5 research outputs found

    Comprehensive dataset on fluoride removal from aqueous solution by enhanced electrocoagulation process by persulfate salts

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    Depending on the quantity and concentration, drinking water containing fluoride (F–) ions can have either favorable or unfavorable impacts on individuals and the environment. High levels of F– (over 2 to 4 mg/L) can cause skeletal problems, dental fluorosis, and brain damage in children. Conventional F– removal is often complex and thus causes an adverse effect on the environment and financial burdens. The use of persulfate salts to enhance the electrocoagulation process is one of the most recent advances in the removal of F– from water. To investigate the efficacy of F– removal, a laboratory-scale electrochemical batch reactor with iron and aluminum electrodes was employed with various persulfate doses, pH values, current intensities, and supporting electrolyte concentrations. It was observed that the performance of the enhanced electrocoagulation process by persulfate increased over time, and it worked well in a certain range of pH. Also, for the initial F– concentration of 10 mg/L, increasing the supporting electrolyte concentration to 1.5 g/L improved fluoride removal efficiency from 80 to 91.2%, but higher concentrations (2.5 g/L) reduced efficiency to 71%. The most effective removal of F– was found to occur at a persulfate dose of 0.2 mg/L. At this dose, F– removal efficiency exceeded 92% for all studied F– concentrations. Overall, electrocoagulation using persulfate salts proved more efficient than electrocoagulation alone at removing fluoride from water sources

    Dataset of fluoride concentration and health risk assessment in drinking water in the Saveh City of Markazi Province, Iran

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    This study aims at analyzing fluoride levels in water sources and drinking water in Saveh City, with a focus on health risks assessment. Excessive fluoride concentrations (above 2 to 4 mg/L) can lead to skeletal issues, dental fluorosis, and brain damage, while low concentrations (below 0.7-1.5 mg/L depending on temperature) can harm tooth health and strength. For drinking water consumptions, centralized and decentralized desalination units were utilized from, Saveh's brackish water. In this research study a total of 63 samples were collected randomly from underground and surface water sources, distribution networks, and desalination units during both Winter and Summer seasons. Fluoride analysis was conducted using the spectrophotometric method with the DR6000 device and SPADNS reagent. The results indicated that during winter, average fluoride concentrations in underground water, water treatment plant output, distribution network, centralized desalination unit output, and decentralized desalination unit output were 0.67, 0.64, 0.62, 0.064, and 0.07 mg/L, respectively. In summer, the average concentrations were 0.79, 0.75, 0.71, 0.04, and 0.07 mg/L, respectively. For desalinated water produced by centralized desalination units during the summer season, the Estimated Daily Intake (EDI) values for fluoride in different age groups, including infants, children, teenagers, and adults, were found to be 0.0003, 0.0023, 0.0016, and 0.0013 mg/kg, respectively. Health risk assessment data indicated Hazard Quotient (HQ) values for fluoride in these age groups were 0.005, 0.037, 0.026, and 0.02, respectively. Similar values were observed in the winter data. However, it is important to note that the fluoride concentration in Saveh's drinking water is nearly zero, and the absence of fluoride in desalinated drinking water can have a negative impact on dental health. Therefore, it is crucial to address the lack of fluoride in the drinking water of this city

    Dataset on the spent filter backwash water treatment by sedimentation, coagulation and ultra filtration

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    During operation of most water treatment plants, spent filter backwash water (SFBW) is generated, which accounts about 2â10% of the total plant production. By increasing world population and water shortage in many countries, SFBW can be used as a permanent water source until the water treatment plant is working. This data article reports the practical method being used for water reuse from SFBW through different method including pre-sedimentation, coagulation and flocculation, second clarification, ultra filtration (UF) and returned settled SFBW to the beginning of water treatment plant (WTP). Also, two coagulants of polyaluminum ferric chloride (PAFCl) and ferric chloride (FeCl3) were investigated with respect to their performance on treated SFBW quality. Samples were collected from Isfahan's WTP in Iran during spring and summer season. The acquired data indicated that drinkable water can be produced form SFBW by applying hybrid coagulation-UF process (especially when PAFCl used as coagulant). Keywords: Spent filter backwash water, Water treatment, Coagulation, Ultra-filtratio

    Carbon Nanotubes Technology for Removal of Arsenic from Water

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    Please cite this article as: Naghizadeh A, Yari AR, Tashauoei HR, Mahdavi M, Derakhshani E, Rahimi R, Bahmani P. Carbon nanotubes technology for removal of arsenic from water. Arch Hyg Sci 2012;1(1):6-11. Aims of the Study: This study was aimed to investigate the adsorption mechanism of the arsenic removal from water by using carbon nanotubes in continuous adsorption column. Materials & Methods: Independent variables including carbon nanotubes dosage, contact time and breakthrough point were carried out to determine the influence of these parameters on the adsorption capacity of the arsenic from water. Results: Adsorption capacities of single wall and multiwall carbon nanotubes were about 148 mg/g and 95 mg/g respectively. The experimental data were analyzed using Langmuir and Freundlich isotherm models and equilibrium data indicate the best fit obtained with Langmuir isotherm model. Conclusions: Carbon nanotubes can be considered as a promising adsorbent for the removal of arsenic from large volume of aqueous solutions. References: 1. Lomaquahu ES, Smith AH. Feasibility of new epidemiology studies on arsenic exposures at low levels. AWWA Inorganic Contaminants Workshop. San Antonio; 1998. 2. Burkel RS, Stoll RC. Naturally occurring arsenic in sandstone aquifer water supply wells of North Eastern Wisconsin. Ground Water Monit Remediat 1999;19(2):114-21. 3. Mondal P, Majumder CB, Mohanty B. Laboratory based approaches for arsenic remediation from contaminated water: recent developments. J Hazard Mater 2006;137(1): 464-79. 4. Meenakshi RCM. Arsenic removal from water: a review. Asian J Water Environ Pollut 2006;3(1):133-9. 5. Wickramasinghe SR, Binbing H, Zimbron J, Shen Z, Karim MN. Arsenic removal by coagulation and filtration: comparison of ground waters from United States and Bangladesh. Desalination 2004;169:231-44. 6. Hossain MF. Arsenic contamination in Bangladesh-an overview. Agric Ecosyst Environ 2006;113(1-4):1-16. 7. USEPA, Arsenic. Final Rule, Federal Register 2001;66(14):6976-7066. 8. Luong TV, Guifan S, Liying W, Dianjun PR. People-centered approaches to water and environmental sanitation: Endemic chronic arsenic poisoning. China 30 th WEDC International Conference; 2004. Vientiane, Lao PDR; 2004. 9. Guo X, Fujino Y, Kaneko S, Wu K, Xia Y, Yoshimura T. Arsenic contamination of groundwater and prevalence of arsenical dermatosis in the Hetao plain area, Inner Mongolia. Chin Mol Cell Biochem 2001;222(1-2):137-40. 10. Hansen HK, Núñez P, Grandon R. Electrocoagulation as a remediation tool for wastewaters containing arsenic. Miner Eng 2006;19(5):521-4. 11. Pande SP, Deshpande LS, Patni PM, Lutade SL. Arsenic removal studies in some ground waters of West Bengal, India. J Environ Sci Health 1997;32(7):1981-7. 12. Kim J, Benjamin MM. Modeling a novel ion exchange process for arsenic and nitrate removal. Water Res 2004;38(8):2053-62. 13. Baciocchi R, Chiavola A, Gavasci R. Ion exchange equilibria of arsenic in the presence of high sulphate and nitrate concentrations. Water Sci Technol: Water Supply 2005;5(5): 67-74. 14. Jegadeesan G, Mondal K, Lalvani SB. Arsenate remediation using nanosized modified zerovalent iron particles. Environ Prog 2005;24(3):289-96. 15. Han B, Runnells T, Zimbron J, Wickramasinghe R. Arsenic removal from drinking water by flocculation and microfiltration. Desalination 2002;145(1-3):293-8. 16. de Lourdes Ballinas M, Rodríguez de San Miguel E, de Jesús Rodríguez MT, Silva O, Muñoz M, de Gyves J. Arsenic(V) removal with polymer inclusion membranes from sulfuric acid media using DBBP as carrier. Environ Sci Technol 2004;38(3):886-91. 17. Dambies L, Vincent T, Guibal E. Treatment of arsenic-containing solutions using chitosan derivatives: uptake mechanism and sorption performance. Water Res 2002;36(15):3699-710. 18. Naghizadeh A, Naseri S, Nazmara S. Removal of trichloroethylene from water by adsorption on to multiwall carbon nanotubes. Iran J Environ Health Sci Eng 2011;8(4):317-24. 19. Savage N, Diallo MS. Nanomaterials and water purification: opportunities and challenges. J Nanopart Res 2005;7:331–42 20. Ntim SA, Mitra S. Adsorption of arsenic on multiwall carbon nanotube-zirconia nanohybrid for potential drinking water purification. J Colloid Interface Sci 2012;375(1):154-9. 21. Tojanowicz M. Analytical applications of carbon nanotubes: a review. Trends Anal Chem 2006;25(5):480-9. 22. Gupta S, Babu BV. Modeling, simulation, and experimental validation for continuous Cr(VI) removal from aqueous solutions using sawdust as an adsorbent. Biores Technol 2009;100(23):5633-40. 23. Dhodapkar R, Borde P, Nandy T. Super absorbent polymers in environmental remediation. Glob NEST J 2009;11(2):223-34. 24. Kundu S, Kavalakatt SS, Pal A, Ghosh SK, Mandal M, Pal T. Removal of arsenic using hardened paste of Portland cement: batch adsorption and column study. Water Res 2004;38(17):3780-90. 25. Wasiuddin NM, Tango M, Islam MR. A novel method for arsenic removal at low concentrations. Energy Sources 2002;24:1031-41

    Studying the Polypropylenimine-G2 (PPI-G2) Dendrimer Performance in Removal of Escherichia coli, Proteus mirabilis, Bacillus subtilis and Staphylococcus aureus from Aqueous Solution

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    Abstract Background: Dendrimers are a subset of branched structures that have certain structural order. The aim of this study was to investigate the performance of Polypropylenimine-G2 (PPI-G2) dendrimers in removal of Escherichia coli, Proteus mirabilis, Bacillus subtilis and Staphylococcus aureus from aqueous solution. Materials and Methods: In this experimental study, initially dilution of 103 CFU/ml was prepared from each strain of bacteria. Then, different concentrations of dendrimers (0.5, 5, 50 and 500 µg/ml) was added to water. In order to determine the efficiency of dendrimers in removal of bacteria, samples were taken at different times (0, 10, 20, 30, 40, 50 and 60 min) and were cultured on nutrient agar medium. Samples were incubated for 24 hours at 37 ° C and then the number of colonies was counted. Results: By the increasment of dendrimer concentration and contact time, the number of bacteria in aqueous solution decreased. In times of 40, 50 and 60 minutes, and the concentrations of 50 and 500 µg/ml, all kinds of bacteria in aqueous solution were removed. 0.5 µg/ml of dendrimer concentration had not effect in reducing the number of Escherichia coli and Proteus mirabilis. The effect of dendrimer on gram-negative bacteria was weaker than gram-positive bacteria. Conclusion: Results of this study indicated that PPI-G2 dendrimer is able to remove Escherichia coli, Proteus mirabilis, Staphylococcus aureus and Bacillus subtilis in aqueous solution. However, using dendrimers can be considered as a new approach for drinking water disinfection but it requires further wide range studies
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