Divalent Heavy Metal Removal Using Manganese Oxide Coated Polymeric Media for Storm Water Treatment

2001 ◽  
Vol 2001 (14) ◽  
pp. 29-55 ◽  
Author(s):  
Dingfang Liu ◽  
John J. Sansalone ◽  
Frank K. Cartledge ◽  
Jonathan Kolich
Keyword(s):  
Heavy Metal ◽  
Water Treatment ◽  
Manganese Oxide ◽  
Metal Removal ◽  
Heavy Metal Removal ◽  
Storm Water ◽  
Polymeric Media

Polyvinyl alcohol/polysaccharide hydrogel graft materials for arsenic and heavy metal removal

2015 ◽  
Vol 39 (7) ◽  
pp. 5823-5832 ◽  
Author(s):  
Md. Najmul Kabir Chowdhury ◽  
Ahmad Fauzi Ismail ◽  
Mohammad Dalour Hossen Beg ◽  
Gurumurthy Hegde ◽  
Rasool Jamshidi Gohari
Keyword(s):  
Heavy Metal ◽  
Water Treatment ◽  
Polyvinyl Alcohol ◽  
Metal Removal ◽  
Heavy Metal Removal ◽  
Hydrogel Formation ◽  
Polysaccharide Hydrogel ◽  
Metallic Species

Polyvinyl alcohol/polysaccharide hydrogel formation ((A)–(C)) and metallic species adsorption ((D)) for water treatment.

scholarly journals Biohybrid nanofibers containing manganese oxide–forming fungi for heavy metal removal from water

2020 ◽  
Vol 15 ◽  
pp. 155892501989895
Author(s):  
Yaewon Park ◽  
Shuang Liu ◽  
Terrence Gardner ◽  
Drake Johnson ◽  
Aaron Keeler ◽  
...  
Keyword(s):  
Heavy Metal ◽  
Metal Ions ◽  
Manganese Oxide ◽  
Heavy Metal Ions ◽  
Manganese Oxides ◽  
Metal Removal ◽  
Strong Association ◽  
Heavy Metal Removal ◽  
Fungal Hyphae ◽  
Farm Unit

Manganese-oxidizing fungi support bioremediation through the conversion of manganese ions into manganese oxide deposits that in turn adsorb manganese and other heavy metal ions from the environment. Manganese-oxidizing fungi were immobilized onto nanofiber surfaces to assist remediation of heavy metal–contaminated water. Two fungal isolates, Coniothyrium sp. and Coprinellus sp., from a Superfund site (Lot 86, Farm Unit #1) water treatment system were incubated in the presence of nanofibers. Fungal hyphae had strong association with nanofiber surfaces. Upon fungal attachment to manganese chloride–seeded nanofibers, Coniothyrium sp. catalyzed the conformal deposition of manganese oxide along hyphae and nanofibers, but Coprinellus sp. catalyzed manganese oxide only along its hyphae. Fungi–nanofiber hybrids removed various heavy metals from the water. Heavy metal ions were adsorbed into manganese oxide crystalline structure, possibly by ion exchange with manganese within the manganese oxide. Hybrid materials of fungal hyphae and manganese oxides confined to nanofiber-adsorbed heavy metal ions from water.

scholarly journals Synthesis and Water Treatment Applications of Nanofibers by Electrospinning

Processes ◽  
2021 ◽  
Vol 9 (10) ◽  
pp. 1779
Author(s):  
Saumya Agrawal ◽  
Rashmi Ranjan ◽  
Bajrang Lal ◽  
Ashiqur Rahman ◽  
Swatantra P. Singh ◽  
...  
Keyword(s):  
Heavy Metals ◽  
Heavy Metal ◽  
Water Treatment ◽  
Environmental Remediation ◽  
Electrode Materials ◽  
Metal Removal ◽  
Heavy Metal Removal ◽  
Membrane Distillation ◽  
Electrospinning Process

In the past few decades, the role of nanotechnology has expanded into environmental remediation applications. In this regard, nanofibers have been reported for various applications in water treatment and air filtration. Nanofibers are fibers of polymeric origin with diameters in the nanometer to submicron range. Electrospinning has been the most widely used method to synthesize nanofibers with tunable properties such as high specific surface area, uniform pore size, and controlled hydrophobicity. These properties of nanofibers make them highly sought after as adsorbents, photocatalysts, electrode materials, and membranes. In this review article, a basic description of the electrospinning process is presented. Subsequently, the role of different operating parameters in the electrospinning process and precursor polymeric solution is reviewed with respect to their influence on nanofiber properties. Three key areas of nanofiber application for water treatment (desalination, heavy-metal removal, and contaminant of emerging concern (CEC) remediation) are explored. The latest research in these areas is critically reviewed. Nanofibers have shown promising results in the case of membrane distillation, reverse osmosis, and forward osmosis applications. For heavy-metal removal, nanofibers have been able to remove trace heavy metals due to the convenient incorporation of specific functional groups that show a high affinity for the target heavy metals. In the case of CECs, nanofibers have been utilized not only as adsorbents but also as materials to localize and immobilize the trace contaminants, making further degradation by photocatalytic and electrochemical processes more efficient. The key issues with nanofiber application in water treatment include the lack of studies that explore the role of the background water matrix in impacting the contaminant removal performance, regeneration, and recyclability of nanofibers. Furthermore, the end-of-life disposal of nanofibers needs to be explored. The availability of more such studies will facilitate the adoption of nanofibers for water treatment applications.

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