Assessing the Removal of Arsenite and Arsenate Mixtures from the Synthetic Bangladesh Groundwater (SBGW) Using Combined Fe(VI)/Fe(III) Treatments and Local Regression Analysis

Javier Quino-Favero,Patricia Prieto Veramendi,Lisveth Flores Del Pino,Paloma Mogrovejo García,Raúl Eyzaguirre Perez

doi:10.3390/w13091134

Javier Quino-Favero, Patricia Prieto Veramendi + Show 3 more

Open Access

https://doi.org/10.3390/w13091134

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Journal: Water	Publication Date: Apr 21, 2021
Citations: 7	License type: CC BY 4.0

Affiliation: University of Lima, National Agrarian University

Abstract

Arsenic is an inorganic pollutant that, depending on oxidation–reduction and pH level conditions, may be found in natural waters in two variants: As(III) and As(V). Any treatment to effectively remove arsenic from water will be conditioned by the presence of one or both variants. In this context, this study assesses using electrochemically produced Fe(VI) with Fe(III) to remove As(III), As(V), and their combinations from the Synthetic Bangladesh Groundwater (SBGW) containing anions that interfere with iron-based arsenic removal processes. The combined use of Fe(VI) and Fe(III) allowed us to remove the total arsenic below the 10 mg L−1 threshold established by the World Health Organization and Peruvian regulations for drinking water. An optimum combination of 1 mg L−1 of Fe(VI) and 30 mg L−1 of Fe(III) was identified and tested on the removal of four different proportions of As(III):As(V) for two total concentrations: 500 and 250 mg L−1. There were no significant differences in the final removal values under the different proportions of As(III):As(V) for each total concentration, with a final removal average of 99.0% and 96.9% for the 500 and 250 µg L−1 concentrations, respectively.

Highlights

Arsenic is a metalloid widely distributed throughout the Earth’s crust, and it is released into water sources as part of a leaching process from rocks and sediments, as well as from anthropogenic sources [1]
Freshwater arsenic concentrations may range from minor traces to as high as 44,000 μg L−1 in Waiotapu Valley, New Zealand [2]
Considering the 10 μg L−1 threshold proposed by the World Health Organization (WHO), 100 million people around the world are at risk of arsenic exposure from drinking water

Summary

Introduction

Arsenic is a metalloid widely distributed throughout the Earth’s crust, and it is released into water sources as part of a leaching process from rocks and sediments, as well as from anthropogenic sources [1]. Freshwater arsenic concentrations may range from minor traces to as high as 44,000 μg L−1 in Waiotapu Valley, New Zealand [2]. Considering the 10 μg L−1 threshold proposed by the World Health Organization (WHO), 100 million people around the world are at risk of arsenic exposure from drinking water. 45 million people in Asian developing countries are exposed to concentrations exceeding. The WHO considers that contaminated drinking water poses the greatest threat to public health from arsenic [4]. The toxic effects of arsenic in adults, depending on exposure levels and times, include skin injuries, cardiovascular effects, gastrointestinal disturbances, liver disease, and cancer [6]. Lung disease and defective intellectual functions [7]

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