ARSENIC REMOVAL FROM GROUNDWATER USING RECYCLED IRON NANOPARTICLES: DEVELOPMENT AND EVALUATION OF A LOW-COST FILTER FOR RURAL COMMUNITIES
The presence of geogenic arsenic in groundwater poses a serious threat to public health in regions such as the Lake Poopó basin in Oruro, Bolivia. This study developed and evaluated a low-cost experimental filter using metallic iron (Fe⁰) and iron oxide (Fe₃O₄) nanoparticles obtained from recycled iron shavings using top-down and bottom-up filtration technologies. The nanoparticles were integrated into a homemade filtration system along with readily available materials such as sand, charcoal, and ground brick. Kinetic and adsorption tests were performed under controlled conditions, achieving arsenic removal rates exceeding 97% with Fe⁰ nanoparticles and 91% with Fe₃O₄. These results best fit the Freundlich isotherm model and second-order kinetics, which describe the arsenate adsorption behavior on both nanoparticles. The filter proved effective for up to 13 consecutive treatment cycles, reducing arsenic concentrations to levels ≤ 0.01 mg/L. This approach represents a sustainable, economical, and technically viable alternative for rural communities affected by this contaminant.
ARSENIC REMOVAL FROM GROUNDWATER USING RECYCLED IRON NANOPARTICLES: DEVELOPMENT AND EVALUATION OF A LOW-COST FILTER FOR RURAL COMMUNITIES
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DOI: 10.37572/EdArt_1212257968
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Palavras-chave: Arsenic; iron nanoparticles; iron oxide; groundwater; low-cost filter; adsorption.
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Keywords: Arsenic; iron nanoparticles; iron oxide; groundwater; low-cost filter; adsorption.
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Abstract:
The presence of geogenic arsenic in groundwater poses a serious threat to public health in regions such as the Lake Poopó basin in Oruro, Bolivia. This study developed and evaluated a low-cost experimental filter using metallic iron (Fe⁰) and iron oxide (Fe₃O₄) nanoparticles obtained from recycled iron shavings using top-down and bottom-up filtration technologies. The nanoparticles were integrated into a homemade filtration system along with readily available materials such as sand, charcoal, and ground brick. Kinetic and adsorption tests were performed under controlled conditions, achieving arsenic removal rates exceeding 97% with Fe⁰ nanoparticles and 91% with Fe₃O₄. These results best fit the Freundlich isotherm model and second-order kinetics, which describe the arsenate adsorption behavior on both nanoparticles. The filter proved effective for up to 13 consecutive treatment cycles, reducing arsenic concentrations to levels ≤ 0.01 mg/L. This approach represents a sustainable, economical, and technically viable alternative for rural communities affected by this contaminant.
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Número de páginas: 10
- JUAN SIMON TORRES ESPADA
- Yrene Romina Lazcano Cruz