AI Article Synopsis
- Researchers studied how well calcined and ground mussel shells can retain mercury, with and without phosphate, using two types of experiments.
- In batch experiments, calcined shells showed significantly better mercury adsorption than ground shells and the presence of phosphate further enhanced this retention, resulting in very low levels of mercury desorption.
- In stirred flow experiments, calcined shells again outperformed ground shells in mercury retention, and the addition of phosphates led to considerable improvements in both shell types, indicating that mercury-phosphate interactions enhance retention capabilities.
- Overall, the findings suggest that both types of mussel shells can effectively remove mercury from water, with phosphates boosting their efficiency.
Article Abstract
We determined mercury retention on calcined and ground mussel shell, in presence and absence of phosphate, using batch and stirred flow chamber experiments. In batch experiments the calcined shell exhibited higher Hg adsorption, with good fitting to Freundlich equation (R2: 0.925-0.978); the presence of phosphate increased Hg adsorption; mercury desorption was 13% or lower, diminishing up to 2% under the presence of phosphates. In stirred flow chamber experiments calcined shell retained more Hg than ground shells (6300 vs. 4000-5200 micromol/kg); Hg retention increased an additional 40% on calcined shell and up to an additional 70% on ground shells when phosphates were present; mercury desorption was quite similar in all shell types (20%-34%), increasing up to 49%-60% in ground shells when phosphates were present. The higher Hg adsorption on calcined shell would be related to its calcite and dolomite concentrations; mercury-phosphate interactions would cause the increase in Hg retention when phosphates are present. Data on Hg desorption suggest that Hg retention was not easily reversible after batch experiments, increasing in the stirred flow chamber due to convective flow. Calcined and ground mussel shells could be recycled removing Hg from water, with the presence of phosphates in solution improving efficacy.
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| http://dx.doi.org/10.1016/s1001-0742(12)60320-9 | DOI Listing |
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