Thermal plasma processing of Moringa oleifera biochars: adsorbents for fluoride removal from water

Anthropogenic activities accelerate fluoride contamination in groundwater, which largely affects public health. Though biochars have been explored for defluoridation, the plasma technology-based production of biochars has not received as considerable attention as other methods and it is also importa...

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Bibliographic Details
Published in:RSC advances 2023-01, Vol.13 (7), p.4340-4350
Main Authors: Gourai, Moumita, Nayak, Ashok K, Nial, Partha S, Satpathy, Bijaylaxmi, Bhuyan, Rajashree, Singh, Saroj K, Subudhi, Umakanta
Format: Article
Language:English
Subjects:
Adsorbates
Adsorbents
Adsorption
Argon
Calcium oxide
Carbon
Carbonyls
Continuous flow
Drinking water
Fluorides
Groundwater
Inert atmospheres
Magnesium oxide
Plasma
Plasma processing
Public health
Slaked lime
Superconductors (materials)
Surface chemistry
Thermal plasmas
Water sampling
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Summary:Anthropogenic activities accelerate fluoride contamination in groundwater, which largely affects public health. Though biochars have been explored for defluoridation, the plasma technology-based production of biochars has not received as considerable attention as other methods and it is also important that biochars be tested on groundwater samples. In the present study, for the first time, we report the preparation of biochars from different parts of using thermal plasma processing and demonstrate fluoride adsorption in both synthetic and contaminated groundwater. Water samples were collected from different locations in Nuapada district of Odisha such as Kotamal-Makardampada (20°24'46''N 82°37'19''E), Pandrapathar (20°34'41''N 82°39'25''E), Karlakot-Kadobhata (20°22'52''N 82°37'24''E), Kotamal-Jhakarpada (20°24'35''N 82°37'20''E), and Dohelpada (20°33'50''N 82°38'57''E). The leaf samples are processed at 1600 °C for 3 min in an inert atmosphere under a continuous flow of argon to get suitable biochars. The plasma-synthesized biochars contain larger exposed surfaces, which are efficient for the adsorption of fluoride. The prepared biochars were highly porous, amorphous, and contain > 72% carbon, which increases the efficiency of defluoridation due to the surface adsorbate site exposed. XRD of the samples showed the presence of calcium hydroxide, magnesium oxide, and calcium oxide, and large peaks of carbon. Raman data showed the double bond of carbon with oxygen in the form of carbonyl bonds, thioether, and sulfhydryl bonds, which contribute to the protonated site for the adsorption of fluoride, and assist in water penetration and swelling of biochars. The biochar of is very efficient for the adsorption of fluoride from standard samples as well as groundwater samples up to a concentration of 6 ppm. Conclusively, the present investigation shows that leaves are a good alternative adsorbent that could be used for the removal of fluoride from groundwater samples with > 85% removal in 18 h using 1 g biochar for 100 mL or 10 g biochar for 1 L water containing 4 ppm fluoride. To our knowledge, this is the first report on the thermal plasma-based production of biochars for the removal of fluoride from drinking water.
ISSN:2046-2069
2046-2069
DOI:10.1039/d2ra07514h