Review
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New Generation Nanoadsorbents and Conventional Techniques for Arsenic Removal from Waters

Year 2024, Volume: 11 Issue: 2, 845 - 868, 15.05.2024
https://doi.org/10.18596/jotcsa.1438869

Abstract

Nowadays, with excessive use due to rapid population growth, growing industry, and technological developments, environmental pollution is also increasing and is reaching a point where it threatens the health of humans. The alarming increase in environmental pollution is mostly seen in the form of water pollution. Water pollution has reached levels that threaten human health. There are difficulties in accessing clean water in many parts of the world as a result of restricting the use of natural water resources polluted by both human activities and natural causes. Therefore, intense efforts are made to remove especially heavy metals and other harmful substances that pollute water. Among these toxic heavy metals threatening the health of humans, arsenic is at the top of the list as the most dangerous one. In recent years, many methods and techniques have been developed in addition to classical methods for removing pollutants from water. In this study, conventional methods used in the treatment of arsenic-contaminated waters, the difficulties encountered in the removal process, and the advantages and disadvantages of the methods were critically reviewed in the light of current and past information. In addition, detailed comparative information is given about nano-sized adsorbents, which is an innovative approach used in the adsorption method, one of the arsenic removal methods.

References

  • 1. Smedley PL, Kinniburgh DG. A Review of the Source, Behavior and Distribution of Arsenic in Natural Waters. Applied Geochemistry. 2002; 17(5): 517–568. Available from: <DOI>
  • 2. Mohan D, Pittman CU. Arsenic removal from water/wastewater using adsorbents A critical review, Journal of Hazardous Materials. 2007; 142(1-2):1-53. Available from: <DOI> .
  • 3. Mandal BK, Suzuki KT. Arsenic round the world: a review. Talanta. 2002; 58(1): 201-235. Available from: <DOI>.
  • 4. Sharma VK, Sohn M. Aquatic arsenic: toxicity, speciation, transformations, and remediation. Environment international. 2009; 35(4): 743-759
  • 5. Weerasundara L, Ok YS, Bundschuh J. Selective removal of arsenic in water: A critical review, Environmental Pollution. 2021; 268: 115668 Available from: <DOI>
  • 6. Teixeira MC, Ciminelli VST, Dantas MSS, Diniz SF, Duarte HA Raman Spectroscopy and DFT Calculations of As(III) Complexation with a Cysteine-Rich Biomaterial. Journal of Colloid and Interface Science. 2007; 315(1): 128-134 Available from: <DOI>
  • 7. Patel K S, Pandey P K, Martín-Ramos P, Corns WT, Varol S, Bhattacharya P, Zhu Y. A review on arsenic in the environment: contamination, mobility, sources, and exposure. RSC Advances, 2023; 13(13): 8803-8821.
  • 8. Shen S, Li XF, Cullen WR, Weinfeld M, Le XC. Arsenic binding to proteins. Chemical Reviews 2013; 113(10): 7769-7792. Available from: <DOI>
  • 9. Mudhoo A, Sharma S K, Garg V K, Tseng CH. Arsenic: an overview of applications, health, and environmental concerns and removal processes. Critical Reviews in Environmental Science and Technology, 2011; 41(5): 435-519. Available from: <DOI>.
  • 10. Choong TS, Chuah TG, Robiah Y, Koay FG, Azni I. Arsenic toxicity, health hazards and removal techniques from water: an overview. Desalination. 2007; 217(1-3): 139-166. Available from: <DOI>.
  • 11. Altowayti WAH, Othman N, Shahir S, Alshalif AF, Al-Gheethi AA, Al-Towayti FAH, Haris SA. Removal of arsenic from wastewater by using different technologies and adsorbents: A review. International Journal of Environmental Science and Technology.2021;19:9243–9266. Available from:<DOI>
  • 12. Dilpazeer F, Munir M, Baloch MYJ, Shafiq I, Iqbal J, Saeed M, Mahboob I. A Comprehensive Review of the Latest Advancements in Controlling Arsenic Contaminants in Groundwater. Water. 2023; 15(3): 478. Available from: <DOI>
  • 13. Rathi BS, Kumar PS. A review on sources, identification and treatment strategies for the removal of toxic Arsenic from water system. Journal of Hazardous Materials 2021; 418: 126299. Available from: <DOI>
  • 14. Singh R, Singh S, Parihar P, Singh VP, Prasad SM. Arsenic contamination, consequences and remediation techniques: a review. Ecotoxicology and environmental safety. 2015; 112: 247-270. Available from: <DOI>
  • 15. Mahamallik P, Swain R. A mini-review on arsenic remediation techniques from water and future trends. Water Science and Technology. 2023; 87(12): 3108-3123. Available from: <DOI>
  • 16. Alka S, Shahir S, Ibrahim N, Ndejiko MJ, Vo DVN, Abd Manan F. Arsenic removal technologies and future trends: A mini review. Journal of Cleaner Production. 2021; 278, 123805. Available from: <DOI>
  • 17. Rahidul Hassan, H. A review on different arsenic removal techniques used for decontamination of drinking water. Environmental Pollutants and Bioavailability, 2023; 35(1): 2165964. Available from: <DOI>
  • 18. Nicomel NR, Leus K, Folens K, Van Der Voort P, Du Laing G. Technologies for arsenic removal from water: current status and future perspectives. International journal of environmental research and public health. 2016; 13(1): 62. Available from: <DOI>.
  • 19. Ahmed MF. An overview of arsenic removal technologies in Bangladesh and India. In Proceedings of BUET-UNU international workshop on technologies for arsenic removal from drinking water, Dhaka. 2001; 5-7.
  • 20. Selatile MK, Ray SS, Ojijo V, Sadiku R. Recent developments in polymeric electrospun nanofibrous membranes for seawater desalination. RSC Advances, 2018; 8(66): 37915-37938. Available from: <DOI>
  • 21. Kirisenage PM, Zulqarnain SM, Myers JL, Fahlman BD, Mueller A, Marquez I. Development of Adsorptive Membranes for Selective Removal of Contaminants in Water. Polymers, 2022; 14(15): 3146. Available from: <DOI>
  • 22. Moreira VR, Lebron YAR, Santos LVS, de Paula EC, Amaral MCS. Arsenic contamination, effects and remediation techniques: A special look onto membrane separation processes. Process Safety and Environmental Protection. 2021; 148, 604-623. Available from: <DOI>
  • 23. Chen M, Shafer-Peltier K, Randtke S J, Peltier E. Modeling arsenic (V) removal from water by micellar enhanced ultrafiltration in the presence of competing anions. Chemosphere. 2018; 213: 285-294. Available from: <DOI>
  • 24. Chia RJJ, Lau WJ, Yusof N, Shokravi H, Ismail AF. Adsorptive Membranes for Arsenic Removal–Principles, Progress and Challenges. Separation & Purification Reviews, 2023; 52(4): 379-399.<DOI>
  • 25. Awual MR, Hossain MA, Shenashen M. Evaluating of arsenic(V) removal from water by weak-base anion exchange adsorbents. Environmental science and pollution research international. 2013; 20:421-430. Available from: <DOI>
  • 26. Wang Y, Tsang DC. Effects of solution chemistry on arsenic (V) removal by low-cost adsorbents. Journal of Environmental Sciences. 2013; 25(11): 2291-2298. Available from: <DOI>.
  • 27. Crini G, Lichtfouse E, Wilson LD, Morin-Crini N. Conventional and non-conventional adsorbents for wastewater treatment. Environmental Chemistry Letters, 2019; 17, 195-213. Available from: <DOI>
  • 28. Liu B, Kim KH, Kumar V, Kim S. A review of functional sorbents for adsorptive removal of arsenic ions in aqueous systems. Journal of hazardous materials, 2020; 388, 121815. Available from: <DOI>
  • 29. Kyzas GZ, Matis KA. Nanoadsorbents for pollutants removal: a review. Journal of Molecular Liquids. 2015; 203, 159-168. Available from: <DOI>
  • 30. Ali I. New generation adsorbents for water treatment. Chemical Reviews, 2012; 112(10): 5073-5091. Available from: <DOI>
  • 31. Habuda-Stanić M, Nujić M. Arsenic removal by nanoparticles: a review. Environ Sci Pollut Res. 2015; 22: 8094–8123. Available from: <DOI>
  • 32. Lata S, Samadder SR. Removal of arsenic from water using nano adsorbents and challenges: A review, Journal of Environmental Management. 2016;166: 387-406. Available from: <DOI>.
  • 33. Mohmood I, Lopes CB, Lopes I, Ahmad I, Duarte AC, Pereira E. Nanoscale materials and their use in water contaminants removal—a review. Environmental science and pollution Research. 2013; 20: 1239-1260. Available from: <DOI>
  • 34. Khan NA, Khan SU, Ahmed S, Farooqi IH, Dhingra A, Hussain A, Changani F. Applications of nanotechnology in water and wastewater treatment: A review. Asian Journal of Water, Environment and Pollution. 2019; 16(4): 81-86. Available from: <DOI>
  • 35. Saha S, Sarkar P. Arsenic remediation from drinking water by synthesized nano-alumina dispersed in chitosan-grafted polyacrylamide. Journal of hazardous materials. 2012; 227-228: 68-78. Available from: <DOI>
  • 36. Yürüm A, Kocabaş Ataklı ZÖ, Sezen M, Semiat R, Yürüm Y. Fast deposition of porous iron oxide on activated carbon by microwave heating and arsenic (V) removal from water.Chemical Engineering Journal.2014; 242: 321-332. Available from: <DOI>.
  • 37. Pizarro C, Rubio MA, Escudey M, Albornoz MF, Muñoz D, Denardin J, Fabris JD. Nanomagnetite-zeolite composites in the removal of arsenate from aqueous systems. Journal of the Brazilian Chemical Society.2015; 26: 1887-1896. Available from: <DOI>
  • 38. Savina IN, English CJ, Whitby RL, Zheng Y, Leistner A, Mikhalovsky SV, Cundy AB. . High efficiency removal of dissolved As (III) using iron nanoparticle-embedded macroporous polymer composites. Journal of hazardous materials. 2011; 192(3): 1002-1008. Available from: <DOI>
  • 39. Önnby L, Svensson C, Mbundi L, Busquets R, Cundy A, Kirsebom H. . γ-Al2O3-based nanocomposite adsorbents for arsenic (V) removal: Assessing performance, toxicity and particle leakage. Science of the total environment.2014; 473-474: 207-214. Available from: <DOI>
  • 40. Önnby L, Pakade V, Mattiasson B, Kirsebom H. Polymer Composite Adsorbents Using Particles of Molecularly Imprinted Polymers or Aluminium Oxide Nanoparticles for Treatment of Arsenic Contaminated Waters. Water. Res 2012; 4 6: 4111-4120. Available from: <DOI>
  • 41. Siddiqui SI, Naushad M, Chaudhry SA. Promising prospects of nanomaterials for arsenic water remediation: A comprehensive review. Process Safety and Environmental Protection. 2019; 126: 60-97. Available from: <DOI>
  • 42. Lu F, Astruc D. Nanomaterials for removal of toxic elements from water. Coordination Chemistry Reviews. 2018; 356: 147-164. Available from: <DOI>
  • 43. Wadhawan S, Jain A, Nayyar J, Mehta SK. . Role of nanomaterials as adsorbents in heavy metal ion removal from waste water: A review. Journal of Water Process Engineering. 2020; 33: 101038. Available from: <DOI>
  • 44. Mostafa MG, Hoinkis J. . Nanoparticle adsorbents for arsenic removal from drinking water: a review. International Journal of Environmental Science, Management and Engineering Research, 2012; 1(1): 20-31.
  • 45. Khin MM, Nair AS, Babu VJ, Murugan R, Ramakrishna S. A review on nanomaterials for environmental remediation. Energy & Environmental Science, 2012; 5(8): 8075-8109. Available from: <DOI> .
  • 46. Wong W, Wong HY, Badruzzaman ABM, Goh HH, Zaman M. . Recent advances in exploitation of nanomaterial for arsenic removal from water: a review. Nanotechnology. 2016; 28(4), 042001. Available from: <DOI>.
  • 47. Alidokht L, Anastopoulos I, Ntarlagiannis D, Soupios P, Tawabini B, Kalderis D, Khataee A. Recent advances in the application of nanomaterials for the remediation of arsenic-contaminated water and soil. Journal of Environmental Chemical Engineering, 2021; 9(4): 105533. Available from: <DOI>
  • 48. Picón D, Torasso N, Baudrit JRV, Cerveny S, Goyanes S. Bio-inspired membranes for adsorption of arsenic via immobilized L-Cysteine in highly hydrophilic electrospun nanofibers. Chemical Engineering Research and Design. 2022; 185: 108-118. Available from: <DOI>.
  • 49. Zhang WX. Nanoscale iron particles for environmental remediation: an overview. Journal of nanoparticle Research, 2003; 5: 323-332. Available from: <DOI>
  • 50. Mosaferi M, Nemati S, Khataee A, Nasseri S, Hashemi AA. Removal of Arsenic (III, V) from aqueous solution by nanoscale zero-valent iron stabilized with starch and carboxymethyl cellulose. Journal of Environmental Health Science and Engineering. 2014; 12: 1-11. Available from: <DOI>
  • 51. Ersan G, Brienza M, Mulchandani A, Apul OG, Garcia-Segura S. . Trends on arsenic species removal by metal-based nanoadsorbents. Current Opinion in Environmental Science & Health. 2023;34: 100478. Available from: <DOI>
  • 52. Patra AK, Dutta A, Bhaumik A. Self-assembled mesoporous γ-Al2O3 spherical nanoparticles and their efficiency for the removal of arsenic from water. Journal of hazardous materials. 2012; 201-202: 170-177. Available from: <DOI>
  • 53. Ghosh S, Prabhakar R, Samadder SR. Performance of γ-aluminium oxide nanoparticles for arsenic removal from groundwater. Clean technologies and environmental policy. 2019; 21: 121-138. Available from: <DOI>
  • 54. Martinson CA, Reddy KJ. Adsorption of arsenic (III) and arsenic (V) by cupric oxide nanoparticles. Journal of colloid and interface science, 2009; 336(2): 406-411. Available from: <DOI>
  • 55. Goswami A, Raul PK, Purkait MK. Arsenic adsorption using copper (II) oxide nanoparticles. Chemical Engineering Research and Design, 2012; 90(9): 1387-1396. Available from: <DOI>
  • 56. Ashraf S, Siddiqa A, Shahida S, Qaisar S. . Titanium-based nanocomposite materials for arsenic removal from water: A review. Heliyon, 2019; 5(5): e01577 Available from: <DOI>
  • 57. Jegadeesan G, Al-Abed SR, Sundaram V, Choi H, Scheckel KG, Dionysiou DD. Arsenic sorption on TiO2 nanoparticles: size and crystallinity effects. Water research, 2010; 44(3): 965-973. Available from: <DOI>
  • 58. Deng M, Chi M, Wei M, Zhu A, Zhong L, Zhang Q, Liu Q. A facile route of mesoporous TiO2 shell for enhanced arsenic removal. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021; 627, 127138. Available from: <DOI>
  • 59. Singh N, Singh SP, Gupta V, Yadav HK, Ahuja T, Tripathy SS, Rashmi. A process for the selective removal of arsenic from contaminated water using acetate functionalized zinc oxide nanomaterials. Environmental Progress & Sustainable Energy, 2013; 32(4): 1023-1029. Available from: <DOI>
  • 60. Rehman H, Ali Z, Hussain M, Gilani SR, Shahzady TG, Zahra A, Farooq MU. Synthesis and characterization of ZnO nanoparticles and their use as an adsorbent for the arsenic removal from drinking water. Digest Journal of Nanomaterials and Biostructures, 2019; 14(4): 1033-1040.
  • 61. Cui H, Su Y, Li Q, Gao S, Shang JK. Exceptional arsenic (III, V) removal performance of highly porous, nanostructured ZrO2 spheres for fixed bed reactors and the full-scale system modeling. Water research, 2013; 47(16): 6258-6268. Available from: <DOI>
  • 62. Zheng YM, Yu L, Wu D, Chen JP. Removal of arsenite from aqueous solution by a zirconia nanoparticle. Chemical engineering journal, 2012; 188: 15-22. Available from: <DOI>
  • 63. Litter MI. A short review on the preparation and use of iron nanomaterials for the treatment of pollutants in water and soil. Emergent Materials, 2022; 5(2): 391-400. Available from: <DOI>
  • 64. Ahmaruzzaman M. Magnetic nanocomposite adsorbents for abatement of arsenic species from water and wastewater. Environmental Science and Pollution Research. 2022; 29(55): 82681-82708 Available from: <DOI>
  • 65. Siddiqui SI, Chaudhry SA. Iron oxide and its modified forms as an adsorbent for arsenic removal: A comprehensive recent advancement. Process Safety and Environmental Protection. 2017; 111: 592-626. Available from: <DOI>
  • 66. Rashid US, Saini-Eidukat B, Bezbaruah AN. Modeling arsenic removal by nanoscale zero-valent iron. Environmental monitoring and assessment. 2020; 192: 1-7. Available from: <DOI>
  • 67. Xue W, Li J, Chen X, Liu H, Wen S, Shi X, Xu Y. Recent advances in sulfidized nanoscale zero-valent iron materials for environmental remediation and challenges. Environmental Science and Pollution Research, 2023; 30(46): 101933-101962. Available from: <DOI>
  • 68. Yin L, Liu L, Lin S, Owens G, Chen Z. Synthesis and characterization of Nanoscale Zero-Valent Iron (nZVI) as an adsorbent for the simultaneous removal of As (III) and As (V) from groundwater. Journal of Water Process Engineering, 2022; 47: 102677. Available from: <DOI>
  • 69. Morgada ME, Levy IK, Salomone V, Farías SS, Lopez G, Litter MI. Arsenic (V) removal with nanoparticulate zerovalent iron: effect of UV light and humic acids. Catalysis Today, 2009; 143(3-4), 261-268. Available from: <DOI>
  • 70. Mamindy-Pajany Y, Hurel C, Marmier N. Roméo M. Arsenic (V) adsorption from aqueous solution onto goethite, hematite, magnetite and zero-valent iron: effects of pH, concentration and reversibility. Desalination, 2011; 281: 93-99. Available from: <DOI>
  • 71. Chowdhury SR, Yanful EK. Arsenic removal from aqueous solutions by adsorption on magnetite nanoparticles. Water and Environment Journal, 2011; 25(3): 429-437. Available from: <DOI>
  • 72. Jain R. Recent advances of magnetite nanomaterials to remove arsenic from water. RSC advances, 2022; 12(50): 32197-32209. Available from: <DOI>
  • 73. Mayo JT, Yavuz C, Yean S, Cong L, Shipley H, Yu W, Colvin VL. The effect of nanocrystalline magnetite size on arsenic removal. Science and technology of advanced materials. 2007; 8(1-2): 71. Available from: <DOI>
  • 74. Arora R. Nano adsorbents for removing the arsenic from waste/ground water for energy and environment management- a review, Materials Today: Proceedings. 2021; 45(6): 4437-4440. Available from: <DOI>.
  • 75. Ahmaruzzaman Md. Recent developments of magnetic nanoadsorbents for remediation of arsenic from aqueous stream, Journal of Environmental Science and Health, Part A. 2022; 57(12): 1058-1072. Available from: <DOI>
  • 76. Polowczyk I, Cyganowski P, Ulatowska J, Sawiński W, Bastrzyk A. Synthetic iron oxides for adsorptive removal of arsenic. Water, Air, & Soil Pollution, 2018; 229: 1-10. Available from: <DOI>
  • 77. Deliyanni EA, Lazaridis NK. Matis KA. Arsenates Sorption by Nanocrystalline Hybrid Surfactant-Akaganéite, Separation Science and Technology, 2012; 47(16): 2331-2339. Available from: <DOI>
  • 78. Salem Attia TM, Hu XL, Yin DQ. Synthesised magnetic nanoparticles coated zeolite (MNCZ) for the removal of arsenic (As) from aqueous solution. Journal of Experimental Nanoscience, 2014; 9(6): 551-560. Available from: <DOI>
  • 79. El-Sayed ME. Nanoadsorbents for water and wastewater remediation. Science of the Total Environment, 2020; 739: 139903. Available from: <DOI>
  • 80. Jamali‐Behnam F, Najafpoor AA, Davoudi M, Rohani‐Bastami T, Alidadi H, Esmaily H, Dolatabadi M. Adsorptive removal of arsenic from aqueous solutions using magnetite nanoparticles and silica‐coated magnetite nanoparticles. Environmental Progress & Sustainable Energy, 2018; 37(3): 951-960. <DOI>
  • 81. Vitela-Rodriguez AV, Rangel-Mendez JR. Arsenic removal by modified activated carbons with iron hydro (oxide) nanoparticles. Journal of environmental management, 2013; 114: 225-231. Available from: <DOI>
  • 82. Gupta VK, Moradi O, Tyagi I, Agarwal S, Sadegh H, Shahryari Ghoshekandi R, Makhlouf ASH, Goodarzi M, & Garshasbi A. Study on the removal of heavy metal ions from industry waste by carbon nanotubes: Effect of the surface modification: a review, Critical Reviews in Environmental Science and Technology, 2016; 46(2): 93-118. Available from: <DOI>
  • 83. Liu X, Wang M, Zhang S, Pan B. Application potential of carbon nanotubes in water treatment: a review. Journal of Environmental Sciences, 2013; 25(7): 1263-1280. Available from: <DOI>
  • 84. Ali I. Microwave assisted economic synthesis of multi walled carbon nanotubes for arsenic species removal in water: batch and column operations. Journal of molecular liquids, 2018; 271: 677-685. Available from: <DOI>
  • 85. Tabatabaiee Bafrooee AA, Moniri E, Ahmad Panahi H, Miralinaghi M, Hasani AH. Ethylenediamine functionalized magnetic graphene oxide (Fe3O4@GO-EDA) as an efficient adsorbent in Arsenic (III) decontamination from aqueous solution. Research on Chemical Intermediates, 2021; 47: 1397-1428. Available from: <DOI>
  • 86. Bhaumik M, Noubactep C, Gupta VK, McCrindle RI, Maity A. Polyaniline/Fe0 composite nanofibers: An excellent adsorbent for the removal of arsenic from aqueous solutions. Chemical Engineering Journal, 2015; 271: 135-146. Available from: <DOI>
  • 87. Pontoni L, Fabbricino M. Use of chitosan and chitosan-derivatives to remove arsenic from aqueous solutions—a mini review. Carbohydrate research, 2012; 356, 86-92. Available from: <DOI>
  • 88. Singh P, Bajpai J, Bajpai AK, Shrivastava RB. Fixed-bed studies on removal of arsenic from simulated aqueous solutions using chitosan nanoparticles. Bioremediation journal, 2011; 15(3): 148-156. Available from: <DOI>
  • 89. Min LL, Zhong LB, Zheng YM, Liu Q, Yuan ZH, Yang LM. Functionalized chitosan electrospun nanofiber for effective removal of trace arsenate from water. Scientific reports, 2016; 6(1): 32480. Available from: <DOI>
  • 90. Chai F, Wang R, Yan L, Li G, Cai Y, Xi C. Facile fabrication of pH-sensitive nanoparticles based on nanocellulose for fast and efficient As(V) removal. Carbohydrate polymers, 2020; 245: 116511. Available from: <DOI>
  • 91. Prabhu SM, Pawar RR, Sasaki K, Park CM. A mechanistic investigation of highly stable nano ZrO2 decorated nitrogen-rich azacytosine tethered graphene oxide-based dendrimer for the removal of arsenite from water. Chemical Engineering Journal, 2019; 370: 1474-1484. Available from: <DOI>
  • 92. Yavari Z, Amin MM, Izanloo H, Rahimi S, Mohamadi F. Using Generation 3 Polyamidoamine Dendrimer as Adsorbent for the Removal of Pentavalent Arsenic from Aqueous Solutions. J Environ Health Sustain Dev, 2016; 1(1): 28-36.
  • 93. Kumar A, Joshi H, Kumar A. Remediation of arsenic by metal/metal oxide-based nanocomposites/nanohybrids: contamination scenario in groundwater, practical challenges, and future perspectives. Separation & Purification Reviews, 2021; 50(3): 283-314. Available from: <DOI>
  • 94. Türkmen D, Özkaya-Türkmen M, Akgönüllü S, Denizli A. Development of ion imprinted based magnetic nanoparticles for selective removal of arsenic (III) and arsenic (V) from wastewater, Separation Science and Technology, 2022; 57(6): 990-999. Available from: <DOI>
  • 95. Haris SA, Dabagh S, Mollasalehi H, Ertas YN. Alginate coated superparamagnetic iron oxide nanoparticles as nanocomposite adsorbents for arsenic removal from aqueous solutions. 2023; Separation and Purification Technology, 310, 123193. Available from: <DOI>
  • 96. Abdollahi M, Zeinali S, Nasirimoghaddam S, Sabbaghi S. Effective removal of As(III) from drinking water samples by chitosan-coated magnetic nanoparticles. Desalination and Water Treatment, 2015; 56(8): 2092-2104. Available from: <DOI>
  • 97. Morillo D, Uheida A, Pérez G, Muhammed M, Valiente M. Arsenate removal with 3-mercaptopropanoic acid-coated superparamagnetic iron oxide nanoparticles. Journal of colloid and interface science, 2015; 438, 227-234. Available from: <DOI>
  • 98. Tripathy M, Padhiari S, Hota G. L-Cysteine-Functionalized Mesoporous Magnetite Nanospheres: Synthesis and Adsorptive Application toward Arsenic Remediation. Journal of Chemical Engineering Data. 2020; 65(8): 3906-3919. Available from: <DOI>
  • 99. Biftu WK, Ravindhranath K, Ramamoorty M. New research trends in the processing and applications of iron-based nanoparticles as adsorbents in water remediation methods. Nanotechnology for Environmental Engineering, 2020; 5: 1-12. Available from: <DOI>
  • 100. Gurbuz F, Akpınar Ş, Ozcan S, Acet Ö, Odabaşı M. Reducing arsenic and groundwater contaminants down to safe level for drinking purposes via Fe 3+-attached hybrid column. Environmental monitoring and assessment, 2019;191, 1-14. Available from: <DOI>
Year 2024, Volume: 11 Issue: 2, 845 - 868, 15.05.2024
https://doi.org/10.18596/jotcsa.1438869

Abstract

References

  • 1. Smedley PL, Kinniburgh DG. A Review of the Source, Behavior and Distribution of Arsenic in Natural Waters. Applied Geochemistry. 2002; 17(5): 517–568. Available from: <DOI>
  • 2. Mohan D, Pittman CU. Arsenic removal from water/wastewater using adsorbents A critical review, Journal of Hazardous Materials. 2007; 142(1-2):1-53. Available from: <DOI> .
  • 3. Mandal BK, Suzuki KT. Arsenic round the world: a review. Talanta. 2002; 58(1): 201-235. Available from: <DOI>.
  • 4. Sharma VK, Sohn M. Aquatic arsenic: toxicity, speciation, transformations, and remediation. Environment international. 2009; 35(4): 743-759
  • 5. Weerasundara L, Ok YS, Bundschuh J. Selective removal of arsenic in water: A critical review, Environmental Pollution. 2021; 268: 115668 Available from: <DOI>
  • 6. Teixeira MC, Ciminelli VST, Dantas MSS, Diniz SF, Duarte HA Raman Spectroscopy and DFT Calculations of As(III) Complexation with a Cysteine-Rich Biomaterial. Journal of Colloid and Interface Science. 2007; 315(1): 128-134 Available from: <DOI>
  • 7. Patel K S, Pandey P K, Martín-Ramos P, Corns WT, Varol S, Bhattacharya P, Zhu Y. A review on arsenic in the environment: contamination, mobility, sources, and exposure. RSC Advances, 2023; 13(13): 8803-8821.
  • 8. Shen S, Li XF, Cullen WR, Weinfeld M, Le XC. Arsenic binding to proteins. Chemical Reviews 2013; 113(10): 7769-7792. Available from: <DOI>
  • 9. Mudhoo A, Sharma S K, Garg V K, Tseng CH. Arsenic: an overview of applications, health, and environmental concerns and removal processes. Critical Reviews in Environmental Science and Technology, 2011; 41(5): 435-519. Available from: <DOI>.
  • 10. Choong TS, Chuah TG, Robiah Y, Koay FG, Azni I. Arsenic toxicity, health hazards and removal techniques from water: an overview. Desalination. 2007; 217(1-3): 139-166. Available from: <DOI>.
  • 11. Altowayti WAH, Othman N, Shahir S, Alshalif AF, Al-Gheethi AA, Al-Towayti FAH, Haris SA. Removal of arsenic from wastewater by using different technologies and adsorbents: A review. International Journal of Environmental Science and Technology.2021;19:9243–9266. Available from:<DOI>
  • 12. Dilpazeer F, Munir M, Baloch MYJ, Shafiq I, Iqbal J, Saeed M, Mahboob I. A Comprehensive Review of the Latest Advancements in Controlling Arsenic Contaminants in Groundwater. Water. 2023; 15(3): 478. Available from: <DOI>
  • 13. Rathi BS, Kumar PS. A review on sources, identification and treatment strategies for the removal of toxic Arsenic from water system. Journal of Hazardous Materials 2021; 418: 126299. Available from: <DOI>
  • 14. Singh R, Singh S, Parihar P, Singh VP, Prasad SM. Arsenic contamination, consequences and remediation techniques: a review. Ecotoxicology and environmental safety. 2015; 112: 247-270. Available from: <DOI>
  • 15. Mahamallik P, Swain R. A mini-review on arsenic remediation techniques from water and future trends. Water Science and Technology. 2023; 87(12): 3108-3123. Available from: <DOI>
  • 16. Alka S, Shahir S, Ibrahim N, Ndejiko MJ, Vo DVN, Abd Manan F. Arsenic removal technologies and future trends: A mini review. Journal of Cleaner Production. 2021; 278, 123805. Available from: <DOI>
  • 17. Rahidul Hassan, H. A review on different arsenic removal techniques used for decontamination of drinking water. Environmental Pollutants and Bioavailability, 2023; 35(1): 2165964. Available from: <DOI>
  • 18. Nicomel NR, Leus K, Folens K, Van Der Voort P, Du Laing G. Technologies for arsenic removal from water: current status and future perspectives. International journal of environmental research and public health. 2016; 13(1): 62. Available from: <DOI>.
  • 19. Ahmed MF. An overview of arsenic removal technologies in Bangladesh and India. In Proceedings of BUET-UNU international workshop on technologies for arsenic removal from drinking water, Dhaka. 2001; 5-7.
  • 20. Selatile MK, Ray SS, Ojijo V, Sadiku R. Recent developments in polymeric electrospun nanofibrous membranes for seawater desalination. RSC Advances, 2018; 8(66): 37915-37938. Available from: <DOI>
  • 21. Kirisenage PM, Zulqarnain SM, Myers JL, Fahlman BD, Mueller A, Marquez I. Development of Adsorptive Membranes for Selective Removal of Contaminants in Water. Polymers, 2022; 14(15): 3146. Available from: <DOI>
  • 22. Moreira VR, Lebron YAR, Santos LVS, de Paula EC, Amaral MCS. Arsenic contamination, effects and remediation techniques: A special look onto membrane separation processes. Process Safety and Environmental Protection. 2021; 148, 604-623. Available from: <DOI>
  • 23. Chen M, Shafer-Peltier K, Randtke S J, Peltier E. Modeling arsenic (V) removal from water by micellar enhanced ultrafiltration in the presence of competing anions. Chemosphere. 2018; 213: 285-294. Available from: <DOI>
  • 24. Chia RJJ, Lau WJ, Yusof N, Shokravi H, Ismail AF. Adsorptive Membranes for Arsenic Removal–Principles, Progress and Challenges. Separation & Purification Reviews, 2023; 52(4): 379-399.<DOI>
  • 25. Awual MR, Hossain MA, Shenashen M. Evaluating of arsenic(V) removal from water by weak-base anion exchange adsorbents. Environmental science and pollution research international. 2013; 20:421-430. Available from: <DOI>
  • 26. Wang Y, Tsang DC. Effects of solution chemistry on arsenic (V) removal by low-cost adsorbents. Journal of Environmental Sciences. 2013; 25(11): 2291-2298. Available from: <DOI>.
  • 27. Crini G, Lichtfouse E, Wilson LD, Morin-Crini N. Conventional and non-conventional adsorbents for wastewater treatment. Environmental Chemistry Letters, 2019; 17, 195-213. Available from: <DOI>
  • 28. Liu B, Kim KH, Kumar V, Kim S. A review of functional sorbents for adsorptive removal of arsenic ions in aqueous systems. Journal of hazardous materials, 2020; 388, 121815. Available from: <DOI>
  • 29. Kyzas GZ, Matis KA. Nanoadsorbents for pollutants removal: a review. Journal of Molecular Liquids. 2015; 203, 159-168. Available from: <DOI>
  • 30. Ali I. New generation adsorbents for water treatment. Chemical Reviews, 2012; 112(10): 5073-5091. Available from: <DOI>
  • 31. Habuda-Stanić M, Nujić M. Arsenic removal by nanoparticles: a review. Environ Sci Pollut Res. 2015; 22: 8094–8123. Available from: <DOI>
  • 32. Lata S, Samadder SR. Removal of arsenic from water using nano adsorbents and challenges: A review, Journal of Environmental Management. 2016;166: 387-406. Available from: <DOI>.
  • 33. Mohmood I, Lopes CB, Lopes I, Ahmad I, Duarte AC, Pereira E. Nanoscale materials and their use in water contaminants removal—a review. Environmental science and pollution Research. 2013; 20: 1239-1260. Available from: <DOI>
  • 34. Khan NA, Khan SU, Ahmed S, Farooqi IH, Dhingra A, Hussain A, Changani F. Applications of nanotechnology in water and wastewater treatment: A review. Asian Journal of Water, Environment and Pollution. 2019; 16(4): 81-86. Available from: <DOI>
  • 35. Saha S, Sarkar P. Arsenic remediation from drinking water by synthesized nano-alumina dispersed in chitosan-grafted polyacrylamide. Journal of hazardous materials. 2012; 227-228: 68-78. Available from: <DOI>
  • 36. Yürüm A, Kocabaş Ataklı ZÖ, Sezen M, Semiat R, Yürüm Y. Fast deposition of porous iron oxide on activated carbon by microwave heating and arsenic (V) removal from water.Chemical Engineering Journal.2014; 242: 321-332. Available from: <DOI>.
  • 37. Pizarro C, Rubio MA, Escudey M, Albornoz MF, Muñoz D, Denardin J, Fabris JD. Nanomagnetite-zeolite composites in the removal of arsenate from aqueous systems. Journal of the Brazilian Chemical Society.2015; 26: 1887-1896. Available from: <DOI>
  • 38. Savina IN, English CJ, Whitby RL, Zheng Y, Leistner A, Mikhalovsky SV, Cundy AB. . High efficiency removal of dissolved As (III) using iron nanoparticle-embedded macroporous polymer composites. Journal of hazardous materials. 2011; 192(3): 1002-1008. Available from: <DOI>
  • 39. Önnby L, Svensson C, Mbundi L, Busquets R, Cundy A, Kirsebom H. . γ-Al2O3-based nanocomposite adsorbents for arsenic (V) removal: Assessing performance, toxicity and particle leakage. Science of the total environment.2014; 473-474: 207-214. Available from: <DOI>
  • 40. Önnby L, Pakade V, Mattiasson B, Kirsebom H. Polymer Composite Adsorbents Using Particles of Molecularly Imprinted Polymers or Aluminium Oxide Nanoparticles for Treatment of Arsenic Contaminated Waters. Water. Res 2012; 4 6: 4111-4120. Available from: <DOI>
  • 41. Siddiqui SI, Naushad M, Chaudhry SA. Promising prospects of nanomaterials for arsenic water remediation: A comprehensive review. Process Safety and Environmental Protection. 2019; 126: 60-97. Available from: <DOI>
  • 42. Lu F, Astruc D. Nanomaterials for removal of toxic elements from water. Coordination Chemistry Reviews. 2018; 356: 147-164. Available from: <DOI>
  • 43. Wadhawan S, Jain A, Nayyar J, Mehta SK. . Role of nanomaterials as adsorbents in heavy metal ion removal from waste water: A review. Journal of Water Process Engineering. 2020; 33: 101038. Available from: <DOI>
  • 44. Mostafa MG, Hoinkis J. . Nanoparticle adsorbents for arsenic removal from drinking water: a review. International Journal of Environmental Science, Management and Engineering Research, 2012; 1(1): 20-31.
  • 45. Khin MM, Nair AS, Babu VJ, Murugan R, Ramakrishna S. A review on nanomaterials for environmental remediation. Energy & Environmental Science, 2012; 5(8): 8075-8109. Available from: <DOI> .
  • 46. Wong W, Wong HY, Badruzzaman ABM, Goh HH, Zaman M. . Recent advances in exploitation of nanomaterial for arsenic removal from water: a review. Nanotechnology. 2016; 28(4), 042001. Available from: <DOI>.
  • 47. Alidokht L, Anastopoulos I, Ntarlagiannis D, Soupios P, Tawabini B, Kalderis D, Khataee A. Recent advances in the application of nanomaterials for the remediation of arsenic-contaminated water and soil. Journal of Environmental Chemical Engineering, 2021; 9(4): 105533. Available from: <DOI>
  • 48. Picón D, Torasso N, Baudrit JRV, Cerveny S, Goyanes S. Bio-inspired membranes for adsorption of arsenic via immobilized L-Cysteine in highly hydrophilic electrospun nanofibers. Chemical Engineering Research and Design. 2022; 185: 108-118. Available from: <DOI>.
  • 49. Zhang WX. Nanoscale iron particles for environmental remediation: an overview. Journal of nanoparticle Research, 2003; 5: 323-332. Available from: <DOI>
  • 50. Mosaferi M, Nemati S, Khataee A, Nasseri S, Hashemi AA. Removal of Arsenic (III, V) from aqueous solution by nanoscale zero-valent iron stabilized with starch and carboxymethyl cellulose. Journal of Environmental Health Science and Engineering. 2014; 12: 1-11. Available from: <DOI>
  • 51. Ersan G, Brienza M, Mulchandani A, Apul OG, Garcia-Segura S. . Trends on arsenic species removal by metal-based nanoadsorbents. Current Opinion in Environmental Science & Health. 2023;34: 100478. Available from: <DOI>
  • 52. Patra AK, Dutta A, Bhaumik A. Self-assembled mesoporous γ-Al2O3 spherical nanoparticles and their efficiency for the removal of arsenic from water. Journal of hazardous materials. 2012; 201-202: 170-177. Available from: <DOI>
  • 53. Ghosh S, Prabhakar R, Samadder SR. Performance of γ-aluminium oxide nanoparticles for arsenic removal from groundwater. Clean technologies and environmental policy. 2019; 21: 121-138. Available from: <DOI>
  • 54. Martinson CA, Reddy KJ. Adsorption of arsenic (III) and arsenic (V) by cupric oxide nanoparticles. Journal of colloid and interface science, 2009; 336(2): 406-411. Available from: <DOI>
  • 55. Goswami A, Raul PK, Purkait MK. Arsenic adsorption using copper (II) oxide nanoparticles. Chemical Engineering Research and Design, 2012; 90(9): 1387-1396. Available from: <DOI>
  • 56. Ashraf S, Siddiqa A, Shahida S, Qaisar S. . Titanium-based nanocomposite materials for arsenic removal from water: A review. Heliyon, 2019; 5(5): e01577 Available from: <DOI>
  • 57. Jegadeesan G, Al-Abed SR, Sundaram V, Choi H, Scheckel KG, Dionysiou DD. Arsenic sorption on TiO2 nanoparticles: size and crystallinity effects. Water research, 2010; 44(3): 965-973. Available from: <DOI>
  • 58. Deng M, Chi M, Wei M, Zhu A, Zhong L, Zhang Q, Liu Q. A facile route of mesoporous TiO2 shell for enhanced arsenic removal. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021; 627, 127138. Available from: <DOI>
  • 59. Singh N, Singh SP, Gupta V, Yadav HK, Ahuja T, Tripathy SS, Rashmi. A process for the selective removal of arsenic from contaminated water using acetate functionalized zinc oxide nanomaterials. Environmental Progress & Sustainable Energy, 2013; 32(4): 1023-1029. Available from: <DOI>
  • 60. Rehman H, Ali Z, Hussain M, Gilani SR, Shahzady TG, Zahra A, Farooq MU. Synthesis and characterization of ZnO nanoparticles and their use as an adsorbent for the arsenic removal from drinking water. Digest Journal of Nanomaterials and Biostructures, 2019; 14(4): 1033-1040.
  • 61. Cui H, Su Y, Li Q, Gao S, Shang JK. Exceptional arsenic (III, V) removal performance of highly porous, nanostructured ZrO2 spheres for fixed bed reactors and the full-scale system modeling. Water research, 2013; 47(16): 6258-6268. Available from: <DOI>
  • 62. Zheng YM, Yu L, Wu D, Chen JP. Removal of arsenite from aqueous solution by a zirconia nanoparticle. Chemical engineering journal, 2012; 188: 15-22. Available from: <DOI>
  • 63. Litter MI. A short review on the preparation and use of iron nanomaterials for the treatment of pollutants in water and soil. Emergent Materials, 2022; 5(2): 391-400. Available from: <DOI>
  • 64. Ahmaruzzaman M. Magnetic nanocomposite adsorbents for abatement of arsenic species from water and wastewater. Environmental Science and Pollution Research. 2022; 29(55): 82681-82708 Available from: <DOI>
  • 65. Siddiqui SI, Chaudhry SA. Iron oxide and its modified forms as an adsorbent for arsenic removal: A comprehensive recent advancement. Process Safety and Environmental Protection. 2017; 111: 592-626. Available from: <DOI>
  • 66. Rashid US, Saini-Eidukat B, Bezbaruah AN. Modeling arsenic removal by nanoscale zero-valent iron. Environmental monitoring and assessment. 2020; 192: 1-7. Available from: <DOI>
  • 67. Xue W, Li J, Chen X, Liu H, Wen S, Shi X, Xu Y. Recent advances in sulfidized nanoscale zero-valent iron materials for environmental remediation and challenges. Environmental Science and Pollution Research, 2023; 30(46): 101933-101962. Available from: <DOI>
  • 68. Yin L, Liu L, Lin S, Owens G, Chen Z. Synthesis and characterization of Nanoscale Zero-Valent Iron (nZVI) as an adsorbent for the simultaneous removal of As (III) and As (V) from groundwater. Journal of Water Process Engineering, 2022; 47: 102677. Available from: <DOI>
  • 69. Morgada ME, Levy IK, Salomone V, Farías SS, Lopez G, Litter MI. Arsenic (V) removal with nanoparticulate zerovalent iron: effect of UV light and humic acids. Catalysis Today, 2009; 143(3-4), 261-268. Available from: <DOI>
  • 70. Mamindy-Pajany Y, Hurel C, Marmier N. Roméo M. Arsenic (V) adsorption from aqueous solution onto goethite, hematite, magnetite and zero-valent iron: effects of pH, concentration and reversibility. Desalination, 2011; 281: 93-99. Available from: <DOI>
  • 71. Chowdhury SR, Yanful EK. Arsenic removal from aqueous solutions by adsorption on magnetite nanoparticles. Water and Environment Journal, 2011; 25(3): 429-437. Available from: <DOI>
  • 72. Jain R. Recent advances of magnetite nanomaterials to remove arsenic from water. RSC advances, 2022; 12(50): 32197-32209. Available from: <DOI>
  • 73. Mayo JT, Yavuz C, Yean S, Cong L, Shipley H, Yu W, Colvin VL. The effect of nanocrystalline magnetite size on arsenic removal. Science and technology of advanced materials. 2007; 8(1-2): 71. Available from: <DOI>
  • 74. Arora R. Nano adsorbents for removing the arsenic from waste/ground water for energy and environment management- a review, Materials Today: Proceedings. 2021; 45(6): 4437-4440. Available from: <DOI>.
  • 75. Ahmaruzzaman Md. Recent developments of magnetic nanoadsorbents for remediation of arsenic from aqueous stream, Journal of Environmental Science and Health, Part A. 2022; 57(12): 1058-1072. Available from: <DOI>
  • 76. Polowczyk I, Cyganowski P, Ulatowska J, Sawiński W, Bastrzyk A. Synthetic iron oxides for adsorptive removal of arsenic. Water, Air, & Soil Pollution, 2018; 229: 1-10. Available from: <DOI>
  • 77. Deliyanni EA, Lazaridis NK. Matis KA. Arsenates Sorption by Nanocrystalline Hybrid Surfactant-Akaganéite, Separation Science and Technology, 2012; 47(16): 2331-2339. Available from: <DOI>
  • 78. Salem Attia TM, Hu XL, Yin DQ. Synthesised magnetic nanoparticles coated zeolite (MNCZ) for the removal of arsenic (As) from aqueous solution. Journal of Experimental Nanoscience, 2014; 9(6): 551-560. Available from: <DOI>
  • 79. El-Sayed ME. Nanoadsorbents for water and wastewater remediation. Science of the Total Environment, 2020; 739: 139903. Available from: <DOI>
  • 80. Jamali‐Behnam F, Najafpoor AA, Davoudi M, Rohani‐Bastami T, Alidadi H, Esmaily H, Dolatabadi M. Adsorptive removal of arsenic from aqueous solutions using magnetite nanoparticles and silica‐coated magnetite nanoparticles. Environmental Progress & Sustainable Energy, 2018; 37(3): 951-960. <DOI>
  • 81. Vitela-Rodriguez AV, Rangel-Mendez JR. Arsenic removal by modified activated carbons with iron hydro (oxide) nanoparticles. Journal of environmental management, 2013; 114: 225-231. Available from: <DOI>
  • 82. Gupta VK, Moradi O, Tyagi I, Agarwal S, Sadegh H, Shahryari Ghoshekandi R, Makhlouf ASH, Goodarzi M, & Garshasbi A. Study on the removal of heavy metal ions from industry waste by carbon nanotubes: Effect of the surface modification: a review, Critical Reviews in Environmental Science and Technology, 2016; 46(2): 93-118. Available from: <DOI>
  • 83. Liu X, Wang M, Zhang S, Pan B. Application potential of carbon nanotubes in water treatment: a review. Journal of Environmental Sciences, 2013; 25(7): 1263-1280. Available from: <DOI>
  • 84. Ali I. Microwave assisted economic synthesis of multi walled carbon nanotubes for arsenic species removal in water: batch and column operations. Journal of molecular liquids, 2018; 271: 677-685. Available from: <DOI>
  • 85. Tabatabaiee Bafrooee AA, Moniri E, Ahmad Panahi H, Miralinaghi M, Hasani AH. Ethylenediamine functionalized magnetic graphene oxide (Fe3O4@GO-EDA) as an efficient adsorbent in Arsenic (III) decontamination from aqueous solution. Research on Chemical Intermediates, 2021; 47: 1397-1428. Available from: <DOI>
  • 86. Bhaumik M, Noubactep C, Gupta VK, McCrindle RI, Maity A. Polyaniline/Fe0 composite nanofibers: An excellent adsorbent for the removal of arsenic from aqueous solutions. Chemical Engineering Journal, 2015; 271: 135-146. Available from: <DOI>
  • 87. Pontoni L, Fabbricino M. Use of chitosan and chitosan-derivatives to remove arsenic from aqueous solutions—a mini review. Carbohydrate research, 2012; 356, 86-92. Available from: <DOI>
  • 88. Singh P, Bajpai J, Bajpai AK, Shrivastava RB. Fixed-bed studies on removal of arsenic from simulated aqueous solutions using chitosan nanoparticles. Bioremediation journal, 2011; 15(3): 148-156. Available from: <DOI>
  • 89. Min LL, Zhong LB, Zheng YM, Liu Q, Yuan ZH, Yang LM. Functionalized chitosan electrospun nanofiber for effective removal of trace arsenate from water. Scientific reports, 2016; 6(1): 32480. Available from: <DOI>
  • 90. Chai F, Wang R, Yan L, Li G, Cai Y, Xi C. Facile fabrication of pH-sensitive nanoparticles based on nanocellulose for fast and efficient As(V) removal. Carbohydrate polymers, 2020; 245: 116511. Available from: <DOI>
  • 91. Prabhu SM, Pawar RR, Sasaki K, Park CM. A mechanistic investigation of highly stable nano ZrO2 decorated nitrogen-rich azacytosine tethered graphene oxide-based dendrimer for the removal of arsenite from water. Chemical Engineering Journal, 2019; 370: 1474-1484. Available from: <DOI>
  • 92. Yavari Z, Amin MM, Izanloo H, Rahimi S, Mohamadi F. Using Generation 3 Polyamidoamine Dendrimer as Adsorbent for the Removal of Pentavalent Arsenic from Aqueous Solutions. J Environ Health Sustain Dev, 2016; 1(1): 28-36.
  • 93. Kumar A, Joshi H, Kumar A. Remediation of arsenic by metal/metal oxide-based nanocomposites/nanohybrids: contamination scenario in groundwater, practical challenges, and future perspectives. Separation & Purification Reviews, 2021; 50(3): 283-314. Available from: <DOI>
  • 94. Türkmen D, Özkaya-Türkmen M, Akgönüllü S, Denizli A. Development of ion imprinted based magnetic nanoparticles for selective removal of arsenic (III) and arsenic (V) from wastewater, Separation Science and Technology, 2022; 57(6): 990-999. Available from: <DOI>
  • 95. Haris SA, Dabagh S, Mollasalehi H, Ertas YN. Alginate coated superparamagnetic iron oxide nanoparticles as nanocomposite adsorbents for arsenic removal from aqueous solutions. 2023; Separation and Purification Technology, 310, 123193. Available from: <DOI>
  • 96. Abdollahi M, Zeinali S, Nasirimoghaddam S, Sabbaghi S. Effective removal of As(III) from drinking water samples by chitosan-coated magnetic nanoparticles. Desalination and Water Treatment, 2015; 56(8): 2092-2104. Available from: <DOI>
  • 97. Morillo D, Uheida A, Pérez G, Muhammed M, Valiente M. Arsenate removal with 3-mercaptopropanoic acid-coated superparamagnetic iron oxide nanoparticles. Journal of colloid and interface science, 2015; 438, 227-234. Available from: <DOI>
  • 98. Tripathy M, Padhiari S, Hota G. L-Cysteine-Functionalized Mesoporous Magnetite Nanospheres: Synthesis and Adsorptive Application toward Arsenic Remediation. Journal of Chemical Engineering Data. 2020; 65(8): 3906-3919. Available from: <DOI>
  • 99. Biftu WK, Ravindhranath K, Ramamoorty M. New research trends in the processing and applications of iron-based nanoparticles as adsorbents in water remediation methods. Nanotechnology for Environmental Engineering, 2020; 5: 1-12. Available from: <DOI>
  • 100. Gurbuz F, Akpınar Ş, Ozcan S, Acet Ö, Odabaşı M. Reducing arsenic and groundwater contaminants down to safe level for drinking purposes via Fe 3+-attached hybrid column. Environmental monitoring and assessment, 2019;191, 1-14. Available from: <DOI>
There are 100 citations in total.

Details

Primary Language English
Subjects Inorganic Chemistry (Other)
Journal Section REVIEW ARTICLES
Authors

Veyis Karakoç 0000-0002-2511-6478

Erol Erçağ This is me 0000-0003-4927-2405

Publication Date May 15, 2024
Submission Date February 18, 2024
Acceptance Date March 3, 2024
Published in Issue Year 2024 Volume: 11 Issue: 2

Cite

Vancouver Karakoç V, Erçağ E. New Generation Nanoadsorbents and Conventional Techniques for Arsenic Removal from Waters. JOTCSA. 2024;11(2):845-68.