Unveiling the Role of Sulfur in Rapid Defluorination of Florfenicol by Sulfidized Nanoscale Zero-Valent Iron in Water under Ambient Conditions
Chemical Sciences not elsewhere classified
florfenicol
mol
Iron
Biophysics
0211 other engineering and technologies
02 engineering and technology
Biochemistry
Microbiology
SNZVI
Inorganic Chemistry
Batch reactivity experiments
dechlorination
groundwater
Sulfidized nanoscale zero-valent iron
surface
Groundwater
Ambient Conditions Groundwater cont.
Thiamphenicol
Evolutionary Biology
pathway
Water
electron transfer
nanoscale zero-valent iron
Fe
6. Clean water
Trichloroethylene
Infectious Diseases
material
13. Climate action
chlorine
defluorination
contaminants
reactive
NZVI
Sulfur
Water Pollutants, Chemical
Biotechnology
DOI:
10.1021/acs.est.0c07319
Publication Date:
2021-02-06T11:50:54Z
AUTHORS (8)
ABSTRACT
Groundwater contamination by halogenated organic compounds, especially fluorinated ones, threatens freshwater sources globally. Sulfidized nanoscale zero-valent iron (SNZVI), which is demonstrably effective for dechlorination of groundwater contaminants, has not been well explored for defluorination. Here, we show that SNZVI nanoparticles synthesized via a modified post-sulfidation method provide rapid dechlorination (∼1100 μmol m-2 day-1) and relatively fast defluorination (∼6 μmol m-2 day-1) of a halogenated emerging contaminant (florfenicol) under ambient conditions, the fastest rates that have ever been reported for Fe0-based technologies. Batch reactivity experiments, material characterizations, and theoretical calculations indicate that coating S onto the metallic Fe surface provides a highly chemically reactive surface and changes the primary dechlorination pathway from atomic H for nanoscale zero-valent iron (NZVI) to electron transfer for SNZVI. S and Fe sites are responsible for the direct electron transfer and atomic H-mediated reaction, respectively, and β-elimination is the primary defluorination pathway. Notably, the Cl atoms in florfenicol make the surface more chemically reactive for defluorination, either by increasing florfenicol adsorption or by electronic effects. The defluorination rate by SNZVI is ∼132-222 times higher with chlorine attached compared to the absence of chlorine in the molecule. These mechanistic insights could lead to new SNZVI materials for in situ groundwater remediation of fluorinated contaminants.
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