents. Water Science and Technology: Water Supply. 2002 Jan;2(1):311-7.

Sarkar M, Banerjee A, Pramanick PP, Sarkar AR. Use of laterite for the removal of fluoride from contaminated drinking water. Journal of Colloid and Interface Science. 2006 Oct 15;302(2):432-41.

Xiuru Y, Kuanxiu S, Jianping W, Liuchang H, Zhaohui Y. Preparation of CeO2-TiO2/SiO2 and its removal properties for fluoride ion. J. Rare Earths. 1998;16(4):279-80.

Zhu P, Wang H, Sun B, Deng P, Hou S, Yu Y. Adsorption of fluoride from aqueous solution by magnesia‐amended silicon dioxide granules. Journal of Chemical Technology & Biotechnology. 2009 Oct;84(10):1449-55.

Gupta AK, Deva D, Sharma A, Verma N. Adsorptive removal of fluoride by micro-nanohierarchal web of activated carbon fibers. Industrial & engineering chemistry research. 2009 Nov 4;48(21):9697-707.

Sivasamy A, Singh KP, Mohan D, Maruthamuthu M. Studies on defluoridation of water by coal‐based sorbents. Journal of Chemical Technology & Biotechnology. 2001 Jul;76(7):717-22.

Sarkar M, Banerjee A, Pramanick PP, Sarkar AR. Use of laterite for the removal of fluoride from contaminated drinking water. Journal of Colloid and Interface Science. 2006 Oct 15;302(2):432-41.

Mukherjee S, Sahu P, Halder G. Microbial remediation of fluoride-contaminated water via a novel bacterium Providencia vermicola (KX926492). Journal of environmental management. 2017 Dec 15;204:413-23.

Kumar V, Talreja N, Deva D, Sankararamakrishnan N, Sharma A, Verma N. Development of bi-metal doped micro-and nano multi-functional polymeric adsorbents for the removal of fluoride and arsenic (V) from wastewater. Desalination. 2011 Nov 1;282:27-38.

Pollard AJ, Reeves RD, Baker AJ. Facultative hyperaccumulation of heavy metals and metalloids. Plant Science. 2014 Mar 1;217:8-17.

Abdallah FB, Elloumi N, Mezghani I, Garrec JP, Boukhris M. Industrial fluoride pollution of Jerbi grape leaves and the distribution of F, Ca, Mg, and P in them. Fluoride. 2006;39(1):43-8.

Thijs S, Sillen W, Rineau F, Weyens N, Vangronsveld J. Towards an enhanced understanding of plant–microbiome interactions to improve phytoremediation: engineering the metaorganism. Frontiers in Microbiology. 2016 Mar 16;7:341.

Baunthiyal M, Ranghar S. Accumulation of fluoride by plants: potential for phytoremediation. Clean–Soil, Air, Water. 2015 Jan;43(1):127-32.

Petzold CJ, Chan LJ, Nhan M, Adams PD. Analytics for Metabolic Engineering. Front. Bioeng. Biotechnol. 3, 135.

Baker AJ, McGrath SP, Reeves RD, Smith JA, Terry N, Bañuelos G. A review of the ecology and physiology of a biological resource for phytoremediation of metal-polluted soils. Phytoremediation of Contaminated Soil and Water. Metal Hyperaccumulator Plants. 2000:85-107.

Pollard AJ, Reeves RD, Baker AJ. Facultative hyperaccumulation of heavy metals and metalloids. Plant Science. 2014 Mar 1;217:8-17.

Lorestani B, Cheraghi M, Yousefi N. Phytoremediation potential of native plants growing on a heavy metals contaminated soil of copper mine in Iran. International Journal of Geological and Environmental Engineering. 2011 May 24;5(5):299-304.

Saini P, Khan S, Baunthiyal M, Sharma V. Organ-wise accumulation of fluoride in Prosopis juliflora and its potential for phytoremediation of fluoride contaminated soil. Chemosphere. 2012 Oct 1;89(5):633-5.

Downloads

Published

2023-11-17

How to Cite

Kumar, D., & Kumar, K. (2023). Fluoride Removal from Water Using Adsorption Method with Different Compounds: A Comprehensive Review. Journal for Research in Applied Sciences and Biotechnology, 2(5), 132–138. https://doi.org/10.55544/jrasb.2.5.22