Investigating the sustainable performance of a nanoscale zerovalent iron permeable reactive barrier for removal of nitrate, sulfide, and arsenic

Abstract The quality of groundwater resources is at catastrophic risk. The proper performance of iron nanoparticles has made a permeable reactive barrier (PRB) an alternative to conventional filtration methods. The performance of nanozerovalent iron (nZVI) PRBs is limited by particle aggregation, in...

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Published inAqua (London, England) Vol. 72; no. 4; pp. 540 - 556
Main Authors Naghikhani, Ali, Karbassi, Abdolreza, Sarang, Amin, Baghdadi, Majid
Format Journal Article
LanguageEnglish
Published Oxford IWA Publishing 01.04.2023
Subjects
Aggregation
Arsenic
biopolymers
Contamination
Drought
Freshwater resources
Groundwater
Groundwater quality
Iron
Longevity
Microorganisms
Microscopy
Nanomaterials
Nanoparticles
nanozerovalent iron
Nitrate removal
Nitrates
organic mulch
Performance evaluation
Permeability
permeable reactive barrier
Permeable reactive barriers
Phase separation
Pollution prevention
Stability analysis
Sulfides
Sulphides
Sustainability
Water resources
Xanthan
Xanthan gum
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Summary:Abstract The quality of groundwater resources is at catastrophic risk. The proper performance of iron nanoparticles has made a permeable reactive barrier (PRB) an alternative to conventional filtration methods. The performance of nanozerovalent iron (nZVI) PRBs is limited by particle aggregation, instability, and phase separation, even at low iron concentrations. Therefore, the precipitation of reactive materials and a decrease in the longevity of PRB are fundamental challenges. A laboratory setup is used to compare the performance of bare nZVI and xanthan gum (XG)-nZVI + Mulch PRB to simultaneously remove nitrate, sulfide, and arsenic in groundwater. nZVI (average diameter of 35–55 nm) particles are used as reactive media. The objectives are (1) to develop a method for treating nitrate, sulfide, and arsenic simultaneously in groundwater using organic mulch and XG-nZVI; and (2) to evaluate the longevity performance of the XG-nZVI + Mulch and bare nanoparticles treatment system over 10 days. The results showed that the XG-nZVI + Mulch barrier's performance for eliminating NO3-, As, and S2− was generally improved compared to the bare nZVI barriers by 5.7, 19.2, and 10.9%, respectively. Finally, despite the need for long-term sustainability assessment, XG-nZVI PRB performance is impressive, and this stability promises to improve the longevity of nanoparticles while used in PRBs.
ISSN:2709-8028
1606-9935
2709-8036
1605-3974
DOI:10.2166/aqua.2023.006