Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes

Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes Publisher

Karimi P¹ ; Rasolevandi T² ; Sadani M^{1, 3} ; Azarpira H⁴ ; Mohseni SM^{1, 3}

Show Affiliations

1. Student Research Committee, School of Public Health and Safety, Shahid Beheshti University of Medical Sciences, Tehran, Iran
2. Environmental Health Engineering Department, School of Public Health, Tehran University of Medical Sciences, Tehran, Iran
3. Environmental Health Engineering Department, School of Public Health and safety, Beheshti University of Medical Sciences, Tehran, Iran
4. Department of Environmental Health Engineering, Social Determinants of Health Research Center, Saveh University of Medical Sciences, Saveh, Iran

Source: Journal of Molecular Structure Published:2022

Abstract

Heavy metals in groundwater are concerned due to their potential negative impact on human such as persistent toxicity, conversation to more toxic compounds, possibility of condensation, entry into the food chain and non-biodegradability. In this study, removal of arsenic in a novel process includes reduction and complexion, adsorption and oxidation in the sequential UV/SO32- reduction and UV/MnO2 particle oxidation processes investigated. In our study, in the optimal condition MnO2 0.1 mM, Na2SO3 0.3 mM, 6 min reaction time (synthetic sample) and at pH 6, 10 mg L−1 arsenic was removed. After that, the real sample examined and anions increase the time to reach in blew the World Health Organization standard. In the first stage, the sulfite-sulfate cycle converts arsenate to arsenite, and then both substances are removed from the solution by forming a complex on the MnO2 surface advantages of this method against others include less time, higher efficiency, less use of reactive materials, and no need for large pH changes without release of sulfite or sulfate. At pH 8 about 60% and 40% of reaction species were oxidative and reductive species respectively. However, at pH 6 the number of oxidative species is much less than the reactive species. Considering the better efficiency at pH 6, it shows that reducing species have a more important and primary role in arsenic removal. Also, the amount of energy consumed decreases from 15.23 to 5.37 kWh per cubic meter, Kobs (min−1) 0.0748 to 0.1218 and robs (mg/L.min) increase from 3.74 to 24.36 with change of As concentration from 50 to 250 µg L−1. This method investigated in a real well sample with anions, and more effective anions were phosphate and sulfate. Phosphate reacts with eaq− and react with sulfite radical and does not allow the formation of complexes, on the other hand Sulfate help to convert Arsenite to arsenate and arsenate direct removal. © 2022

Related Docs

View other Related Docs

1. Cadmium Precipitation by Sulfite Reaction Chain Under Uv Irradiation, Desalination and Water Treatment (2022)

2. Simultaneous Cr (Vi) Reduction and Diazinon Oxidation With Organometallic Sludge Formation Under Photolysis: Kinetics, Degradation Pathways, and Mechanism, Environmental Science and Pollution Research (2023)

3. Comparative Study of Energy Consumption, Kinetic, and Performance Between Conventional and Baffled Photocatalytic Reactor (Bpcr) to Ofloxacin Photo-Degradation, Environmental Science and Pollution Research (2022)

4. Diazinon and Mcpa Photo-Reduction With Sulfite Excitation Under Uv Irradiation and Reducing Agents’ Generation, Heliyon (2023)

5. Diazinon Pesticide Photocatalytic Degradation in Aqueous Matrices Based on Reductive Agent Release in Iodide Exciting Under Uv Irradiation, Environmental Science and Pollution Research (2022)

6. 4-Chloro-2-Methylphenoxyacetic Acid Decomposition by Production of Reduction Species in Sulfite Excitation Through Photolysis, Journal of Molecular Structure (2024)

7. Modeling and Optimizing Chromate Photo-Precipitation With Iodide Exciting Under Uv Irradiation, Desalination and Water Treatment (2020)

8. Sustainable Technologies for Removal of Arsenic From Water and Wastewater: A Comprehensive Review, Journal of Molecular Liquids (2025)

Experts (# of related papers)

View all Related Experts

Kamyar Yaghmaeian (1)

Mohammadhadi Dehghani Tafti (1)

Style	Citing Format
MLA	Karimi P, et al.. "Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes." Journal of Molecular Structure, vol. 1258, no. , 2022, pp. -.
APA	Karimi P, Rasolevandi T, Sadani M, Azarpira H, Mohseni SM (2022). Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes. Journal of Molecular Structure, 1258(), -.
Chicago	Karimi P, Rasolevandi T, Sadani M, Azarpira H, Mohseni SM. "Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes." Journal of Molecular Structure 1258, no. (2022): -.
Harvard	Karimi P et al. (2022) 'Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes', Journal of Molecular Structure, 1258(), pp. -.
Vancouver	Karimi P, Rasolevandi T, Sadani M, Azarpira H, Mohseni SM. Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes. Journal of Molecular Structure. 2022;1258():-.
BibTex	@article{ author = {Karimi P and Rasolevandi T and Sadani M and Azarpira H and Mohseni SM}, title = {Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes}, journal = {Journal of Molecular Structure}, volume = {1258}, number = {}, pages = {-}, year = {2022} }
RIS	TY - JOUR AU - Karimi P AU - Rasolevandi T AU - Sadani M AU - Azarpira H AU - Mohseni SM TI - Accelerated Two-Step Arsenic Photoredox Sedimentation in the Sequential Uv/So32− Reduction and Uv/Mno2 Oxidation Processes JO - Journal of Molecular Structure VL - 1258 IS - SP - EP - PY - 2022 ER -

Science Communicator Platform

Authors

Authors Affiliations

Abstract