Optimization of magnetic powdered activated carbon for aqueous Hg(II) removal and magnetic recovery

► Thermal oxidation of MPAC decreased the amorphous characteristic of iron oxides. ► Thermal oxidation did not influence magnetic recovery or Hg removal performance. ► At all thermal oxidation temperatures, the 3:1 MPAC achieved the highest Hg removal. Activated carbon is known to adsorb aqueous Hg(...

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Bibliographic Details
Published in:Journal of hazardous materials 2012-01, Vol.199 (15), p.9-14
Main Authors: Faulconer, Emily K., von Reitzenstein, Natalia V. Hoogesteijn, Mazyck, David W.
Format: Article
Language:English
Subjects:
Activated carbon
Adsorption
atomic absorption spectrometry
Carbon - chemistry
cold
headspace analysis
iron oxides
Magnetic sorbent
Magnetics
Mercury
Mercury - isolation & purification
Mercury adsorption
mixing
nitrogen
Optimization
Oxidation
Oxidation-Reduction
porosity
Recovering
recycling
Sorbents
Spectrophotometry, Atomic
surface area
Synthesis
temperature
vapors
Wastes
X-Ray Diffraction
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Summary:► Thermal oxidation of MPAC decreased the amorphous characteristic of iron oxides. ► Thermal oxidation did not influence magnetic recovery or Hg removal performance. ► At all thermal oxidation temperatures, the 3:1 MPAC achieved the highest Hg removal. Activated carbon is known to adsorb aqueous Hg(II). MPAC (magnetic powdered activated carbon) has the potential to remove aqueous Hg to less than 0.2 μg/L while being magnetically recoverable. Magnetic recapture allows simple sorbent separation from the waste stream while an isolated waste potentially allows for mercury recycling. MPAC Hg-removal performance is verified by mercury mass balance, calculated by quantifying adsorbed, volatilized, and residual aqueous mercury. The batch reactor contained a sealed mercury–carbon contact chamber with mixing and constant N 2 (g) headspace flow to an oxidizing trap. Mercury adsorption was performed using spiked ultrapure water (100 μg/L Hg). Mercury concentrations were obtained using EPA method 245.1 and cold vapor atomic absorption spectroscopy. MPAC synthesis was optimized for Hg removal and sorbent recovery according to the variables: C:Fe, thermal oxidation temperature and time. The 3:1 C:Fe preserved most of the original sorbent surface area. As indicated by XRD patterns, thermal oxidation reduced the amorphous characteristic of the iron oxides but did not improve sorbent recovery and damaged porosity at higher oxidation temperatures. Therefore, the optimal synthesis variables, 3:1 C:Fe mass ratio without thermal oxidation, which can achieve 92.5% (±8.3%) sorbent recovery and 96.3% (±9%) Hg removal. The mass balance has been closed to within approximately ±15%.
ISSN:0304-3894
1873-3336
DOI:10.1016/j.jhazmat.2011.10.023